PHOTOMULTIPLIER TUBES
AND ASSEMBLIES
TOPIC
Masatoshi Koshiba (left), Professor Emeritus at the University of Tokyo, who
was awarded the Nobel prize in physics; Teruo Hiruma (middle), President
of Hamamatsu Photonics; Dr. Sydney Brenner (right) who was awarded the
Nobel Prize in Physiology or Medicine. They met together on December
10th, 2002, at the Stockholm Concert Hall.
(Photo courtesy of The Chunichi Shimbun)
INTRODUCTION
In ionizing radiation measurements, scintillation counters which are combinations of scintillators and photomultiplier tubes are
used as most common and useful devices in detecting X-, alpha-, beta-, gamma-rays and other high energy charged particles. A
scintillator emits flashes of light in response to input ionizing radiations and a photomultiplier tube coupled to a scintillator detects
these scintillation lights in a precise way.
In high energy physics experiments, one of important apparatuses is a Cherenkov counter in which photomultiplier tubes detect
Cherenkov radiations emitted by high energy charged particles passing through a dielectric material.
To detect radiations accurately, photomultiplier tubes may be required to have high detecting efficiency (QE & energy resolution),
wide dynamic range (pulse linearity), good time resolution (TTS), high stablility & reliability, and to be operatable in high magnetic
field environment or at high temperature condition. A ruggedized construction is required according to circumstances. On the
other hand, several kinds of position sensitive photomultiplier tubes have been developed and are used in these measurements.
This catalog provides a quick reference for Hamamatsu photomultiplier tubes, especially designed or selected for scintillation
counters and Cherenkov radiation detectors, and includes most of types currently available ranging in size from 3/8" through 20"
in diameter. It should be noted that this catalog is just a starting point in describing Hamamatsu product line since new types are
continuously under-development.
Please feel free to contact us with your specific requirements.
Photomultiplier Tubes
and Assemblies
For Scintillation Counting
and High Energy Physics
TABLE OF CONTENTS
Photomultiplier Tubes
Page
Operating Characteristics ........................................................................ 2
Selection Guide by Application .............................................................. 14
List Guide for Photomultiplier Tubes ..................................................... 16
Photomultiplier Tubes ........................................................................... 18
Dimensional Outlines and Basing Diagrams for Photomultiplier Tubes ........... 24
Typical Gain Characteristics .................................................................. 34
Position Sensitive Photomultiplier Tubes .............................................. 38
Voltage Distribution Ratios .................................................................... 40
Photomultiplier Tube Assemblies
Quick Reference for PMT Hybrid Assemblies .................................... 42
Dimensional Outlines and Circuit Diagrams for PMT Hybrid Assemblies ............ 44
Quick Reference for PMT Socket Assemblies ..................................... 52
Dimensional Outlines and Circuit Diagrams for PMT Socket Assemblies ............. 54
Dimensional Outlines for E678 Series Sockets ..................... 60
Index by Type No. .................................................................... 62
Cautions and Warranty ............................................................ 64
Typical Photocathode Spectral Response
and Emission Spectrum of Scintillators ................................. 65
Operating Characteristics
This section describes the prime features of photomultiplier
tube construction and basic operating characteristics.
1. GENERAL
The photomultiplier tube (PMT) is a photosensitive device consisting of an input window, a photocathode, focusing electrodes, an electron multiplier (dynodes) and an anode in a vacuum tube, as shown in Figure 1. When light enters the photocathode, the photocathode emits photoelectrons into vacuum
by the external photoelectric effect. These photoelectrons are
directed by the potential of focusing electrode towards the electron multiplier where electrons are multiplied by the process of
secondary electron emission.
The multiplied electrons are collected to the anode to produce
output signal.
FOCUSING ELECTRODES
Spectral response is usually expressed in term of quantum efficiency and radiant sensitivity as shown on the inside the back
cover.
Quantum efficiency (QE) is defined as the ratio of the number
of photoelectrons emitted from the photocathode to the number
of incident photons.
It's customarily stated as a percentage.
The equation of QE is as follows:
QE =
STEM
INCIDENT
LIGHT
Photoelectric Current
(A/W)
Radiant Power of Light
Quantum efficiency and radiant sensitivity have the following
relationship at a given wavelength.
QE =
INPUT
WINDOW
Number of Photoelectrons
×100 (%)
Number of Photons
Radiant sensitivity (S) is the photoelectric current from the photocathode divided by the incident radiant power at a given wavelength, expressed in A/W (ampere per watt).
The equation of S is as follows:
S=
Figure 1: Cross-Section of Head-On Type PMT
PHOTOCATHODE
2.2 Quantum Efficiency and Radiant Sensitivity
S×1240
×100 (%)
λ
where λ is the wavelength in nm (nanometer).
PHOTOELECTRON
ELECTRON MULTIPLIER
(DYNODES)
ANODE
2.3 Window Materials
TPMHC0048EA
The window materials commonly used in PMT are as follows:
(1) Borosilicate glass
This is the most frequently used material. It transmits light from
the infrared to approximately down to 300 nm.
2. PHOTOCATHODE
2.1 Spectral Response
The photocathode of PMT converts energy of incident light into
photoelectrons by the external photoelectric effect. The conversion efficiency, that is photocathode sensitivity, varies with the
wavelength of incident light. This relationship between the photocathode sensitivity and the wavelength is called the spectral
response characteristics.
Typical spectral response curves of the variation of bialkali
photocathodes are shown on the inside of the back cover.
The spectral response range is determined by the photocathode material on the long wavelength edge, and by the window material on the short wavelength edge.
In this catalog, the long wavelength cut-off of spectral response
range is defined as the wavelength at which the cathode radiant sensitivity drops to 1 % of the maximum sensitivity.
2
For scintillation counting application, the low noise borosilicate
glass (this is called K-free glass) may be used. It contains very
little amount of potassium (K2O and 40K) which can cause unwanted background noise because of its radioisotopes.
(2) UV-transmitting glass
This glass transmits ultraviolet light well as the name implies,
and it is widely used. The UV cut-off wavelength is approximately 185 nm.
This material transmits ultraviolet light down to 160 nm. Silica
is not suitable for the stem material of tubes because it has a
different thermal expansion coefficient from kovar metal which
is used for the tube leads. Thus, borosilicate glass is used for
the stem. In order to seal these two materials having different
thermal expansion ratios, a technique called graded seal is
used. This is a technique to seal several glass materials having
gradually different thermal expansion ratios. Another feature of
silica is superiority in radiation hardness.
2.4 Photocathode Materials
The photocathode is a photoemissive surface with very low
work and high energy physics applications:
(1) Bialkali
This has a spectral response which fits the emission spectra of
most scintillators. Thus, it is frequently used for scintillator applications.
(2) High Temperature Bialkali
This is particularly useful at higher operating temperatures up
to 175 °C. Its major application is oil well logging. Also it can be
operated with very low dark current at the room temperature.
(3) Extended Green Bialkali
This is a variant of bialkali photocathode and has especially
high sensitivity in a green region. It's suitable for scintillating tile
or fiber calorimeters with wavelength shifters and for CsI(Tl)
scintillators.
As stated above, the spectral response range is determined by
the materials of the photocathode and the window as shown in
Figure 20.
It is important to select appropriate materials which will suit the
application.
2.5 Luminous and Blue Sensitivity
Since the measurement of spectral response characteristics of
a PMT requires a sophisticated system and time, it isn't practical to provide spectral response data on each tube. Instead,
cathode and anode luminous sensitivity data are usualiy attached.
The cathode luminous sensitivity is the photoelectric current
from the photocathode per incident light flux (10-5 to 10-2 lumen) from a tungsten filament lamp operated at a distribution
temperature of 2856K.
The cathode luminous sensitivity is expressed in the unit of
µA/lm (micro amperes per lumen).
Note that the lumen is a unit used for luminous flux in the visible region, therefore these values may be meaningless for
tubes which are sensitive out of the visible region (refer to Figure 2).
The cathode blue sensitivity is the photoelectric current from
the photocathode per incident light flux of a tungsten filament
lamp at 2856K passing through a blue filter. Corning CS-5-58
filter which is polished to half stock thickness is used for the
measurement of this sensitivity. This filter is a band-pass filter
and its peak wavelength of transmittance is 400 nm.
Since the light flux, once transmitted through the blue filter, can
not be expressed in lumen, the blue sensitivity is usually represented by the blue sensitivity index.
The blue sensitivity is a very important parameter in the scintillation counting since most of the scintillators produce emission
spectrum in the blue region, and may dominate the factor of
energy resolution.
These parameters of cathode luminous and blue sensitivities
are particularly useful when comparing tubes having the same
or similar spectral response ranges. Hamamatsu final test
sheets accompanied with tubes usually indicate these parameters.
Figure 2: Typical Human Eye Response and Spectral
Distribution of 2856K Tungsten Lamp
100
TPMOB0054EB
TUNGSTEN
LAMP
AT 2856K
80
RELATIVE VALUE (%)
(3) Synthetic silica
60
40
VISUAL SENSITIVITY
20
0
200
400
600
800
1000
1200
1400
WAVELENGTH (nm)
3
3. ELECTRON MULTIPLIER (DYNODES)
4.2 Gain (Current Amplification)
The superior sensitivity (high gain and high S/N ratio) of PMT is
due to a low noise electron multiplier which amplifies electrons
in a vaccum with cascade secondary emission process. The
electron multiplier consists of several to up to 19 stages of
electrodes which are called dynodes.
Photoelectrons emitted from a photocathode are accelerated
by an electric field so as to strike the first dynode and produce
secondary electron emissions. These secondary electrons then
impinge upon the next dynode to produce additional secondary
electron emissions. Repeating this process over successive
dynode stages (cascade process), a high gain is achieved.
Therefore a very small photoelectric current from the photocathode can be observed as a large output current from the
anode of the PMT.
Gain is simply the ratio of the anode output current to the photoelectric current from the photocathode. Ideally, the gain of the
PMT is defined as δn, where n is the number of dynode stage
and δ is an average secondary emission ratio.
While the secondary electron emission ratio δ is given by
(2) Box and grid type
Good collection efficiency, good uniformity
(3) Box and linear focused type
Good collection efficiency, good uniformity, low profile
(4) Circular cage type
Fast time response, compactness
δ = A • Eα
where A is constant, E is an interstage voltage, and α is a coefficient determined by the dynode material and geometric structure. It usually has a value of 0.7 to 0.8.
When a voltage V is applied between the cathode and the
anode of the PMT having n dynode stages, gain G becomes
(5) Venetian blind type
G = δn = (A • Eα)n =
Good uniformity, large output current
(6) Fine mesh type
High immunity to magnetic fields, good uniformity, high pulse
linearity, position detection possible.
=
An
(n + 1)αn
4. ANODE
The PMT anode output is the product of photoelectric current
from the photocathode and gain. Photoelectric current is proportional to the intensity of incident light. Gain is determined by
the applied voltage on a specified voltage divider.
4.1 Luminous sensitivity
The anode luminous sensitivity is the anode output current per
incident light flux (10-10 to 10-5 lumen) from a tungsten filament
lamp operated at a distribution temperature of 2856K. This is
expressed in the unit of A/lm (amperes per lumen) at a specified anode-to-cathode voltage with a specified voltage divider.
4
(K: constant)
TPMOB0038EB
108
102
107
106
NS
I
TIV
103
ITY
109
101
AN
O
ANODE LUMINOUS SENSITIVITY (A/lm)
Also hybrid dynodes combining two of the above dynodes have
been developed. These hybrid dynodes are designed to provide the merits of each dynode type.
Vαn = K • Vαn
IN
104
Immunity to magnetic fields, high pulse linearity, position detection possible.
Compact dynode construction, fast time response, position detection possible.
n
Figure 3: Example of Gain vs. Supply Voltage
(7) Coarse mesh
(8) Metal channel type
α
{A • ( n V+ 1 ) }
100
105
10-1
104
10-2
200
300
500
700
1000
GAIN
Fast time response, high pulse linearity
SE
(1) Linear focused type
GA
There are several principal types of dynode structures. Features of each type are as follows:
DE
3.1 Dynode Types
103
1500
SUPPLY VOLTAGE (V)
Figure 3 shows gain characteristics.
Since generally PMTs have 8 to 12 dynode stages, the anode
output varies directly with the 6th to 10th power of the change
in applied voltage. The output signal of the PMT is extremely
susceptible to fluctuations in the power supply voltage, thus the
power supply should be very stable and exhibit minimum ripple, drift and temperature coefficient. Regulated high voltage
power supplies designed with this consideration are available
from Hamamatsu.
5. ANODE DARK CURRENT
6. TIME RESPONSE
A small amount of output current flows in a PMT even when it
is operated in complete darkness. This current is called the
anode dark current. The dark current and the noise resulted
from are critical factors to determin the lower limit of light detection.
The causes of dark current may be categorized as follows:
In applications where forms of the incident light are pulses, the
anode output signal should reproduce a waveform faithful to
the incident pulse waveform.
This reproducibility depends on the anode pulse time response.
(1) Thermionic emission of electrons
The time for the anode output pulse to rise from 10% to 90% of
the peak amplitude when the whole photocathode is illuminated by a delta-function light pulse.
(2) Ionization of residual gases
Residual gases inside the PMT can be ionized by the flow of
photoelectrons. When these ions strike the photocathode or
earlier stages of dynodes, secondary electrons may be emitted, thus resulting in relatively large output noise pulses. These
noise pulses are usually observed as afterpulses following the
primary signal pulses and may be a problem in detecting short
light pulses. Present PMT's are designed to minimize afterpulses.
(3) Glass scintillation
In case electrons deviating from their normal trajectories strike
the glass envelope, scintillations may occur and dark pulses
may result. To eliminate these pulses, PMT's may be operated
with the anode at high voltage and the cathode at the ground
potential. Otherwise it is useful to coat the glass bulb with a
conductive paint connected to the cathode (called HA coating:
see page 9).
(2) Electron Transit Time (refer to Figure 4)
The time interval between the arrival of a delta-function light
pulse at the photocathode and the instant when the anode output pulse reaches its peak amplitude.
(3) T.T.S. (Transit Time Spread) (refer to Figure 5)
This is also called the transit time jitter. This is the fluctuation in
transit time between individual pulses, and may be defined as
the FWHM of the frequency distribution of electron transit
times. T.T.S. depends on the number of incident photons. The
values in this catalog are measured in the single photoelectron
state.
Figure 4: Definition of Rise Time and Transit Time
DELTA-FUNCTION
LIGHT PULSE AT PHOTOCATHODE
TRANSIT TIME
Tt
10%
(4) Ohmic leakage
Ohmic leakage resulting from insufficient insulation of the glass
stem base and socket may be another source of dark current.
This is predominant when a PMT is operated at a low voltage
or low temperature.
Contamination by dirt and humidity on the surface of the tube
may cause ohmic leakage, and therefore should be avoided.
(5) Field emission
When a PMT is operated at a voltage near the maximum rating
value, some electrons may be emitted from electrodes by
strong electric fields causing dark pulses. It is therefore recommended that the tube be operated at 200 volts to 300 volts lower than the maximum rating.
The anode dark current decreases along time after a PMT is
placed in darkness. In this catalog, anode dark currents are
specified as the state after 30 minutes storage in darkness.
90%
RISE TIME
TPMOC0041EA
Figure 5: Definition of T.T.S.
FWHM=T.T.S.
Tt
FREQUENCY
Since the materials of the photocathode and dynodes have
very low work functions, they emit thermionic electrons even at
the room temperature. Most of the dark current originates from
the thermionic emissions especially from the photocathode,
and it is multiplied by the dynodes.
(1) Rise Time (refer to Figure 4)
Tt
TIME
TPMOC0042EA
(4) C.R.T. (Coincident Resolving Time)
This is one of the important parameters in high energy physics
applications and is defined as the FWHM of a coincident timing
spectrum of a pair PMT's facing each other when they detect
coincident gamma-ray emission due to positron annihilation of
a radiation source (22Na). The scintillators used are CsF, BGO
or BaF2 crystals. These PMT's can be selected for special requirements.
5
Figure 6 shows typical time response characteristics vs. applied voltage for types R2059 (51 mm dia. head-on, 12-stage,
linear-focused type).
Figure 6: Time Response Characteristics vs. Supply
Voltage
102
Figure 7: Example of Pulse Linearity Characteristic
10
DEVIATION (%)
These parameters are affected by the dynode structure and
applied voltage. In general, PMTs of the linear focused or circular cage structure exhibit better time response than that of
the box-and-grid or venetian blind structure.
TPMHB0094ED
0
2%
5%
-10
TYPE NO. : R2059
TPMOB0059EB
TRANSIT TIME
-20
100
101
102
103
OUTPUT CURRENT (mA)
101
TIME (ns)
The special voltage distribution ratios are designed to achieve
strong electric fields in the later stages of the electron multiplier.
Some types are specified with these special voltage dividers.
RISE TIME
100
8. UNIFORMITY
T. T. S.
The definition of the pulse linearity is proportionality between
the input light amount and the output current in the pulse operation mode. When intense light pulses are to be measured, it's
necessary to know the pulse linearity range of the PMT.
In this catalog, typical values of pulse linearity are specified at
two points (±2 % and ±5 % deviations from linear proportionality), as shown in Figure 7.
The two-pulse technique is employed in this measurement.
LED's are used for a pulsed light source. Its pulse width is
50ns and the repetition rate is 1 kHz.
The deviation from the proportionality is called non-linearity in
this catalog. The cause of non-linearity is mainly a space
charge effect in the later stages of an electron multiplier. This
space charge effect depends on the pulse height of the PMT
output current and the strength of electric fields between electrodes. Even if the electrical charge is small, the pulse height of
the PMT output should be considered.
Figure 8: Example of Spatial Uniformity
TOP VIEW OF
PHOTOCATHODE
a'
7. PULSE LINEARITY
a
SUPPLY VOLTAGE (V)
100
0
2000 2500 3000
50
1500
100
1000
SENSITIVITY (%)
500
Although the focusing electrodes of a PMT are designed so
that electrons emitted from the photocathode or dynodes are
collected efficiently by the first or following dynodes, some
electrons may deviate from their desired trajectories and collection efficiency is degraded. The collection efficiency varies
with the position on the photocathode from which the photoelectrons are emitted, and influences the spatial uniformity of a
photomultiplier tube. The spatial uniformity is also determined
by the photocathode surface uniformity itself.
In general, head-on type PMT's provide better spatial uniformity than side-on type PMT's because of less limitations in the
photocathode to first dynode geometry. Tubes especially designed for gamma camera applications have excellent spatial
uniformity. Example of spatial uniformity is shown in Figure 8.
SENSITIVITY (%)
50
0
a
a'
TPMHC0050EA
6
9. ANODE DARK CURRENT
10. ENVIRONMENT
In scintillation counting, there are two relevant stability characteristics for the PMT in pulse height mode operation, the long
term and the short term. In each case a 137Cs source (662 keV),
and an NaI(Tl) scintillator, and a multichannel pulse height analyzer are used. PMT's are warmed up for about one hour in the
dark with voltage applied.
10.1 Temperature Characteristics
9.1 Long Term Stability (Mean gain deviation)
This is defined as follows when the PMT is operated for 16
hours at a constant count rate of 1k s-1:
n
Σ P-Pi
i =1
Dg =
n
100
P
•
The sensitivity of the PMT varies with the temperature. Figure
10 shows typical temperature coefficients of anode sensitivity
around the room temperature for bialkali and high temp. bialkali
photocathode types. In the ultraviolet to visible region, the temperature coefficient of sensitivity has a negative value, while it
has a positive value near the longer wavelength cut-off.
Since the temperature coefficient change is large near the longer wavelength cut-off, temperature control may be required in
some applications.
Figure 10: Typical Temperature Coefficients of Anode
Sensitivity
(%)
9.2 Short Term Stability
This is the gain shift against count rate change. The tube is initially operated at about 10k s-1. The photo-peak count rate is
then decreased to approximately 1k s-1 by increasing the distance between the 137Cs source and the scintillator coupled to
the PMT.
9.3 Drift and Life Characteristics
While operating a photomultiplier tube continuously over a long
period, anode output current of the photomultiplier tube may
vary slightly with time, although operating conditions have not
changed. This change is reffered to as drift or in the case
where the operating time is 103 hours to 104 hours it is called
life characteristics. Figure 9 shows typical life characteristics.
Drift is primarily caused by damage to the last dynode by
heavy electron bombardment. Therefore the use of lower
anode current is desirable. When stability is of prime importance, the use of average anode current of 1 µA or less is recommended.
Figure 9: Examples of Life
RELATIVE ANODE CURRENT (%)
TPMHB0448EB
SUPPLY VOLTAGE:1000 V
INITIAL ANODE CURRENT:10 µA
x¯ + σ
100
x̄
TEMPERATURE COEFFICIENT (%/°C)
0.5
where P is the mean pulse height averaged over n readings, Pi
is the pulse height at the i-th reading, and n is the total number
of readings.
TPMOB0036EC
0
HIGH TEMP.
BIALKALI
BIALKALI
-0.5
200
400
600
800
WAVELENGTH (nm)
10.2 Magnetic Field
Most PMTs are affected by the presence of magnetic fields.
Magnetic fields may deflect electrons from their normal trajectories and cause a loss of gain. The extent of the loss of gain
depends on the type of the PMT and its orientation in the magnetic field. Figure 11 shows typical effects of magnetic fields on
some types of PMTs. In general, a PMT having a long path
from the photocathode to the first dynode are very sensitive to
magnetic fields. Therefore head-on types, especially of large
diameter, tend to be more adversely influenced by magnetic
fields.
When a PMT has to be operated in magnetic fields, it may be
necessary to shield the PMT with a magnetic shield case. (Hamamatsu provides a variety of magnetic shield cases.)
x¯ - σ
50
0
1
10
100
1000
10000
TIME (h)
7
For example, the shield case, of which inner diameter is 60 mm
and the thickness is 0.8 mm, can be used in a magnetic field of
around 5 mTesla without satulation. If a magnetic field strength
is more than 10 mTesla, the double shielding method is necessary for a conventional PMT, otherwise proximity mesh types
should be used. It should be noted that the magnetic shielding
effect decreases towards the edge of the shield case as shown
in Figure 12. It is suggested to cover a PMT with a shield case
longer than the PMT length by at least half the PMT diameter.
Figure 11: Typical Effects by Magnetic Fields
Perpendicular to Tube Axis
1.0
TPMOB0017EB
28 mm dia.
SIDE-ON TYPE
19 mm dia.
HEAD-ON TYPE
LINEAR-FOCUSED
TYPE DYNODE
RELATIVE OUTPUT
(
)
11. VOLTAGE DIVIDER CONSIDERATION
11.1 General
Interstage voltages for PMT dynodes are usually supplied by a
voltage divider network consisting of multiple series of resistors. Schematic diagrams of typical voltage divider networks
are illustrated in Figure 13. Circuit (a) is a basic arrangement
and (b) is for pulse operations. Figure 14 shows the response
of a PMT using the voltage divider (a) as a function of the input
light flux. The deviation from the linearity (non-linear region B)
is caused by an increase in dynode voltages resulting from the
redistribution of the decreased voltage primarily between the
last dynode and the anode. As the input light level increases,
the anode output current begins to saturate at near the value of
the current flowing through the voltage divider (region C) due to
the effect of voltage losses in the last few stages. Therefore,
the upper limit of dynamic range of the PMT is determined by
the voltage divider current. To prevent this problem, it is suggested that the voltage divider current be maintained at least
20 times the anode output current required from the PMT.
0.1
Figure 13: Schematic Diagrams of Voltage Divider Networks
(a)Basic arrangement for DC operation
51 mm dia.
HEAD-ON TYPE
BOX-AND-GRID
TYPE DYNODE
(
PHOTOCATHODE
1R
0.01
-3
-2
-1
0
ANODE
)
1
2
1R
1R
1R
1R
1R
1R
1R
1R
1R
1R
-HV
3
(b)For pulse operation
MAGNETIC FLUX DENSITY (mT)
PHOTOCATHODE
ANODE
Figure 12: Edge Effect of Magnetic Shield Case
t
LONGER than r
1R
1R
1R
1R
1R
1R
1R
1R
-HV
1R
1R
1R
C1
C2
C3
Figure 14: Response of a PMT Using Voltage Divider (a)
100
10
1
r
r
TPMOB0011EB
The proximity mesh made of non-magnetic material has been
introduced as alternate dynodes in PMT's. These types (see
page 22) exhibit much higher immunity to external magnetic
fields than the conventional PMT's. Also triode and tetrode
types (see page 22) are useful for applications at high light intensities.
8
10
TACCB0005EA
C
1.0
B
1000
ACTUAL
CURVE
0.1
0.01
0.001
0.001
IDEAL
CURVE
A
L
RATIO OF AVERAGE OUTPUT CURRENT
TO DIVIDER CURRENT
SHIELDING FACTOR
2r
TACCC0030EB
PHOTOMULTIPLIER TUBE
0.01
0.1
LIGHT FLUX (A.U.)
1.0
10
11.2 Decoupling (Charge Storage) Capacitors
12.2 External Potential
Generally high output current is required in applications where
the input light is in the form of pulses. In order to maintain dynode potentials at a constant value during pulse durations and
handle high peak currents, large capacitors are used as shown
in Figure 13 (b). The capacitor values depend on the output
charge. If linearity of better than 1 % is needed, the capacitor
value between the last dynode and the anode should be at
least 100 times the output charge per pulse, as shown in the
following formula:
If the input window or glass envelope near the photocathode is
grounded, slight conductivity of glass material causes a current
flow between the photocathode, which has a high negative potential, and ground.
This may cause electrolysis of photocathode, leading to significant deterioration.
Also this may cause noise resulted from the light flashes at the
above input window or glass envelope.
For those reasons, when designing a PMT housing with an
electrostatic or magnetic shield case, extreme care should be
required.
C > 100
I•t
V
(farads)
where I is the peak output current in amperes, t is the pulse
width in seconds, and V is the voltage across the capacitor in
volts.
Hamamatsu provides socket assemblies incorporating voltage
divider networks. They are compact, rugged, and carefully engineered to minimize electric leakage. (See page 52.)
12. CATHODE POTENTIAL
12.3 HA Coating
When the anode ground scheme is used, bringing a grounded
metallic holder or magnetic shield case near the glass envelope of PMT can cause electrons to strike the inner glass wall,
resulting in the noise.
This problem can be solved by applying a black conductive
paint around the glass envelope and connecting it to the cathode potential. Then PMT is wrapped with an insulating black
cover, as shown in Figure 16. This method is called HA coating.
Figure 16: HA Coating
12.1 General
The general technique used for voltage divider circuits is to
ground the anode with a high negative voltage applied to the
photocathode. This scheme eliminates the potential difference
between the external circuit and the anode, facilitating the connection of such circuits such as ammeters or current to voltage
conversion operational amplifiers to the PMT.
In scintillation counting, it is often impossible to use this technique, since the grounded scintillator is directly coupled to the
PMT.
CONDUCTIVE PAINT
CONNECTED TO
CATHODE PIN
INSULATING BLACK COVER
TPMHC0049EB
In such cases, it is recommended that the cathode to be grounded, as shown in Figure 15, with a high positive voltage applied
to the anode.
Figure 15: Cathode Ground Scheme
PHOTOCATHODE
13. SCINTILLATION COUNTING
ANODE
13.1 General
C
+HV
TPMOC0067EB
Using this scheme, a coupling capacitor C is used to isolate the
high positive voltage applied to the anode from the signal, making it impossible to obtain a DC signal output. If the count rate
of the PMT output pulses is high, this scheme may cause a
base line shift.
Scintillation counting is one of the most common and effective
methods in detecting radiation particles. It uses a PMT coupled
to a scintillator which produces light by incidence of radiation
particles.
In radiation particle measurement, there are two parameters
that should be measured. One is the energy of individual particle and the other is the amount of particles. When radiation
particles enter the scintillator, they produce light flashes in response to each particle. The amount of flash is proportional to
the energy of the incident particle and individual light flashes
are detected by the PMT. Consequently, the output pulses obtained from the PMT contain information on both the energy
and number of pulses, as shown in Figure 17.
9
Figure 17: Incident Particles and PMT Output
By analyzing these output pulses using a multichannel analyzer (MCA), pulse height distribution (PHD), or energy spectra, as
shown in Figure 18, are obtained. From the PHD, the number
of incident particles at various energy levels can be measured.
TIME
13.2 Energy Resolution
SCINTILLATOR
THE HEIGHT OF OUTPUT
PULSE IS PROPORTIONAL
TO THE ENERGY OF
INCIDENT PARTICLE.
CURRENT
PMT
For the energy spectrum measurement, it is very important to
have a distinct peak at each energy level. This characteristic is
evaluated as the pulse height resolution or the energy resolution
and is most significant in the radiation particle indentification.
Figure 19 shows the definition of the energy resolution using
NaI(Tl) scintillator and 137Cs γ-ray source. It is customarily stated as a percentage.
Figure 19: Definition of Pulse Height Resolution
TIME
TPMOC0039EA
(a) 55Fe+Nal(TI)
COUNTS
1000
(51 mm dia. × 2.5 mm t)
NUMBER OF PULSES
Figure 18: Typical Pulse Height Distribution (Energy Spectral)
b
a
H
H
2
PULSE HEIGHT
500
a
Energy Resolution (FWHM) = — × 100 %
b
TPMOB0088EA
0
500
1000
ENERGY
(b) 137Cs+Nal(TI)
COUNTS
10000
The following factors determin the energy resolution.
(1) Energy conversion efficiency of the scintillator
(2) Intrinsic energy resolution of the scintillator
(3) Quantum efficiency of the photocathode
(4) Collection efficiency of photoelectrons at the first dynode
(5) Secondary emission yield of dynodes (especially first dynode)
(51 mm dia. × 51 mm t)
5000
The equation of the pulse height resolution is described as follows:
0
500
1000
ENERGY
where R(E) : energy resolution
RS(E) : energy resolution of a scintillator
RP(E) : energy resolution of a PMT
(c) 60Co+Nal(TI)
10000
R(E)2 = RS(E)2 + RP(E)2
(51 mm dia. × 51 mm t)
COUNTS
RP(E)2 is described as follows:
R(E)2 =
5000
0
500
1000
ENERGY
TPMOB0087EC
10
δ
2.352
×
δ–1
Nηα
where N : mean number of incident photon
η : quantum efficiency
α : collection efficiency
δ : mean secondary emission yield of each dynode
A: Borosilicate Glass
B: UV Glass
C: Synthetic Silica
D: Bialkali Photocathode
E: High Temp. Bialkali Photocathode
F: Extended Green Bialkali Photocathode
To obtain a good energy resolution, it is important to use a
good scintillator having a high efficiency and a good intrinsic
energy resolution. It is also important to reduce a light loss between a PMT and a scintillator. For this purpose, it is useful to
couple them with silicon oil having a refractive index close to
that of the faceplate window used in the PMT.
13.3 Emission Spectrum of Scintillator
13.4 Features of Scintillators
The quantum efficiency of the PMT is one of the main factors
to determine its energy resolution. It is necessary to choose a
PMT whose spectral response matches the scintillator emission. Figure 20 shows PMT typical spectral response vs. emission spectra of scintillators. For NaI(Tl), which is the most popular scintillator, bialkali photocathode PMTs are widely used.
Figure 21 shows typical temperature responses of various scintillators. These characteristics should be considered in the actual operation.
Table 1 shows a summary of scintillator characteristics.
These data are reported by scintillator manufactures.
Figure 21: Typical Temperature Response of Various
Scintillators
Figure 20: Typical Spectral Response and Emission
Spectra of Scintillators
RELATIVE LIGHT OUTPUT (%)
100
TPMOB0033EA
TPMHB0342EC
C
F
B
10
E
A
PWO
LSO
Nal (Tl)
PLASTIC YAP
1
CsI (Tl)
BGO
100
80
60
BaF2
40
20
0.1
0
100
200
300
400
500
600
10
700
RELATIVE INTENSITY (%)
QUANTUM EFFICIENCY (%)
D
NaI (Tl)
100
80
60
BGO
CsI (Tl)
Pure CsI
40
20
-100
-60
-20
0
+20
+60
+100
+140
SCINTILLATOR TEMPERATURE (°C)
WAVELENGTH (nm)
Table 1: Summary of Scintillator Characteristics
Nal(Tl)
BGO
Csl(Tl)
Pure Csl
BaF2
GSO: Ce
Plastic
LSO: Ce
PWO
YAP: Ce
Density (g/cm3)
3.67
7.13
4.51
4.51
4.88
6.71
1.03
7.35
8.28
5.55
Lrad (cm)
2.59
1.12
1.85
1.85
2.10
1.38
40
0.88
0.87
2.70
Refractive Index
1.85
2.15
1.80
1.80
1.58
1.85
1.58
1.82
2.16
1.97
Hygroscopic
Yes
No
Slightly
Slightly
Slightly
No
No
No
No
No
Luminescence
410
480
530
310
325
430
400
420
470
380
220
310
630
30
2.0
40
15
30
20
25
70
0.7
40
(nm)
Decay time
230
300
1000
10
0.9
(nsec)
Relative Light Output
100
15
45 to 50
<10
20
11
14. METAL PACKAGE PHOTOMULTIPLIER TUBE
In general including, the development of more compact and
portable equipment has continuously progressed. This has led
to a strong demand for miniaturization of highly sensitive photodetectors like PMTs. However, it is difficult to miniaturize conventional PMTs with glass envelopes and sophisticated electrode structures.
Accordingly, PMTs have been mainly used in high-precision
photometric systems, while semiconductor sensors have been
used in general purpose, compact and portable equipments/applications. To meet the increasing needs for small
photodetectors with high sensitivity, Hamamatsu has developed subminiature PMTs (R7400 series) using a metal package in place of the traditional glass envelope. These tubes
have a size as small as semiconductor sensors, without sacrificing high sensitivity, and have the high speed response offered by conventional PMTs. The remarkable features of
R7400 series are: smallest size, fast time response, ability of
low light level detection and good immunity to magnetic fields.
Figure 22: Cross Section and Top View of R7400
Figure 23: Cross Section of Metal Channel Dynode with
Electron Trajectories
e
e
TPMHC0101EA
The R7600 series is another version of metal package PMT. It
incorporates 10 to 12 stages of metal channel dynodes into a
metal package of 26 mm × 26 mm square and 20 mm in
height. The prime features are similar to those of R7400 series,
but its effective area is 18 mm × 18 mm instead of 8 mm diameter of R7400. The dimensional outline of R7600U is shown in
Figure 24. In this figure, "U" means a tube having an insulation
plastic cover. It is necessary to prevent electric shock with
some insulation material, because a metal package has a cathode potential voltage.
EFFECTIVE PHOTOCATHODE 8.0
Figure 24: Dimensional Outline of R7600U
15.5 ± 0.2
TO-8 TYPE
METAL CASE
METAL
CHANNEL
DYNODE
30.0 ± 0.5
10.3 ± 0.2
25.7 ± 0.5
22.0 ± 0.5
0.6 ± 0.4
6.0 ± 0.5
18 MIN.
4.4 ± 0.7
12.0 ± 0.5
10.0 ± 0.2
2.54 PITCH
4 MAX.
PHOTOCATHODE
TOP VIEW
EFFECTIVE AREA
TPMHA0231EA
TOP VIEW
29- 0.45
INSULATION
COVER
SIDE VIEW
BOTTOM VIEW
TPMHA0278EI
R7400 is a subminiature PMT that incorporates an eight stages
electron multiplier constructed with stacked thin electrodes
(metal channel dynode) into a TO-8 type metal can package of
15 mm in diameter and 10 mm in height. The development of
this metal package and its unique thin electrodes have made
the fabrication of this subminiature PMT possible. The electrode structure of the electron multiplier was designed by
means of advanced computer simulation and electron trajectory analysis.
Furthermore, our long experience with micromachining technology has achieved a closed proximity assembly of these thin
electrodes. Figure 22 shows a cross section of the R7400 and
Figure 23 shows that of a metal channel dynode with simulated
electron trajectories.
12
As the metal channel dynode is a sort of an array of small linear focused dynodes, secondary electrons hardly go to the adjacent dynode channel in a process of multiplication. It is possible to make multi-anode PMTs utilizing this feature. R7600 series is offering 6 various types of anode shapes as well as single channel type. These anode shapes are categorized into 3
groups. The first group is multianode in matrix. 4 (2 × 2), 16
(4 × 4) and 64 (8 × 8) matrix channels types are available. (see
Figure 25) Those are suitable for scintillating fiber readout as
well as RICH (Ring Image CHerenkov counter). The second
group is linear anode. 16 (1 × 16) and 32 (1 × 32) linear channels types are available. (see Figure 26) Those are suitable for
coupling with slit shape scintillators and ribbon-shaped scintillating fiber bundle. The third one is crossed-plate anode. 6X +
6Y type is available. (see Figure 27) It is possible to get position information by using a center-of-gravity method, this PMT
is suitable for compact PET and radiation imaging.
Figure 25: Anode Variation of R7600 Series (1)
R7600U-00-M4
H8711
(R7600-00-M16)
H7546B
(R7600-00-M64)
Figure 26: Anode Variation of R7600 Series (2)
R5900U-00-L16
H7260
When an electron hits on the upper part of the fine mesh dynode, secondary electrons are emitted upward from the fine
mesh dynode. Those electrons return to the same dynode and
pass through it to reach to next fine mesh dynode. This process is repeated through the last dynode stage and finally electrons are multiplied 106 or more. When magnetic field is set
parallel to a tube axis, the electron trajectories are affected by
Lorentz's force and electrons make spiral movement, since the
electric field is parallel to the tube axis. Its spiral diameter is determined by the strength of magnetic field. When magnetic field
is increased, the number of electrons, which are emitted upward from the fine mesh dynode and return to the same dynode, is increased, Due to this effect, a tube gain is decreased.
Fine Mesh PMT consists of 15 to 19 stages of fine mesh dynodes. Each dynode as well as the photocathode is set in
close each other. Tube diameters from 1" to 2.5" are available.
Figure 28: Cross Section of a Fine Mesh PMT
Figure 27: Anode Variation of R7600 Series (3)
INPUT
WINDOW
FINE MESH
DYNODE
ANODE
R8520U-00-C12
* R5900 series has flange at the bottom of the metal package, whereas
R7600 series doesn't have it.
** R8520 is one of R7600 series, but it has longer length compared with
that of R7600 series.
GLASS BASE
HA COATING
TPMHC0204EB
PHOTOCATHODE
Figure 29: Details of a Fine Mesh Dynode
15. FINE MESH PHOTOMULTIPLIER TUBE
In recent years, the demand for photodetectors to be operated
in strong magnetic fields has increased, especially in the field
of high energy physics. Conventional PMTs electron trajectories are affected by magnetic fields. The gain of these PMTs is
decreased under such conditions. Therefore, it is necessary for
these PMTs to either use a light guide to send signal light to a
region outside the magnetic field or to use a magnetic shield.
The light guide and its coupling to a PMT cause loss of light
and deterioration of the timing characteristics of the signal light.
The use of magnetic shield adds cost and energy loss for the
next particle detector.
PMTs using fine mesh dynodes, they are called Fine Mesh
PMTs, have been developed as photodetectors which can be
operated in high magnetic fields over 1.5 Tesla. Other features
are fast time response and wide dynamic range. Figure 28
shows a cross section of a Fine Mesh PMT and Figure 29
shows details of a fine mesh dynode. Its mesh diameter is
around 4 µm and its pitch is approximately 13 µm.
FINE MESH
DYNODE
ELECTRON
ELECTRON
Approx. 13 µm
TPMOC0012EB
13
Selection Guide by Applications
Applications
Examples of Applicable PMT
HIGH ENERGY PHYSICS
COLLISION EXPERIMENT
R4125, R7899-01 (H8643), R5505-70 (H6152-70), R6427 (H7415),
CALORIMETER
R580 (H3178-51), R580-17 (H3178-61), R7761-70 (H8409-70), R329-02 (H6410),
R1828-01 (H1949-51), R2154-02, R5924-70 (H6617-70), R7723,
R6504-70 (H8318-70), R6091 (H6559), R1250 (H6527)
R1635 (H3164-10), R4124, R1450 (H6524), R3478 (H6612), R4998 (H6533),
TOF COUNTER
R7899-01 (H8643), R6427 (H7415), R1828-01 (H1949-51), R2083 (H2431),
R5496 (H6156-50), R7723, R4143 (H6525), R1250 (H6527)
TAGGING DETECTOR
TRACKING DETECTOR
RICH (Ring Image Cherenkov Counter)
THRESHOLD CHERENKOV COUNTER
ANY USE in High Magnetic Field
R1635 (H3164-10), R4124, R1450 (H6524), R3478 (H6612), H8711 (R7600-00-M16)
R7600U-00-M4, R5900U-00-L16, H8711 (R7600-00-M16), H7546B (R7600-00-M64),
H7260 (R7259)
R7600U-00-M4, H8711 (R7600-00-M16), H7546B (R7600-00-M64)
R2256-02 (H6521), R5113-02 (H6522), R2059 (H3177-51), R1584 (H6528)
R5505-70 (H6152-70), R7761-70 (H8409-70), R5924-70 (H6614-70),
R6504-70 (H8318-70)
R7600 series is flangeless type of R5900 series.
SOLAR NEUTRINO AND LONG BASELINE EXPERIMENT
WATER CHERENKOV COUNTER
R6594, R5912, R5912-02, R7081, R7081-20, R8055, R3600-02 (R3600-06), R7250
COSMIC RAY EXPERIMENT
GAMMA RAY TELESCOPE
R1635 (H3164-10), R2248, R4124, R2102, R6427 (H7415), R7525
FLUORESCENCE DETECTOR
R580 (H3178-51), R6231, R6232, R6233
AIRSHOWER DETECTOR
R1166 (H6520), R580 (H3178-51), R329-02 (H6410), R1828-01 (H1949-51),
R6091 (H6559), R1250 (H6527)
Models in blue are assembly type.
14
Applications
Examples of Applicable PMT
MEDICAL
GAMMA CAMERA
COMPACT GAMMA CAMERA
ANIMAL PET
WHOLE BODY PET
R1306, R6231, R6232, R1307, R1538-01, R6233, R6234, R6235, R6236, R6237
R8520U-00-C12, R2486-02, R3292-02, H8711 (R7600-00-M16),
H7546B (R7600-00-M64), H8500 (R8400)
R8520U-00-C12, R2486-02, R3292-02, H8711 (R7600-00-M16),
H7546B (R7600-00-M64), H8500 (R8400)
R1635 (H3164-10), R1450 (H6524), R7899-01 (H8643), R1548-07
SURGICAL PROBE
R1635 (H3164-10), R1166 (H6520), R8520U-00-C12, R2486-02
LIQUID SCINTILLATION COUNTER
R331, R331-05
R7600 series is flangeless type of R5900 series.
RADIATION MONITOR
SURVEY METER
AREA MONITOR
COMPACT PROBE
R1635 (H3164-10), R647-01 (H3165-10), R1924A, R7899-01 (H8643), R7400U
R1306, R6231, R329-02 (H6410), R4607-06, R6232, R1307, R6233, R877, R877-01
R1635 (H3164-10), R647-01 (H3165-10), R5611-01 (H8135), R7375-01, R1924A,
R7373A-01, R7354, R8143
2-D IMAGING MONITOR
R8520U-00-C12, R2486-02, R3292-02, H8500 (R8400)
ANY USE in HIGH TEMPERATURE
R4177-06, R3991-04, R1288A-06
ANY USE in SHOCK and VIBRATION
R4177-06, R5611-01 (H8135), R3991-04, R1924A, R1288A-06
Models in blue are assembly type.
15
List Guide for Photomultiplier Tubes
Tube
Diameter
q
w
Spectral
Response
Outline
Range (nm)
No.
/
Curve Code
Type
No.
e
Socket
&
Socket
Assembly
r
Cathode Sensitivity
t
y
u
Dynode
Blue
Structure
Q.E.
/ No. of Luminous Sens. at Peak
Typ. Index
Stages
Typ.
(CS 5-58)
(µA/lm) Typ.
(%)
q Spectral Response
The relationship between photocathode sensitivity and wavelength of input light.
Curve code corresponds to that of spectral response curve on
the inside back cover.
(Refer to section 2 on page 2 for further details.)
Anode Sensitivity
o
!0
Gain
Typ.
Luminous
Typ.
(A/lm)
Dark
Current
Typ.
(nA)
!1
Max.
(nA)
<No. of Stages>
The number of dynodes used.
(Refer to section 3 on page 4 for further details.)
t Cathode Sensitivity (Luminous)
The photoelectric current from the photocathode per incident
light flux from a tungsten filament lamp operated at 2856K.
(Refer to section 2.5 on page 3 for further details.)
w Outline No.
This number corresponds to that of PMT dimensional outline
drawing shown on later pages.
Basing diagram symbols are explained as follows:
BASING DIAGRAM SYMBOLS
Short Index
Pin
Pin
Flying
Lead
DY
G(F)
ACC
K
P
SH
IC
NC
y Cathode Blue Sensitivity Index
The photoelectric current from the photocathode per incident
light flux from a tungsten filament lamp operated at 2856K
passing through a blue filter which is Corning CS 5-58 polished
to 1/2 stock thickness.
(Refer to section 2.5 on page 3 for further details.)
All base diagrams show terminals viewed from the
base end of the tube.
Key
i
Anode to
Cathode
Supply
Voltage
(V)
: Dynode
: Grid (Focusing Electrode)
: Accelerating Electrode
: Photocathode
: Anode
: Shield
: Internal Connection (Do not use)
: No Connection (Do not use)
u QE (Quantum Efficiency)
TPMOC0068EB
e Socket & Socket Assembly
★ mark : A socket will be supplied with a PMT.
no mark : A socket will be supplied as an option.
The number in square corresponds to the outline number of
the PMT socket assembly on page 52 and 53.
The ratio of the number of photoelectrons emitted from the photocathode to the number of incident photons.
This catalog shows quantum efficiency at the peak wavelength.
(Refer to section 2.2 on page 2 for further details.)
i Anode to Cathode Voltage
The voltage indicates a standard applied voltage used to measure characteristics. The number in circles corresponds to that of
the voltage distribution ratio on page 40 and 41.
r Dynode
<Dynode Structure>
Each mark means dynode structure as follows:
LINE : linear focused
BOX : box and grid
B & L : box and linear focused
CC : circular cage
VB : venetian blind
FM : fine mesh
CM : coarse mesh
MC : metal channel
16
o Gain (Current Amplification)
The ratio of the anode output current to the photoelectric current from the photocathode.
(Refer to section 4.2 on page 4 for further details.)
!0 Anode Sensitivity (Luminous)
The output current from the anode per incident light flux from a
tungsten filament lamp operated at 2856K.
(Refer to section 4.1 on page 4 for further details.)
(at 25 °C)
Maximum Rating !2
!4
Time Response !3
Typical
Anode
Average Rise Transit T.T.S.
Pulse
to
Anode Time Time Typ.
Height
Cathode
Current Typ.
Typ. (FWHM) Resolution
Voltage
(V)
(mA)
(ns)
(ns)
(ns)
(%)
Stability !5
Long
Term
(%)
Pulse Linearity !6
Short ±2 % ±5 %
Term Deviation Deviation
(%)
(mA)
Type
No.
Note
(mA)
!1 Anode Dark Current
!4 Pulse Height Resolution (P.H.R.)
The output current from the anode measured after 30 minutes
storage in complete darkness.
(Refer to section 5 on page 5 for further details.)
The P.H.R. is measured with the combination of an NaI(Tl) scintillator and a 137Cs source as a standard measurement. If other
scintillators or γ-ray sources are used, note is attached.
(Refer to section 13.2 on page 10 and 11 for further details.)
!2 Maximum Rating
<Anode to Cathode Voltage>
The maximum anode to cathode voltages are limited by the internal structure of the PMT.
Excessive voltage causes electrical breakdown. The voltage
lower than the maximum rating should be applied to the PMT.
<Average Anode Current>
This indicates the maximum averaged current over any interval
of 30 seconds. For practical use, operating at lower average
anode current is recommended.
(Refer to section 9.3 on page 7 for further details)
!3 Time Response
<Rise Time>
The time for the anode output pulse to rise from 10 % to 90 %
of the peak amplitude.
<Electron Transit Time>
The time interval between the arrival of a delta function light
pulse at the photocathode and the instant when the anode output pulse reaches its peak amplitude.
<T.T.S. (Transit Time Spread)>
This is the fluctuation in transit time among individual pulses,
and is defined as the FWHM of the frequency distribution of
transit time.
!5 Stability
<Long Term Stability (Mean Gain Deviation)>
This is defined as follows under the operation for 16 hours at a
constant count rate of 1k s-1:
n
Σ P-Pi
i =1
Dg =
n
•
100
P
(%)
where P is the mean pulse height averaged over n readings, Pi
is the pulse height at the i-th reading, and n is the total number
of readings.
<Short Term Stability>
This is the gain shift on count rate charge. The tube is first operated at about 10k s-1. The photo-peak count rate is then decreased to about 1k s-1 by increasing the distance between the
137Cs source and the tube coupled to the NaI(Tl) scintillator.
(Refer to section 9 on page 7 for further details.)
!6 Pulse Linearity
Typical values of pulse linearity are specified at two points (±2
% and ±5 % deviation points from linear proportionality).
(Refer to section 7 on page 6 for further details.)
<C.R.T. (Coincident Resolving Time)>
This is defined as the FWHM of a coincident timing spectrum of
a pair PMT's. The scintillator used are BGO, BaF2 or CsF crystals.
(Refer to section 6 on page 5 and 6 for further details.)
17
Photomultiplier Tubes
Tube
Diameter
Type
No.
q
w
Spectral
Response
Outline
Range (nm)
No.
/
Curve Code
e
Socket
&
Socket
Assembly
r
Cathode Sensitivity
t
y
u
Dynode
Blue
Structure
Q.E.
/ No. of Luminous Sens. at Peak
Typ. Index
Stages
Typ.
(CS 5-58)
(µA/lm) Typ.
(%)
i
Anode to
Cathode
Supply
Voltage
(V)
Anode Sensitivity
o
!0
Luminous
Typ.
Gain
Typ.
!1
Dark
Current
(A/lm)
Typ.
(nA)
Max.
(nA)
10 mm (3/8 inch) to 38 mm (1-1/2 inch) Dia. Types
10 mm
(3/8")
300 to 650/A-D
q
E678-11N* z
160 to 650/C-D
q
E678-11N* z
300 to 650/A-D
e
E678-13A* x
LINE / 10
110
300 to 650/A-D
w
E678-13A* c
LINE / 10
R4177-06 300 to 650/A-E
e
E678-13E*
LINE / 10
300 to 650/A-D
r
E678-12L* v
R1450
300 to 650/A-D
t
E678-12L* v
LINE / 10
115
R3478
R1635
R2496
R647-01
13 mm
R4124
(1/2")
R1166
LINE / 8
LINE / 8
LINE / 10
25
1250 y
1.0 × 106
100
1
50
25
1250 i
1.0 × 10
100
2
50
10.0
25
1000 !5
6
1.4 × 10
150
1
2
100
10.0
25
1000 @8
1.0 × 106
100
1
15
30
4.5
12
1500 !5
5.0 × 105
15
0.5
10
26
1000 !8
1.0 × 10
110
1
5
11.0
27
1500 @4
6
1.7 × 10
200
3
50
100
100
110
10.0
10.0
10.5
6
6
300 to 650/A-D
y
E678-12L* b
LINE / 8
115
11.0
27
1700 !2
1.7 × 106
200
10
300
19 mm
R3991-04 300 to 650/A-E
(3/4")
u
E678-12A*
CC / 10
30
4.5
12
1500 @7
3.3 × 105
10
0.1
10
300 to 650/A-D
t
E678-12L* n
27
1500 !9
8.7 × 10
100
10
50
300 to 650/A-F
y
E678-12L*
LINE / 6
125
11.0
27
1500 q
8.0 × 10
1
1
10
R5611-01 300 to 650/A-D
u
E678-12A*
CC / 10
90
10.5
26
1000 @7
5.5 × 105
50
3
20
R1288A-06 300 to 650/A-E
i
E678-14C*
LINE / 10
30
4.5
12
1500 @7
3.3 × 105
10
0.1
10
R1924A
300 to 650/A-D
i
E678-14C* ⁄0
26
1000 @7
2.0 × 10
180
3
20
R4998
300 to 650/A-D
o
E678-12A*
LINE / 10
70
9.0
22
2250 !7
6
5.7 × 10
400
100
800
R5380
300 to 650/A-F
!0
E678-14C*
LINE / 6
125
11.0
27
1000 e
6.0 × 103
0.75
1
10
R5505-70 300 to 650/A-D
!1
E678-17A* ,
FM / 15
80
9.5
23
2000 %5
5.0 × 105
40
5
30
2.0 × 106
<1.7 × 106>
5.0 × 106
<2.0 × 106>
190
<160>
475
<190>
2
<2>
10
<4>
15
<20>
200
<80>
2.0 × 106
180
3
20
5.0 × 10
<2.0 × 105>
1.1 × 106
<7.9 × 105>
1.2 × 106
<1.1 × 106>
45
<19>
100
<75>
150
<140>
5
<2>
3
<2>
4
<4>
100
<40>
20
<15>
20
<20>
R4125
R5325
25 mm
(1")
LINE / 10
LINE / 10
115
90
11.0
10.5
R7899-01 300 to 650/A-D
!2
E678-12A*
LINE / 10
95
11.0
27
R6427
300 to 650/A-D
!3
E678-14C* ⁄1⁄2 LINE / 10
95
11.0
27
28 mm
R7111
(1-1/8")
300 to 650/A-D
!4
E678-14C* ⁄0
90
10.5
26
38 mm
(1-1/2")
LINE / 10
@8
@9 >
#0
#1 >
1000 @7
1500
<1500
1250
<1500
1250
<1500
o
!0 >
@1
@3 >
@5
@6 >
3
6
5
R7525
300 to 650/A-D
!5
E678-14C*
LINE / 8
95
11.0
27
R580
300 to 650/A-D
!6
E678-12A* ⁄3
LINE / 10
95
11.0
27
R580-17
300 to 650/A-F
!7
E678-12A*
LINE / 10
125
11.0
27
R980
300 to 650/A-D
!8
E678-12A* ⁄3
CC / 10
100
11.5
28
1000 @1
3.5 × 105
35
3
5
R3886
300 to 650/A-D
!9
E678-12A* ⁄3
CC / 10
90
10.5
26
1000 @1
5.0 × 105
45
3
5
185 to 650/B-D
!6
4
R7761-70 300 to 650/A-D
@0
R5330
E678-12A*
—
LINE / 6
95
11.0
27
1250 w
1.0 × 10
0.95
2
15
FM / 19
80
9.5
23
2000 %6
1.0 × 107
800
15
100
Note: The data in square bracket < > is measured with tapered voltage distribution ratio.
Please refer to page 16 for meaning of numbers in w, e and i.
18
1250
<1500
1500
<1500
5
(at 25 °C)
Maximum Rating !2
!4
Time Response !3
Typical
Anode
Average Rise Transit T.T.S.
Pulse
to
Anode Time Time Typ.
Height
Cathode
Current Typ.
Typ. (FWHM) Resolution
Voltage
Stability !5
Long
Term
Pulse Linearity !6
Short ±2 % ±5 %
Term Deviation Deviation
Note
Type
No.
(V)
(mA)
(ns)
(ns)
(ns)
(%)
(%)
(%)
(mA)
(mA)
1500
0.03
0.8
9
0.5
23/BGO *1
1.0
2.0
3
7
1500
0.03
0.7
9
0.5
23/BGO *1
1.0
2.0
3
7
1250
0.1
2.5
24
2.0
7.8
1.0
2.0
3
7
SILICA (R760) and UV (R960) types are available.
R647-01
1250
0.03
1.1
12
0.5
8.1
1.0
2.0
2
5
UV type (R4141) is available.
R4124
1800
0.02
2.0
20
—
12.0
2.0
2.0
8
13
Flying Lead type (R4177-04) is available.
R4177-06
1250
0.1
2.5
27
2.8
7.8
1.0
2.0
4
7
SILICA (R762) and UV (R750) types are available.
R1166
1800
0.1
1.8
19
0.76
7.8
1.0
2.0
4
8
R1450
1800
0.1
1.3
14
0.36
7.8
1.0
2.0
4
8
SILICA (R2076) and UV (R3479) types are available. R3478
1800
0.02
1.0
13
—
11.0
2.0
2.0
2
5
1800
0.1
2.5
16
0.85
7.8
1.0
2.0
100
170
1800
0.1
1.2
9.5
—
7.8
1.0
2.0
80
120
1250
0.1
1.5
17
0.8
8.0
1.0
2.0
1
2
1800
0.02
1.3
13
—
9.0
1.0
2.0
20
40
1250
0.1
1.5
17
0.9
7.8
1.0
2.0
30
50
Flying Lead type (R1924A-01) is available.
R1924A
2500
0.1
0.7
10
0.16
8.0
1.0
2.0
40
70
SILICA type (R5320) is available.
R4998
1800
0.1
1.6
12
—
7.5
1.0
2.0
80
120
2300
0.01
1.5
5.6
0.35
9.5
2.0
2.0
180
250
1.6
<1.6>
1.7
<1.7>
17
<16>
16
<16>
0.6
<0.7>
0.5
<0.5>
1.6
18
1.3
<1.3>
2.7
<2.7>
2.7
<2.7>
14
<14>
37
<40>
27
<40>
4.5
<4.5>
2.0
<2.0>
1800
0.1
2000
0.2
1250
0.1
1750
0.2
7.8
1.0
2.0
7.8
1.0
2.0
0.9
7.8
1.0
2.0
—
7.8
1.0
2.0
7.7
1.0
1.0
7.7
1.0
1.0
UV type (R3878) is available.
R2496
R3991-04
R4125
UV with 5-stage type (R5364) is available.
R5325
Glass Base type (R5611) is available.
R5611-01
R1288A-06
R5380
For +HV operation.
30
50
Glass Base type (R7899) is available.
<100> <150>
10
30
UV type (R7056) is available.
<100> <150>
30
R1635
R5505-70
R7899-01
R6427
R7111
50
10
30
<100> <150>
40
60
<150> <200>
40
60
<150> <200>
R7525
R580
1750
0.1
1750
0.1
1250
0.1
2.8
40
4.8
7.6
1.0
1.0
1
3
R980
1250
0.1
2.5
32
2.2
7.6
1.0
2.0
1
3
R3886
1600
0.1
2.5
25
—
7.7
1.0
2.0
80
120
R5330
2300
0.01
2.1
7.5
0.35
9.5
2.0
2.0
350
500
R580-17
For +HV operation.
R7761-70
Note 1: This data is measured with 22Na source and BGO scintillator.
19
Tube
Diameter
Type
No.
q
w
Spectral
Response
Outline
Range (nm)
No.
/
Curve Code
e
Socket
&
Socket
Assembly
r
Cathode Sensitivity
t
y
u
Dynode
Blue
Structure
Q.E.
/ No. of Luminous Sens. at Peak
Typ. Index
Stages
Typ.
(CS 5-58)
(µA/lm) Typ.
(%)
Anode Sensitivity
o
!0
i
Anode to
Cathode
Supply
Voltage
(V)
Gain
Typ.
Luminous
Typ.
(A/lm)
Dark
Current
Typ.
(nA)
!1
Max.
(nA)
51 mm (2 inch) to 508 mm (20 inch) Dia. Types
R329-02
300 to 650/A-D
@1
E678-21C* ⁄9
LINE / 12
90
10.5
26
1500 $6
<2000 $8 >
1.1 × 106
<3.0 × 106>
100
<270>
R331-05
300 to 650/A-D
@2
E678-21C* ⁄9
LINE / 12
90
10.5
26
1500 $6
1.3 × 106
120
300 to 650/A-D
@3
E678-14V ⁄6⁄7 BOX / 8
30
1000 t
2.7 × 10
30
2
20
2.0 × 107
<1.0 × 107>
1.7 × 105
<1.3 × 105>
1800
<900>
10
<8>
50
<25>
5
<5>
400
<200>
50
<50>
R1306
110
12.0
2500
<2500
1250
<1250
$0
$1 >
@1
@2 >
5
40
6
<10> <100>
200 min-1 600 min-1
*2
*2
R1828-01 300 to 650/A-D
@4
E678-20A* ⁄5
LINE / 12
90
10.5
26
R1840
300 to 650/A-D
@5
E678-14V
CM / 10
60
8.0
20
51 mm
R2083
(2")
300 to 650/A-D
@6
E678-19F*
LINE / 8
80
10.0
25
3000 !3
2.5 × 106
200
100
800
1.0 × 106
<6.0 × 105>
90
<54>
5
<3>
20
<15>
R2154-02 300 to 650/A-D
@7
E678-14V ⁄4
LINE / 10
90
10.5
26
1250 @1
<1500 @3 >
R4607-06 300 to 650/A-E
@8
E678-15B*
CC / 10
30
4.5
12
1500 @1
3.3 × 105
10
3
50
R5924-70 300 to 650/A-D
@9
FM / 19
70
9.0
22
2000 %6
1.0 × 107
700
30
200
300 to 650/A-D
#0
30
1000 u
2.7 × 10
30
2
20
R7723
300 to 650/A-D
#1
E678-21C*
LINE / 8
90
10.5
26
1750 !1
6
1.0 × 10
90
3
20
60 mm R6232
E678-14V ⁄8
B&L / 8
110
12.0
30
1000 u
2.7 × 105
30
2
20
FM / 19
70
9.0
22
2000 %6
1.0 × 107
700
50
300
30
1000 t
2.7 × 10
30
2
20
5.0 × 105
<4.0 × 105>
5.0 × 106
<5.6 × 105>
5.0 × 106
<1.0 × 107>
30
<23>
400
<45>
450
<900>
5
<5>
50
<10>
10
<30>
50
<50>
500
<50>
60
<120>
30
2
20
10
50
R6231
300 to 650/A-D
#2
64 mm
R6504-70 300 to 650/A-D
(2.5")
#3
300 to 650/A-D
#4
R1307
—
E678-14V ⁄8
—
B&L / 8
E678-14V ⁄6⁄7 BOX / 8
110
110
12.0
12.0
1250
<1250
2500
<2500
1500
<2000
$2
$3 >
#8
#9 >
$6
$8 >
5
5
R2238
300 to 650/A-D
#5
E678-14V
CM / 12
60
8.0
20
76 mm
R4143
(3")
300 to 650/A-D
#6
E678-20A*
LINE / 12
80
9.5
23
R6091
300 to 650/A-D
#7
E678-21C* ⁄9
LINE / 12
90
10.5
26
R6233
300 to 650/A-D
#8
E678-14V ⁄8
B&L / 8
110
12.0
30
1000 u
2.7 × 105
300 to 650/A-D
#9
E678-14V ¤0
27
1250 !6
4.2 × 10
40
1.4 × 107
<4.0 × 107>
1000
<2800>
R877
BOX / 10
95
11.0
5
R1250
300 to 650/A-D
$0
E678-20A* ¤1
LINE / 14
70
9.0
22
2000 %0
<2500 %1 >
127 mm
R1512
(5")
300 to 650/A-D
#9
E678-14V ¤0
VB / 10
95
11.0
27
1500 !6
1.1 × 106
100
20
100
185 to 650/B-D
$1
E678-20A* ¤1
22
2000 %0
1.4 × 10
1000
50
300
3.0 × 106
<2.0 × 106>
240
<160>
30
<20>
300
<200>
R1584
204 mm
(8")
254 mm
(10")
70
R6594
300 to 650/A-D
$2
E678-20A*
B&L / 10
80
10.0
25
R5912
300 to 650/A-D
$3
E678-20A* ¤1
B&L / 10
70
9.0
22
1500 %2
1.0 × 107
700
50
700
R5912-02 300 to 650/A-D
$3
E678-20A*
B&L / 14
70
9.0
22
1700 %4
1.0 × 109
70 000
1000
5000
300 to 650/A-D
$4
E678-20A* ¤1
B&L / 10
80
10.0
25
1500 %2
1.0 × 10
800
50
700
R7081-20 300 to 650/A-D
$4
E678-20A*
B&L / 14
80
10.0
25
1700 %4
1.0 × 109
80 000
1000
5000
300 to 650/A-D
$5
E678-20A*
B&L / 10
60
8.0
20
1500 %3
1.0 × 107
600
200
1000
R3600-02 300 to 650/A-D
$6
E678-20A*
VB / 11
60
8.0
20
2000 #6
1.0 × 107
600
200
1000
300 to 650/A-D
$7
20
2000 %3
1.0 × 10
600
200
1000
R7081
R7250
E678-20A*
B&L / 10
60
Note: The data in square bracket < > is measured with tapered voltage distribution ratio.
Please refer to page 16 for meaning of numbers in w, e and i.
20
9.0
1500 #2
<1500 #3 >
332 mm
R8055
(13")
508 mm
(20")
LINE / 14
7
50
300
<300> <1800>
8.0
7
7
(at 25 °C)
Maximum Rating !2
!4
Time Response !3
Typical
Anode
Average Rise Transit T.T.S.
Pulse
to
Anode Time Time Typ.
Height
Cathode
Current Typ.
Typ. (FWHM) Resolution
Voltage
Stability !5
Long
Term
Short ±2 % ±5 %
Term Deviation Deviation
(V)
(mA)
(ns)
(ns)
(ns)
(%)
(%)
(%)
2700
0.2
2.6
<2.7>
48
<40>
1.1
<1.1>
7.6
1.0
1.0
2500
0.2
2.6
48
1.1
—
—
—
1500
0.1
7.0
60
—
6.3 (8.5) *3
0.5
0.5
1.3
<1.7>
5.0
<5.0>
28
0.55
<32> <0.55>
15
0.7
<17> <1.3>
Pulse Linearity !6
(mA)
15
30
SILICA (R2256-02) and UV (R5113-02) types are available. R329-02
<100> <200>
15
30
SILICA type (R331) is available.
R331-05
1
5
K-FREE type (R1306-15) is available.
R1306
100
200
SILICA (R2059) and UV (R4004) types are available. R1828-01
<250> <500>
80
200
R1840
<200> <400>
0.2
1500
0.1
3500
0.2
0.7
16
0.37
1750
0.1
3.4
<3.4>
31
<33>
3.6
<3.6>
7.6
1.0
1.0
1800
0.02
2.5
29
—
10.0
2.0
2.0
1
5
2300
0.1
2.5
9.5
0.44
9.5
2.0
2.0
500
700
1500
0.1
5.0
48
11.7
6.3 (8.5) *3
0.5
0.5
5
1.0
1.0
8.5
0.5
1.0
7.8
1.0
2.0
Type
No.
(mA)
3000
7.8
Note
100
150
SILICA type (R3377) is available.
50
70
Glass Base type (R3149) is available.
<150> <200>
R2083
R2154-02
R4607-06
For +HV operation.
R5924-70
10
Flying Lead type (R6231-01) is available.
R6231
R7723
2000
0.2
1.6
30
1.7
7.6
1.0
1.0
80
120
10-stage type (R7724) is available.
12-stage type (R7725) is available.
1500
0.1
6.0
52
12.2
6.3 (8.5) *3
0.5
0.5
5
10
Flying Lead type (R6232-01) is available.
R6232
2300
0.1
2.7
11
0.47
9.5
2.0
2.0
700
1000
For +HV operation.
R6504-70
1500
0.1
8.0
64
—
6.3 (8.5) *3
0.5
0.5
1
5
K-FREE type (R1307-07) is available.
R1307
5.5
<5.5>
1.8
<1.8>
2.6
<2.3>
17
<21>
32
<36>
48
<40>
0.8
<2.0>
0.6
<0.6>
2
<1.5>
1500
0.1
3000
0.2
2500
0.2
1500
0.1
6.0
52
1500
0.1
10.0
3000
0.2
2.5
<2.2>
2000
0.1
3000
200
500
<500> <650>
100
180
UV type (R4885) is available.
<150> <250>
40
60
<80> <110>
R2238
8.5
0.5
1.0
7.8
1.0
1.0
7.8
1.0
1.0
12.2
6.3 (8.5) *3
0.5
0.5
90
—
8.0
0.5
0.5
54
<53>
1.2
<1.2>
8.3
1.0
1.0
7.0
82
—
8.0
0.5
1.0
5
20
R1512
0.2
2.5
54
1.2
—
—
—
100
150
R1584
2000
0.1
3.5
<3.5>
45
<45>
1.5
<1.5>
—
—
—
2000
0.1
3.8
55
2.4
—
—
—
20
40
R5912
2000
0.1
4.0
68
2.8
—
—
—
40
70
R5912-02
2000
0.1
4.3
63
2.9
—
—
—
20
40
R7081
2000
0.1
4.5
78
3.3
—
—
—
40
70
R7081-20
2500
0.1
6.0
100
3.4
—
—
—
60
80
R8055
2500
0.1
10
95
5.5
—
—
—
20
40
R3600-02
2500
0.1
7.0
110
3.5
—
—
—
60
80
R7250
R4143
R6091
5
10
Flying Lead type (R6233-01) is available.
R6233
10
20
K-FREE type (R877-01) is available.
R877
100
150
<160> <250>
30
50
<100> <150>
R1250
R6594
Note 2: This data is a value of coincidental background noise.
Note 3: This data in parenthese is measured with 57Co.
21
Tube
Diameter
Type
No.
q
w
Spectral
Response
Outline
Range (nm)
No.
/
Curve Code
e
Socket
&
Socket
Assembly
r
Cathode Sensitivity
t
y
u
Dynode
Blue
Structure
Q.E.
/ No. of Luminous Sens. at Peak
Typ. Index
Stages
Typ.
(CS 5-58)
(µA/lm) Typ.
(%)
i
Anode to
Cathode
Supply
Voltage
(V)
Anode Sensitivity
o
!0
Luminous
Typ.
Gain
Typ.
!1
Dark
Current
(A/lm)
Typ.
(nA)
Max.
(nA)
Metal Package Photomultiplier and Assemblies
16 mm R7400U 300 to 650/A-D
TO-8
type R7400U-06 160 to 650/C-D
$8
E678-12M ¤2¤3 MC / 8
$9
E678-12M ¤2¤3 MC / 8
R7600U
30 mm
R7600U
Square
-00-M4
type
R5900U
-00-L16
300 to 650/A-D
%0
E678-32B ¤4
MC / 10
70
8.0
300 to 650/A-D
%1
E678-32B ¤5
MC / 10
70
300 to 650/A-D
%2
E678-32B ¤6
MC / 10
70
H8711
Assemblies
300 to 650/A-D P51@8
—
70
70
MC / 12
80
800
r
7.0 × 105
50
0.2
2
800
r
7.0 × 10
50
0.2
2
20
800
@0
6
2.0 × 10
140
2
20
8.0
20
800
@0
2.0 × 106
140
0.5
5
8.5
21
800
!5
4.0 × 106
280
0.2
2
800
$4
3.5 × 10
280
0.8
—
8.0
8.0
8.5
21
21
21
5
6
H7546B
300 to 650/A-D P51@9
—
MC / 12
80
8.5
21
800
$5
3.0 × 10
24
0.2
—
H7260
300 to 650/A-D P51#0
—
MC / 10
70
8.5
21
800
!5
2.0 × 106
140
0.2
2
H8500
300 to 650/A-D P51#1
—
MC / 12
55
7.5
21
1000 $9
1.0 × 106
55
32
100
FM / 15
80
9.5
23
2000 %5
5.0 × 105
40
5
30
5
Fine Mesh Photomultipliers
25 mm
(1")
38 mm
(1.5")
51 mm
(2")
64 mm
(2.5")
E678-17A* ,
R5505-70 300 to 650/A-D
!1
R7761-70 300 to 650/A-D
@0
—
FM / 19
80
9.5
23
2000 %6
1.0 × 107
800
15
100
R5924-70 300 to 650/A-D
@9
—
FM / 19
70
9.0
22
2000 %6
1.0 × 107
700
30
200
R6504-70 300 to 650/A-D
#3
7
—
FM / 19
70
9.0
22
2000 %6
1.0 × 10
700
50
300
Square, Rectangular Shape Photomultipliers
10 mm
R2248
(3/8")
13 mm
R2102
(1/2")
300 to 650/A-D
%3
E678-11N* z
LINE / 8
95
9.5
23
1250 y
1.1 × 106
100
1
50
300 to 650/A-D
%4
E678-13A* x
LINE / 10
100
9.5
23
1000 !5
1.0 × 106
100
1
15
300 to 650/A-D
%5
E678-14V ⁄8
30
1000 u
2.7 × 10
30
2
20
76 mm
R6237
300 to 650/A-D
(3")
25 mm
R1548-07 300 to 650/A-D
(1"Dual)
%6
E678-14V ⁄8
B&L / 8
110
12.0
30
1000 u
2.7 × 10
30
2
20
%7
E678-17A* m
LINE / 10
80
9.5
23
1250 #0
2.5 × 106
200
20
250
60 mm R6236
B&L / 8
110
12.0
5
5
Hexagonal Shape Photomultipliers
60 mm R1538
300 to 650/A-D
%8
E678-14V ⁄7
BOX / 8
110
12.0
30
1000 t
2.7 × 105
30
2
20
60 mm R6234
300 to 650/A-D
%9
E678-14V ⁄8
B&L / 8
110
12.0
30
1000 u
2.7 × 105
30
2
20
76 mm
R6235
(3")
300 to 650/A-D
^0
E678-14V ⁄8
B&L / 8
110
12.0
30
1000 u
2.7 × 105
30
2
20
2π Shape Photomultipliers
19 mm
R7375-01 300 to 650/A-D
(3/4")
25 mm
R7373A-01 300 to 650/A-D
(1")
28 mm
(1-1/8")
^1
E678-12A*
CC / 10
90
10.5
26
1000 @7
1.1 × 106
100
3
20
^2
E678-12A*
LINE / 10
90
10.5
26
1000 @7
1.1 × 106
100
3
20
R7354
300 to 650/A-D
^3
E678-14C*
B&L / 9
90
10.5
26
1000 !4
1.5 × 106
120
2
10
R8143
300 to 650/A-D
^4
E678-14C*
BOX / 11
90
10.5
26
1000 #5
2.2 × 106
200
2
10
Note: Please refer to page 16 for meaning of numbers in w, e and i.
22
(at 25 °C)
Maximum Rating !2
!4
Time Response !3
Typical
Anode
Average Rise Transit T.T.S.
Pulse
to
Anode Time Time Typ.
Height
Cathode
Current Typ.
Typ. (FWHM) Resolution
Voltage
Stability !5
Long
Term
Pulse Linearity !6
Short ±2 % ±5 %
Term Deviation Deviation
Note
Type
No.
(V)
(mA)
(ns)
(ns)
(ns)
(%)
(%)
(%)
(mA)
(mA)
1000
0.1
0.78
5.4
0.23
—
1.0
2.0
15
30
1000
0.1
0.78
5.4
0.23
—
1.0
2.0
15
30
900
0.1
1.4
8.8
0.26
—
1.0
2.0
30
60
UV type (R7600U-03) is available.
900
0.1
1.2
8.8
0.32
—
—
—
30
60
(see note 4)
900
0.1
0.60
7.4
0.18
—
—
—
0.8
1.2
(see note 4)
1000
0.017
0.83
10.9
0.30
—
—
—
0.5
1
(see note 4), Assembly with divider network
H8711
1000
0.018
1.0
10.9
0.30
—
—
—
0.3
0.6
(see note 4), Assembly with divider network
H7546B
900
0.1
0.60
6.8
0.18
—
—
—
0.6
0.8
(see note 4), Assembly with divider network
H7260
1100
0.1
0.8
6.0
0.4
—
—
—
1
2
(see note 4), Assembly with divider network
H8500
2300
0.01
1.5
5.6
0.35
9.5
2.0
2.0
180
250
For +HV operation.
R5505-70
2300
0.01
2.1
7.5
0.35
9.5
2.0
2.0
350
500
For +HV operation.
R7761-70
2300
0.1
2.5
9.5
0.44
9.5
2.0
2.0
500
700
For +HV operation.
R5924-70
2300
0.1
2.7
11
0.47
9.5
2.0
2.0
700
1000
For +HV operation.
R6504-70
1500
0.03
0.9
9.0
0.6
23/BGO*1
1.0
2.0
3
7
R2248
1250
0.1
2.5
24
2.2
8.1
1.0
2.0
3
7
R2102
1500
0.1
6.0
52
12.2
6.3 (8.5)*3
0.5
0.5
5
10
Flying Lead type (R6236-01) is available.
R6236
1500
0.1
6.0
52
12.2
6.3 (8.5)*3
0.5
0.5
5
10
Flying Lead type (R6237-01) is available.
R6237
1750
0.1
1.8
20
1.0
20/BGO*1
1.0
2.0
10
15
1500
0.1
8.0
60
—
6.3 (8.5)*3
0.5
0.5
1
5
Flying Lead type (R1538-01) is available.
R1538
1500
0.1
6.0
52
12.2
6.3 (8.5)*3
0.5
0.5
5
10
Flying Lead type (R6234-01) is available.
R6234
1500
0.1
6.0
52
12.2
6.3 (8.5)*3
0.5
0.5
5
10
Flying Lead type (R6235-01) is available.
R6235
1250
0.1
1.5
17
0.8
8
1.0
2.0
1
2
R7375-01
1250
0.1
2
19
1.1
7.8
1.0
2.0
15
30
R7373A-01
1500
0.1
11
33
4.5
8
1.0
2.0
8
10
R7354
1250
0.1
25
72
—
8
1.0
2.0
0.2
0.5
R8143
UV type (R7400U-03) is available.
R7400U
R7400U-06
R7600U
R7600U
-00-M4
R5900U
-00-L16
R1548-07
22Na
Note 1: This data is measured with
source and BGO scintillator.
Note 3: This data in parenthese is measured with 57Co.
Note 4: Dark current, time response and pulse linearity data is typical value for channel.
23
Dimensional Outline and Basing Diagrams
For Photomultiplier Tubes
q R1635, R2496
w R4124
13.5 ± 0.5
A
8 MIN.
FACEPLATE
e R647-01, R4177-06
A
10 MIN.
FACEPLATE
10 MIN.
FACEPLATE
DY5
45.0 ± 1.5
8
4
PHOTOCATHODE
9 DY4
DY3 3
10 MAX.
1
IC
DY10
PHOTOCATHODE
8
5
DY3
3
2
1
10 DY6
DY7 4
11
DY5 3
DY4
DY2
13
K
IC
13 PIN BASE
7
DY8
8
DY6
9
10 DY4
11 DY2
2
DY3
12
1
IC
13
K
DY1
SHORT PIN
SHORT PIN
DY10
5
12
DY1
P
6
DY9
DY8
9
DY5 4
10
DY2
11
K
2
DY1
11 PIN BASE
DY6
7
6
DY7
SHORT PIN
13 MAX.
PHOTOCATHODE
DY8
7
50 ± 2
DY7
5
P
DY9
B
P
6
13 PIN BASE
9.7 ± 0.4
R2496
10.5 ± 0.5
13 MAX.
A
R1635
A
13.5 ± 0.5
71 ± 2
R4177-06
14.5 ± 0.7
61 ± 2
R2496 has a plano-concave faceplate.
TPMHA0343EB
r R1166
TPMHA0102EA
t R1450, R4125
TPMHA0120EA
y R3478, R5325
18.6 ± 0.7
18.6 ± 0.7
15 MIN.
FACEPLATE
18.6 ± 0.7
15 MIN.
FACEPLATE
9 DY4
10 DY2
1
K
12
DY3
DY1
DY9 4
9 DY4
DY7 3
10 DY2
11
2
DY5
1
SHORT PIN
9 DY4
10 DY2
11
2
DY5
1
K
12
DY1
SHORT PIN
DY1
R 3478
13 MAX.
13 MAX.
DY6
8
DY7 3
SHORT PIN
12 PIN BASE
7
IC 4
DY3
12 PIN BASE
12 PIN BASE
6
5
K
12
DY3
PHOTOCATHODE
R3478
R5325
DY3
13 MAX.
DY5
88 ± 2
11
2
PHOTOCATHODE
DY8
7
DY6
8
A
DY9 4
DY7 3
DY10
6
P
5
88 ± 2
PHOTOCATHODE
DY8
7
DY6
8
DY8
IC
15 MIN.
FACEPLATE
P
DY10
6
P
5
B
R647-01
A
65 ± 2
60 ± 2
DY5
6
P
7
5
8
DY6
IC 4
9 IC
IC 3
10 IC
2
DY1
1
12
K
11
DY4
DY2
SHORT PIN
R 5325
TPMHA0344EA
25.4 ± 0.5
FACEPLATE
26 ± 1
FACEPLATE
22 MIN.
P
6
13
DY2
14
DY1
45 MIN.
13 MAX.
1
K
BOTTOM VIEW
P
6
DY9
DY10
A
R5611-01
DY3
A Temporary Base Removed
IC
9
10 DY10
DY5 4
11 DY8
DY3 3
12 DY6
13
DY4
14
DY2
2
1
P
PHOTOCATHODE
DY9 5
DY5
HA COATING
SHORT PIN
SMA
CONNECTOR
DY3
DY2
17
2
G
1 18
DY1
K
B Bottom View
11
2
12
12 PIN BASE
JEDEC
No. B12-43
DY2
K
B
30 ± 1.5
TPMHA0117EB
TPMHA0040EC
P
DY9 5
DY7 4
(Acc)
DY5 3
DY3
37.3 ± 0.5
24
15 DY4
16
3
A
10 DY4
1
DY10
DY8
13
14 DY6
DY7 4
(Acc)
9 DY6
DY1
12
DY8
DY7 4
28 ± 1.5
IC
8
8
DY5 3
R3991-04
7
DY7 5
DY1
14 PIN
GLASS BASE
7
5
12PIN BASE
JEDEC No.B12-43
DY4
6
K
B
37.3 ± 0.5
PHOTOCATHODE
11 DY6
12
2
DY3
B
DY9
13 MAX.
A
10 DY8
DY7 4
DY5 3
A
SEMIFLEXIBLE
LEADS
P
DY10
9
5
43.0 ± 1.5
DY9
PHOTOCATHODE
20 MIN.
71 ± 1
TEMPORARY BASE
REMOVED
A
15 MIN.
FACEPLATE
o R4998
52 MIN.
18.6 ± 0.7
i R1288A-06, 1924A
13 MAX.
u R3991-04, R5611-01
TPMHA0431EB
TPMHA0307EA
DY10
6
DY8
7
8 DY6
9 DY4
2
1
DY1
10 DY2
11
12
G
K
TPMHA0093EC
(Unit: mm)
!0 R5380
!1 R5505-70
25.8 ± 0.7
FACEPLATE
PHOTOCATHODE
HA COATING
13 DY 10
2
K
13 MAX.
17 PIN BASE
A TEMPORARY BASE REMOVED
DY10
DY8
12
13 DY6
14
15 DY4
P
PHOTOCATHODE
7
DY9
14 DY 8
15 DY 6
16
DY 4
17
DY 2
1
DY 1
SHORT PIN
14 PIN BASE
DY 7 5
DY 5 4
DY 3 3
22 MIN.
FACEPLATE
6
DY7 5
16 DY2
DY5 4
3
DY3
18 17
DY1 K
SHORT PIN
13 MAX.
IC IC
P 7 8
IC
9
DY 5 6
5
10 IC
DY 3 4
11 IC
12 DY 6
DY 1 3
2
13
1
14 DY 4
K
DY 2
IC
DY 15 P
DY 13
9 10 DY 14
DY 11 7 8
11
12 DY 12
DY 9 6
40.0 ± 1.5
51 ± 1.5
PHOTOCATHODE
25.40 ± 0.25
17.5 MIN.
13 MAX.
20 MIN.
68 ± 1
25.4 ± 0.5
FACEPLATE
!2 R7899-01
B BOTTOM VIEW
A
P
6
55 MIN.
DY9
12 PIN BASE
JEDEC
No. B12-43
5
DY7
4
DY10
DY8
7
8
9 DY6
DY5 3
10 DY4
11
DY2
12
K
2
DY3
1
DY1
B
37.3 ± 0.5
TPMHA0070EA
!3 R6427
!4 R7111
!5 R7525
28.5 ± 0.5
25 MIN.
FACEPLATE
6
11 DY4
DY5 3
12 DY2
13
K
14
DY1
DY3
2
1
IC
IC
9
10 DY10
DY5 4
PHOTOCATHODE
DY5 4
12 DY6
13
DY4
14
DY2
DY3 3
2
1
K
TPMHA0450EB
!8 R980
39 ± 1
38 ± 1
FACEPLATE
34 MIN.
34 MIN.
DY10
6
DY8
8
DY7 4
PHOTOCATHODE
PHOTOCATHODE
9 DY6
10 DY4
DY5 3
DY2
P
6
DY9
DY10
7
5
109 ± 2
127 MAX
K
8
DY7 4
9 DY6
DY5 3
10 DY4
DY3
11
2
1
DY1
12 PIN BASE
JEDEC
No. B12-43
DY3
DY8
DY2
12
K
99 ± 2
12
DY8
8
DY7 4
127 MAX.
1
DY1
7
5
10 DY4
11
2
6
DY9
9 DY6
DY5 3
DY10
P
7
5
109 ± 2
38 ± 1
34 MIN.
FACEPLATE
DY3
1
IC
TPMHA0506EA
!7 R580-17
P
2
13 MAX.
13 MAX.
TPMHA0387EA
DY9
DY3
SHORT PIN
14 PIN BASE
PHOTOCATHODE
11 DY4
12 DY2
13
K
14
DY1
IC 3
SHORT PIN
!6 R580, R5330
P DY8
DY6
7 8
9
10 IC
6
DY7 5
11 DY8
DY1
14 PIN BASE
FACEPLATE
25 MIN.
IC
DY7 5
SHORT PIN
14 PIN BASE
6
IC
8
116 MAX.
85 ± 2
DY9 5
DY7 4
DY9
PHOTOCATHODE
P
7
13 MAX.
NC
PHOTOCATHODE
DY10
DY8
7 8
9
10 DY6
FACEPLATE
43.0 ± 1.5
P
28.5 ± 0.5
25 MIN.
85 ± 2
28.5 ± 0.5
FACEPLATE
TPMHA0474EA
TPMHA0236EA
11
2
1
DY1
12
DY2
K
12 PIN BASE
JEDEC
No. B12-43
37.3 ± 0.5
37.3 ± 0.5
37.3 ± 0.5
12PIN BASE
JEDEC No.B12-43
TPMHA0121EA
TPMHA0116EA
TPMHA0228EA
25
!9 R3886
@0 R7761-70
39 ± 1
38.0 ± 0.7
34 MIN.
FACEPLATE
A Temporary Base Removed
DY10
9
DY8
10
11 DY6
P
6
63.5 ± 1.5
DY9 5
12 DY4
DY7 4
13 DY2
DY5 3
DY3
HA COATING
2
15
K
1
DY1
B Bottom View
A
DY9
70 MIN.
13 MAX.
P
12 PIN BASE
JEDEC
No. B12-43
SEMIFLEXIBLE
LEADS 0.7
DY10
6
7
5
DY8
8
DY7 4
DY5
DY17 DY19 P
DY18
DY15
10 11 12
13 DY16
9
DY13
8
14
DY11
7
15 DY14
DY9 6
16 DY12
17 DY10
DY7 5
4
18
DY5
DY8
19
3
DY3
2
20 DY6
1
21
DY4
DY1
K
DY2
PHOTOCATHODE
50 ± 2
PHOTOCATHODE
27 MIN.
9 DY6
10
3
DY4
27
11
2
DY3
13 MAX.
FACEPLATE
1
12
DY1
K
DY2
B
37.3 ± 0.5
TPMHA0104EA
@1 R329-02
TPMHA0469EB
@2 R331-05
53.0 ± 1.5
FACEPLATE
53.0 ± 1.5
FACEPLATE
46 MIN.
46 MIN.
SH IC DY10
DY8
IC
10 11 12
DY12
13
9
DY6
14
8
P 7
15 DY4
LIGHT
TIGHT SHIELD
DY11 6
DY9 5
4
DY7
3
2
DY5
1
DY3
DY1
126 ± 2
PHOTOCATHODE
SH IC DY10
IC
DY8
DY12 9 10 11 12 13
DY6
14 DY4
P 8
15
7
DY11 6
16 DY2
DY9 5
17 G
18 IC
DY7 4
19
3
20 IC
2
DY5
1 21
DY3
IC
DY1
K
127 ± 2
HA COATING
50.0
±
0.2
PHOTOCATHODE
HA COATING
16 DY2
17 G
18
IC
19
IC
21 20
K
IC
*CONNECT SH TO DY5
21 PIN BASE
13 MAX.
21 PIN BASE
13 MAX.
*CONNECT SH TO DY5
TPMHA0123EE
@3 R1306
TPMHA0072EE
@4 R1828-01
53.0 ± 1.5
51.0 ± 0.5
FACEPLATE
46 MIN.
114 ± 2
137 MAX.
PHOTOCATHODE
DY8
IC
8
9
10 IC
DY4 4
11 P
DY3 3
12 IC
13
G
14
K
DY2
2
1
DY1
46 MIN.
PHOTOCATHODE
170 ± 3
DY7
DY6
7
6
DY5 5
HA COATING
192 MAX.
FACEPLATE
P DY12
IC
DY10
DY11 9 10 11 12
DY8
13 DY6
DY9 8
14
7
DY7 6
15 DY4
16 DY4
DY5 5
17 DY2
IC 4
18
3
DY3
19 IC
2
20 G1
(G2) & DY1 1
K
IC
56.5 ± 0.5
14 PIN BASE
JEDEC No. B14-38
20 PIN BASE
JEDEC
No. B20-102
52.5 MAX.
TPMHA0089EC
26
TPMHA0064EC
(Unit: mm)
@5 R1840
@6 R2083
TEMPORARY BASE
REMOVED
P
10
FACEPLATE
DY10
55 ± 1
13 MAX.
DY8 5
SEMIFLEXIBLE
LEADS
13 DY7
DY6 3
DY4
65 MIN.
A
2
HA COATING
B
P
P
DY9
DY7
8
9
10 DY5
7
DY8 5
G1
K
SHORT PIN
SMA
CONNECTOR
12 IC
19
DY8
DY6
13
DY4
14
15 DY4
16 DY2
17
IC
18
13
2
IC
12
6
DY7 5
DY5 4
3
DY3
2
1
G2 & DY1
ACC
19 PIN BASE
11 DY3
DY4 3
9 10 11
8
7
BOTTOM VIEW
DY6 4
14PIN BASE
JEDEC No.B14-38
NC NC NC
16
1 18 17 DY3
DY2
K DY1
6
56.5 ± 0.5
PHOTOCATHODE
15 DY5
DY10
B
46 MIN.
12 DY9
6
PHOTOCATHODE
53.0 ± 1.5
FACEPLATE
121 ± 2
A
46 MIN.
13 MAX.
51.0 ± 0.5
1
DY2
DY1
14
K
TPMHA0095EB
@7 R2154-02
TPMHA0185EC
@8 R4607-06
51.0 ± 0.5
52 ± 1
46 MIN.
FACEPLATE
DY7
7
6
DY5 5
DY8
DY9
8
9
10 DY10
14 PIN BASE
JEDEC
No. B14-38
12 IC
DY9
1
DY1
IC
14
DY5
K
DY3
15 PIN BASE
7
6
8
5
DY10
9
DY8
10
DY6
11
DY7 4
13
2
DY2
P
11 P
DY3 3
147 MAX.
124 ± 2
DY4 4
IC
IC
PHOTOCATHODE
80 ± 2
DY6
PHOTOCATHODE
46 MIN.
13 MAX.
FACEPLATE
12 DY4
3
2
1
DY1
13 DY2
14
IC
15
K
SHORT PIN
56.5 ± 0.5
TPMHA0296EB
@9 R5924-70
#0 R6231
51.0 ± 0.5
52 ± 1
FACEPLATE
39 MIN.
P
DY19 11
DY17 10
9
DY18 DY16
DY14
14 15
16 DY12
17 DY10
18
DY8
DY15 8
DY13 7
6
DY11 5
DY9 4 3
2 1 26
DY7
DY5 DY3 DY1 K
SEMIFLEXIBLE
LEADS 0.7
DY5
DY6
7
6
DY4 5
19
20 DY6
21 DY4
22
DY2
13 MAX.
HA COATING
PHOTOCATHODE
90 ± 3
50 ± 2
PHOTOCATHODE
46 MIN.
113 MAX.
FACEPLATE
TPMHA0003EC
IC
9
10 DY7
11 DY8
DY3 4
DY2 3
IC
IC
8
2
1
DY1
12 P
13
G
14
K
56.5 ± 0.5
14 PIN BASE
JEDEC No. B14-38
31
TPMHA0490EA
TPMHA0388EB
27
#1 R7723
#2 R6232
52 ± 1
FACEPLATE
59.5 ± 0.5
FACEPLATE
46 MIN.
55 MIN.
DY5
PHOTOCATHODE
DY6
7
6
IC
8
IC
9
DY4 5
21 PIN BASE
PHOTOCATHODE
11 DY8
DY2 3
123 MAX.
100 ± 3
DY3 4
51.5 ± 1.5
2
1
DY1
IC
12 P
13
G
14
K
14 PIN BASE
JEDEC
No. B14-38
13 MAX.
112 ± 2
IC IC DY6
IC
IC
10 11 12 13 IC
DY8
9
14 DY4
P 8
15
7
DY7 6
16 DY2
DY5 5
17 IC
18
4
IC
IC
19
3
20
2
IC
IC
1 21
DY3
IC
DY1
K
10 DY7
56.5 ± 0.5
TPMHA0509EC
#3 R6504-70
TPMHA0510EA
#4 R1307
64 ± 1
76.0 ± 0.8
SEMIFLEXIBLE
LEADS 0.7
DY7
7
6
DY5 5
PHOTOCATHODE
DY2
DY11 5
DY9 4 3
2 1 26
DY7
DY5 DY3
DY1 K
13 MAX.
HA COATING
DY6
19
20 DY6
21 DY4
22
51.5 ± 1.5
14 PIN BASE
JEDEC
No. B14-38
150 MAX.
55 ± 2
9
DY15 8
7
DY13
6
70 MIN.
127 ± 3
P
DY19 11
DY17 10
PHOTOCATHODE
FACEPLATE
DY18 DY16
DY14
14 15
16 DY12
17 DY10
18
DY8
51 MIN.
FACEPLATE
DY8
IC
8
9
10 IC
DY4 4
11 P
DY3 3
12 IC
13
G
14
K
DY2
2
1
DY1
38
56.5 ± 0.5
TPMHA0336EA
#5 R2238
TPMHA0078EA
#6 R4143
76.0 ± 0.8
77.0 ± 1.5
TEMPORARY BASE
REMOVED
PHOTOCATHODE
DY10 7
DY8 6
70 MIN.
14PIN BASE
JEDEC No. B14-38
7
DY7 6
PHOTOCATHODE
DY5 5
BOTTOM VIEW
DY12
DY10
6
7
5
HA
COATING
DY11
DY9
8
9
10 DY7
DY6 3
2
1
DY2
20
14
15 NC
16 DY4
17 DY2
18
19 NC
K
G1
20 PIN BASE
JEDEC
No. B20-102
11 DY5
DY8 4
DY4
NC 4
3
DY3
2
1
G2 & DY1
IC
16 DY5
P
56.5 ± 0.5
DY12
DY10
NC P
DY11
DY8
9 10 11 12
13
8
DY9
DY6
DY11
DY9
13
14 DY7
18
1 20 19
DY3
DY1
DY 2
B
B
12
192 ± 5
55.0 ± 1.5
13 MAX.
11
9
4
DY6
3
DY4
A
65 MIN.
P
DY12
SEMIFLEXIBLE
LEADS
FACEPLATE
215 MAX.
A
70 MIN.
FACEPLATE
12 DY3
13
DY1
14
K
53.5 MAX.
TPMHA0076EC
28
TPMHA0112EB
(Unit: mm)
#7 R6091
#8 R6233
76.0 ± 0.8
76 ± 1
FACEPLATE
FACEPLATE
65 MIN.
70 MIN
SH IC DY10
IC
DY8
DY12 9 10 11 12 13
DY6
14
P 8
DY4
3
2
DY5
1
DY3
DY1
15
16 DY2
17 G
18 IC
19
IC
21 20
K
PHOTOCATHODE
14 PIN BASE
JEDEC
No. B14-38
IC
51.5 ± 1.5
100 ± 3
137 ± 2
PHOTOCATHODE
DY6
7
6
IC
8
11 DY8
DY2 3
IC
IC
9
10 DY7
DY3 4
123 MAX.
7
DY11 6
DY9 5
DY7 4
DY5
DY4 5
2
1
DY1
12 P
13
G
14
K
* CONNECT SH TO DY5
21 PIN BASE
13 MAX.
56.5 ± 0.5
TPMHA0285ED
#9 R877, R1512
TPMHA0389EB
$0 R1250
133 ± 2
133.0 ± 1.5
120 MIN.
FACEPLATE
111 MIN.
55 MAX.
11 P
DY3 3
12 IC
13
G
14
K
2
1
DY1
DY14
DY12
IC P
DY13
DY10
9 10 11 12
13 DY8
8
DY11
14
7
DY9 6
15 DY6
16 DY4
DY7 5
17
4
DY2
DY5
18
3
DY3
IC
19
2
20
1
G2 & DY1
G1
IC
K
PHOTOCATHODE
259 ± 5
171 ± 3
PHOTOCATHODE
DY4 4
DY2
194 MAX.
FACEPLATE
DY8
DY9
8
9
10 DY10
276 ± 5
DY7
DY6
7
6
DY5 5
HA COATING
14 PIN BASE
JEDEC
No. B14-38
20 PIN BASE
JEDEC
No. B20-102
56.5 ± 0.5
52.5 MAX.
TPMHA0074EC
$1 R1584
TPMHA0018EB
$2 R6594
133 ± 2
128 ± 2
120 MIN.
110 MIN.
R82
.5 ±
DY3 4
178 ± 2
PHOTOCATHODE
259 ± 5
276 ± 5
HA COATING
84.5 ± 2
265 MAX.
PHOTOCATHODE
A TEMPORARY BASE
REMOVED
DY10
P
DY9 9 10
DY8
14 DY6
DY7 8
15
7
DY5 6
16 DY4
2.0
DY14
IC P
DY12
DY13
DY10
9 10 11 12
13 DY8
DY11 8
14
7
DY9 6
15 DY6
16 DY4
DY7 5
17 DY2
DY5 4
18
3
DY3
19 IC
2
20
1
G2 & DY1
G1
IC
K
FACEPLATE
2
FOCUS3 1
DY1
23
K
19
20 FOCUS1
21 DY2
FOCUS2
B BOTTOM VIEW
IC IC
DY10
DY8
9 10 11 12
13
14 DY6
7
IC 6
15 IC
16 DY4
DY7 5
17
DY5 4
18 FOCUS1
3
19 DY2
DY3
2
1
20
FOCUS3
FOCUS2
K
DY1
IC
P
DY9
70 MIN.
13 MAX.
A
20 PIN BASE
JEDEC No. B20-102
20 PIN BASE
JEDEC No. B20-102
8
B
52.5 MAX.
52.5 MAX.
TPMHA0187EC
TPMHA0373ED
29
$3 R5912, R5912-02
$4 R7081, R7081-20
202 ± 5
INPUT WINDOW
190 MIN.
R5912
IC
DY9 8
7
IC 6
DY7 5
DY5 4
3
DY3
2
FOCUS3 1
DY1
16 DY4
17 DY2
18
19 FOCUS1
20
K
PHOTOCATHODE
FOCUS2
245 ± 5
(Bottom View)
275 MAX.
IC IC
DY10
P 9 10 11 12 DY8
13
DY9 8
14 DY6
7
IC 6
15 IC
16 DY4
DY7 5
17 DY2
DY5 4
18
3
DY3
19 FOCUS1
2
20
FOCUS3 1
FOCUS2
K
DY1
IC
7
36.
R1
1
R13
220 ± 5
R7081
IC IC DY10
DY8
13
14 DY6
15 IC
9 10 11 12
P
PHOTOCATHODE
253 ± 5
220 MIN.
R5912-02
IC DY14
DY12
DY13 9 10 11 12 DY10
13
DY11 8
14 DY8
7
DY9 6
15 DY6
P
84.5 ± 2.0
DY7 5
DY5 4
3
FOCUS3
2
DY3 1
DY1
16 FOCUS1
17 DY4
18
19 DY2
20
K
(Bottom View)
300 MAX.
INPUT WINDOW
84.5 ± 2.0
FOCUS2
IC: Internal Connection
(Do not use)
52.5 MAX.
IC DY14
DY12
DY13 9 10 11 12 DY10
13
8
DY11
14 DY8
7
DY9 6
15 DY6
DY7 5
DY5 4
3
FOCUS3
2
DY3 1
DY1
(Bottom View)
20-PIN BASE
JEDEC No. B20-102
R7081-20
P
20
16 FOCUS1
17 DY4
18
19 DY2
K
FOCUS2
(Bottom View)
IC: Internal Connection
(Do not use)
20-PIN BASE
JEDEC No. B20-102
52.5 MAX.
TPMHA0500EA
$5 R8055
TPMHA0501EA
$6 R3600-02
508 ± 10
460 MIN.
332 ± 5
DY10 IC DY8
P
DY11
9 10 11 12 DY6
13 DY4
8
DY9
14
7
DY7 6
15 IC
16 DY2
IC 5
17 FOCUS2
DY5 4
18
3
DY3
K
19
2
1
20
DY1
FOCUS3
IC
FOCUS1
IC: Internal Connection
(Do not use)
312 MIN.
INPUT
WINDOW
P
9 10 11 12
3.4
R22
IC 5
DY5 4
3
DY3
2
FOCUS3 1
DY1
PHOTOCATHODE
20
DY8
13
14 DY6
15 DY4
16 DY2
17 FOCUS2
18
19 FOCUS1
K
15
R3
IC
DY9 8
7
DY7 6
IC DY10
IC
PHOTOCATHODE
IC
610 ± 20
IC: Internal Connection
(Do not use)
680 MAX.
333 ± 5
368 MAX.
(Bottom View)
254 ± 10
202 ± 3
82 ± 2
20-PIN BASE
JEDEC No. B20-102
52.5 MAX.
213 ± 3
METAL STEM FLANGE
20PIN BASE
JEDEC No.B20-102
TPMHA0502EA
$7 R7250
508 ± 10
430 MIN.
IC
IC P
DY10
DY9 9 10 11 12 IC
13 DY8
DY7 8
14
7
DY5 6
15 DY6
16 DY4
DY3 5
17 DY2
IC 4
18
3
FOCUS3 2
19 IC
1 20 FOCUS2
DY1
K
FOCUS1
PHOTOCATHODE
15
R3
610 ± 20
680 MAX.
IC: Internal Connection
(Do not use)
254 ± 10
82 ± 2
20PIN BASE
JEDEC No.B20-102
TPMHA0475ED
30
TPMHA0092EE
(Unit: mm)
$8 R7400U
$9 R7400U-06
INSULATION COVER (Polyoxymethylene)
5.4 ± 0.3
5±1
5.08
PHOTOCATHODE
8 MIN.
Side View
12- 0.45
5.08
PHOTOCATHODE
8MIN.
10.16
10.16
Side View
Bottom View
Bottom View
SHORT PIN DY3 DY5
(IC)
2
1
3
DY7
K
12
4
SHORT PIN DY3 DY5
(IC)
2
1
3
DY7
K
12
4
DY1 11
DY1 11
DY2
5 P
10
6
9
DY4
7
8
DY8
DY6
SHORT PIN
GUIDE MARK
5.08
15.9 ± 0.4
12- 0.45
5.08
WINDOW
9.4 ± 0.4
4.0 ± 0.3
0.3 ± 0.2
SHORT PIN
GUIDE MARK
5.4 ± 0.3
5±1
10.16
12.8 ± 0.5
WINDOW
11.0 ± 0.4
0.5 ± 0.2
SHORT PIN
(IC)
DY2
IC: Internal Connection
(Do not use)
5 P
10
9
DY4
6
7
8
DY8
DY6
SHORT PIN
(IC)
IC: Internal Connection
(Do not use)
TPMHA0411EC
TPMHA0410EC
IC
IC
P
IC
IC
IC
IC
4 MAX.
29- 0.45
INSULATION
COVER
SIDE VIEW
IC
IC
IC
IC
IC
IC
IC
BOTTOM VIEW
2.54 PITCH
IC
P1
IC
IC
IC
P4
IC
INSULATION COVER
SIDE VIEW
1 2 3 4 5 6 7 8 9
32
10
11
31
30
12
GUIDE
29
13
CORNER
28
14
15
27
16
26
25 24 23 22 21 20 19 18 17
IC
P2
IC
IC
IC
P3
IC
29- 0.45
PHOTOCATHODE
TOP VIEW
IC
K
4.4 ± 0.7
4 MAX.
0.20
CUT (K)
Dy10
Dy9
Dy8
Dy7
Dy6
Dy5
IC (Dy10)
CUT (K)
TOP VIEW
1 2 3 4 5 6 7 8 9
32
10
11
31
30
12
GUIDE
29
13
CORNER
28
14
15
27
16
26
25 24 23 22 21 20 19 18 17
22.0 ± 0.5
0.6 ± 0.4
BOTTOM VIEW
CUT (K)
Dy10
Dy9
Dy8
Dy7
Dy6
Dy5
IC (Dy10)
CUT (K)
18 MIN.
2.54 PITCH
PHOTOCATHODE
EFFECTIVE AREA
30.0 ± 0.5
25.7 ± 0.5
0.20
0.6 ± 0.4
4.4 ± 0.7
12.0 ± 0.5
18 MIN.
22.0 ± 0.5
12.0 ± 0.5
30.0 ± 0.5
25.7 ± 0.5
IC (Dy10)
%1 R7600U-00-M4
K
IC (Dy10)
IC
Dy1
Dy2
Dy3
Dy4
IC (Dy10)
CUT (K)
%0 R7600U
Dy1
Dy2
Dy3
Dy4
IC (Dy10)
CUT (K)
15.9 ± 0.4
INSULATION COVER (Polyoxymethylene)
4.0 ± 0.3
10.16
11.5 ± 0.4
: Photocathode
K
Dy : Dynode
: Anode
P
CUT : Short Pin
IC : Internal Connection
(Don't Use)
K
: Photocathode
Dy : Dynode
P
: Anode
CUT : Short Pin
IC : Internal Connection
(Don't Use)
Basing Diagram
Basing Diagram
TPMHA0278EI
TPMHA0297EI
%2 R5900U-00-L16
30.0 ± 0.5
24 MAX.
4.4 ± 0.7
2.54 PITCH
1 MAX.
K
Dy6P13 P11 P9 P7 P5 Dy7
20.32
Dy2
12
EFFECTIVE
AREA
25.7 ± 0.5
15.8
Dy4
NC
P15
P16
4 MAX.
30- 0.45
P14
Dy10
Dy9
1 2 3 4 5 6 7 8 9
10
32
31
11
30
12
29
13
GUIDE
28
14
CORNER
27
15
26
16
25 24 23 22 21 20 19 18 17
16
Side View
P1
P2
NC
Dy3
Dy1
PHOTOCATHODE
INSULATION
COVER
P3
Dy8 P12 P10 P8 P6 P4 Dy5
K
Bottom View
Basing Diagram
1.0 PITCH
0.8
15.8
Top View
K : Photocathode
Dy : Dynode (Dy1-Dy10)
P : Anode (P1-P16)
NC : No Connection
TPMHA0298EE
31
9.8 ± 0.4
13.5 ± 0.5
FACEPLATE
8 MIN.
DY7
5
8
4
DY1
1
IC
DY8
7
8
5
9
DY7 4
10
DY2
11
K
2
DY6
10 DY4
DY5 3
11 DY2
2
DY3
12
1
13
DY1
IC
K
SHORT PIN
10 MAX.
11 PIN BASE
DY6
6
DY9
PHOTOCATHODE
9 DY4
DY3 3
DY10
P
DY8
7
71 ± 2
DY5
45.0 ± 1.5
PHOTOCATHODE
P
6
10 MIN.
SHORT PIN
13 PIN BASE
13 MAX.
FACEPLATE
13.5 ± 0.5
10 MIN.
9.8 ± 0.4
%4 R2102
8 MIN.
%3 R2248
TPMHA0098EC
70 MIN.
76.0 ± 1.5
59.5 ± 1.0
%6 R6237
54 MIN.
%5 R6236
TPMHA0096EA
59.5 ± 1.0
76.0 ± 1.5
54 MIN.
FACEPLATE
DY5
DY6
7
6
IC
8
9
51.5 ± 1.5
14 PIN BASE
JEDEC
No. B14-38
123 MAX.
100 ± 3
DY4 5
DY5
DY4 5
11 DY8
DY2 3
2
1
DY1
DY6
7
6
10 DY7
DY3 4
IC
70 MIN.
PHOTOCATHODE
IC
12 P
13
G
14
K
100 ± 3
PHOTOCATHODE
51.5 ± 1.5
14 PIN BASE
JEDEC
No. B14-38
56.5 ± 0.5
IC
8
IC
9
10 DY7
DY3 4
123 MAX.
FACEPLATE
11 DY8
DY2 3
2
1
DY1
IC
12 P
13
G
14
K
56.5 ± 0.5
TPMHA0392EB
%7 R1548-07
TPMHA0393EB
%8 R1538
67.5 ± 0.6
60 MIN.
24.0 ± 0.5
18 MIN.
8 MIN. 8 MIN.
24.0 ± 0.5
FACEPLATE
59.5 ± 0.5
P2 DY10 DY8
P1
8 9 10 DY7-2
11 DY6
7
DY9
12
6
DY7-1 5
13 DY4
DY3 3
DY1
2
1
IC
DY7
DY6
PHOTOCATHODE
14 DY2
15
16 IC
17 IC
K
51.5 ± 1.5
SHORT PIN
14 PIN BASE
JEDEC
No. B14-38
13 MAX.
17 PIN BASE
DY5
125 ± 3
DY5 4
55 MIN.
6
7
5
DY8
IC
8
9
IC
10
DY4 4
11 P
3
12 IC
13
14
G
K
DY3
DY2
2
1
DY1
19
70 ± 2
PHOTOCATHODE
FACEPLATE
56.5 ± 0.5
TPMHA0511EA
32
TPMHA0512EA
(Unit: mm)
79 MIN.
60 MIN.
85 ± 1
^0 R6235
67.5 ± 0.6
%9 R6234
59.5 ± 0.5
76.0 ± 1.5
55 MIN.
FACEPLATE
100 ± 3
123 MAX.
51.5 ± 1.5
DY6
DY5
7
6
DY4 5
6
PHOTOCATHODE
IC
9
10 DY7
DY3 4
51.5 ± 1.5
12 P
1
DY1
IC
9
10 DY7
DY3 4
13
G
14
K
2
IC
IC
8
DY4 5
11 DY8
DY2 3
14 PIN BASE
JEDEC
No. B14-38
DY6
7
DY5
IC
8
100 ± 3
PHOTOCATHODE
70 MIN.
123 MAX.
FACEPLATE
11 DY8
12 P
13
G
14
K
DY2 3
2
1
DY1
IC
14 PIN BASE
JEDEC
No. B14-38
56.5 ± 0.5
56.5 ± 0.5
TPMHA0390EB
SEMI-FLEXIBLE
LEADS
DY7 4
10 DY8
DY5 3
11 DY6
2
DY3
A
12
1
45 MIN.
13
DY2
14
K
DY1
R13 ± 1
DY4
SEMI-FLEXIBLE
LEADS
5
DY7 4
DY5 4
1
12
DY1
13 DY4
DY1 2
14
DY2
17
K
B BOTTOM VIEW
P
DY10
6
7
DY8
5
8
DY9
B
10 DY4
11
2
DY3
12 DY6
DY3 3
9 DY6
37.3
DY5 3
A TEMPORARY BASE
REMOVED
P
DY9
DY10
8
10
6
DY7
DY8
5
11
A
DY10
7
DY8
8
6
DY9
B
FACEPLATE
PHOTOCATHODE
B BOTTOM VIEW
P
25.4 ± 0.5
50 MIN.
PHOTOCATHODE
A TEMPORARY BASE
REMOVED
P
6
DY9
DY10
9
5
13 MAX.
FACEPLATE
30.0 ± 1.5
18.6 ± 0.7
13 MAX.
R9 ± 1
^2 R7373A-01
43.0 ± 1.5
^1 R7375-01
TPMHA0391EB
DY7 4
9 DY6
DY5 3
10 DY4
37.3
11
2
DY3
DY2
1
12
DY1
K
DY2
K
TPMHA0459EA
^3 R7354
TPMHA0460EA
^4 R8143
28.5 ± 0.5
28.5 ± 0.5
20 MIN.
PHOTOCATHODE
DY6
6
7
8
9
10
5
60 ± 1
3
2
1
DY2
NC
DY10
P
DY11
DY5
PHOTOCATHODE
11 IC
IC 4
DY4
25 MIN.
DY7
DY9
6
7
12 DY3
13
14
DY1
K
DY5
10 DY6
11 DY4
3
2
1
IC
29.0 ± 0.7
DY8
9
5
DY3
SHORT PIN
8
DY7 4
112 ± 2
P
DY8
FACE PLATE
DY9
20 MIN.
25 MIN.
12 DY2
13
14
K
DY1
SHORT PIN
13 MAX.
HA COATING
14 PIN BASE
13 MAX.
14 PIN BASE
TPMHA0416EA
TPMHA0507EA
33
Typical Gain Characteristics
● 10 mm (3/8") Dia. and Metal package Types
108
● 13 mm (1/2") Dia. Types
TPMHB0095ED
10
8 TPMHB0096EC
H8711
7
10
GAIN
R7600U
H7260
R7600U-00-M4
106
R1635
R2248
R2496
5
10
GAIN
6
10
107
R5900U-00-L16
R647-01
R2102
5
10
R7400U
R4177-06
104
4
10
R4124
H7546B
103
3
10
102
500
2
10
500
300
700
1000
1500
2000
700
108
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
SUPPLY VOLTAGE (V)
● 19 mm (3/4") Dia. Types
1000
● 19 mm (3/4") Dia. Types
8 TPMHB0098ED
TPMHB0097ED
10
7
7
10
10
R7375-01
R1166
6
6
10
10
R1450
GAIN
GAIN
R5611-01
5
10
5
R3478
10
R4125
R5325
4
4
10
10
R3991-04
3
3
10
10
2
2
10
10
500
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
34
500
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
● 25 mm (1") Dia. Types
108
● 28 mm (1-1/8") Dia. Types
8 TPMHB0100EE
TPMHB0099ED
10
R7111
R1924A
R7899-01
R4998
R1548-07
7
10
7
10
R8143
R7373A-01
R7354
6
6
10
10
R5505-70
5
10
GAIN
GAIN
R1924A
R7525
5
10
R6427
R5380
4
104
10
R1288A-06
103
102
500
3
10
700
1000
1500
102
500
2000 2500 3000
700
SUPPLY VOLTAGE (V)
● 38 mm (1-1/2") Dia. Types
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
● 38 mm (1-1/2") Dia. Types
8 TPMHB0101EB
10
7
10
8 TPMHB0102EE
10
R7761-70
7
10
R3886
6
106
R580-17
R580
GAIN
GAIN
10
5
10
4
R980
4
10
10
R5330
3
3
10
10
2
2
10
500
5
10
10
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
500
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
35
● 51 mm (2") Dia. Types
● 51 mm (2") Dia. Types
8 TPMHB0103EE
8 TPMHB0104ED
10
10
R5924-70
R331-05
7
7
10
10
R2154-02
R329-02
R5496
106
106
R1306
5
10
R4607-06
GAIN
GAIN
R6231
R2083
5
10
R7723
4
10
10
4
103
10
R1840
R1828-01
3
102
500
2
10
700
1000
1500
500
2000 2500 3000 3500
700
108
1500
2000 2500 3000 3500
SUPPLY VOLTAGE (V)
SUPPLY VOLTAGE (V)
● 60 mm and 64 mm (2.5") Dia. Types
1000
● 76 mm (3") Dia. Types
TPMHB0105ED
108
TPMHB0106EE
R6504-70
7
107
10
R6233
R6235
R6237
R1538
R6232
R6234
R6236
106
GAIN
GAIN
106
5
10
5
10
4
104
10
3
10
R4143
3
10
2
2
10
10
500
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
36
500
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
● 76 mm (3") Dia. Types
● 127 mm (5") Dia. Types
8 TPMHB0107ED
9 TPMHB0108EC
10
10
R1250
R1584
R6091
7
10
8
10
R1307
6
R6594
7
10
10
R1512
GAIN
GAIN
R877
5
10
R2238
6
10
10
4
105
103
104
102
500
3
700
1000
1500
10
500
2000 2500 3000
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
SUPPLY VOLTAGE (V)
● 204 mm (8"), 254 mm (10") and 508 mm (20") Dia. Types
109
TPMHB0109EB
1010
108
TPMHB0657EB
109
R5912-02
R7081-20
108
107
GAIN
GAIN
R5912
R7081
106
R3600-02
R7250
107
10
106
104
105
5
3
10
500
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
104
500
R8055
700
1000
1500
2000 2500 3000
SUPPLY VOLTAGE (V)
37
Position Sensitive Photomultiplier Tubes
Tube
Diameter
q
Spectral
Response
Range (nm)
/
Curve Code
Type
No.
w
Outline
No.
e
Anode Sensitivity
Effective
Area
Number of Plates
or wires
(mm)
Anode
Pitch
Socket
&
Socket
Assembly
(mm)
r
Cathode Sensitivity
t
y
u
Dynode
Blue
Structure
Q.E.
/ No. of Luminous Sens. at Peak
Typ.
Index
Stages
Typ.
(CS 5-58)
(µA/lm)
Typ.
(%)
Position Sensitive Photomultiplier Tubes with Metal Channel Dynodes
30 mm R8520U
Square -00-C12
22 × 22
q
300 to 650/A-D
6(X) + 6(Y) Plates
4.0
E678-32B ¤7
MC / 11
80
9.0
24
Position Sensitive Photomultiplier Tubes
3"
round
5"
round
R2486-02
300 to 650/A-D
w
50
16(X) + 16(Y) Wires
3.75
—
CM / 12
80
9.0
23
R3292-02
300 to 650/A-D
e
100
28(X) + 28(Y) Wires
4.0
—
CM / 12
80
9.0
23
Note: Please refer to page 16 for meaning of numbers in w, e and i.
q R8520U-00-C12
30 ± 0.5
4.4 ± 0.7
12.0 ± 0.5
29.0 ± 0.5
25.7 ± 0.5
0.6 ± 0.4
22 MIN.
4 MAX.
PHOTOCATHODE
G
Side View
Dy4
Dy6
Dy8
Dy10
Bottom View
Dy1 Dy3 Dy5 Dy7 Dy9 Dy11
K
Dy2
25- 0.45
INSULATION COVER
EFFECTIVE AREA
Top View
2.54 PITCH
PX1
1 2 3 4 5 6 7 8 9
10
32
31
11
12
30
29
13
GUIDE
28
14
CORNER
27
15
26
16
25 24 23 22 21 20 19 18 17
PX2
PX3
PY1
K : Photocathode
Dy : Dynode (Dy1-Dy11)
P : Anode (PX1-PX6)
(PY1-PY6)
G : Grid
PX4
PX5
PX6
PY6 PY5 PY4
PY3 PY2
Bottom View
Basing Diagram
TPMHA0484EC
38
Maximum Rating !2 Typical Time Response !3
Anode Sensitivity
o
!0
i
Anode to
Cathode
Supply
Voltage
Gain
Typ.
Luminous
Typ.
!1
Dark
Current
(A/lm)
Typ.
(nA)
Max.
(nA)
Anode
Average Rise Transit T.T.S.
to
Anode Time Time Typ.
Cathode
Current Typ. Typ. (FWHM)
Voltage
(V)
(mA)
(ns)
(ns)
(ns)
800 #4
1.0 × 106
70
2
10
1000
0.1
2.4
11.5
0.70
1250 #7
5.0 × 105
40
20
50
1300
0.06
5.5
17
—
1250 #7
1.3 × 105
10
40
150
1300
0.06
6.0
20
—
Type
No.
Note
R8520-00-C12, without cover type, is
available.
No suffix number: PMT alone
-01: PMT + Voltage Divider
-02: -01 + Resistor Chain
No suffix number: PMT + HA
-01: PMT + HA +Voltage Divider
-02: -01 + Resistor Chain
R8520U
-00-C12
R2486-02
R3292-02
w R2486-02
Y1
Y2
Y3
Y4
Y5
Y6
Y7
Y8
Y9
Y10
Y11
Y12
Y13
Y14
Y15
Y16
76 ± 1
50 MIN.
55 ± 2
11.2 20 ± 1
86.2 ± 3.0
PHOTOCATHODE
C3
X1
X2
X3
X4
X5
X6
X7
X8
X9
X10
X11
X12
X13
X14
X15
X16
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
-H.V
: RG-174/U
SIGNAL OUTPUT
: 0.8D COAXIAL CABLES
2R
1R
2R
2R
2R C2
2R
2R
2R
2R
2R
2R
DY1
Focus
K
EACH
RESISTOR: 1 kΩ
XA XB
1R : 180 kΩ 1/2 W
2R : 360 kΩ 1/2 W
C1 : 0.002 µF/2 kV
C2 : 0.01 µF/500 V
C3 : 0.01 µF/500 V
2R
2R
C1
10 kΩ
1R
RG174/U
HV
IN
YD
YC
TPMHA0160ED
TPMHC0086EE
e R3292-02
Y1
Y2
Y3
Y4
Y5
Y24
Y25
Y26
Y27
Y28
132 ± 3
100 MIN.
X1
X2
X3
X4
X5
X24
X25
X26
X27
X28
133 ± 3
113 ± 2
PHOTOCATHODE
HA COATING
EACH
RESISTOR: 1 kΩ
-H.V
: RG-174/U
R
2R
2R
2R
2R
C2
2R
2R
1R : 180 kΩ
2R : 360 kΩ
C1 : 0.002 µF/2 kV
C2 : 0.01 µF/500 V
C3 : 0.01 µF/500 V
2R
2R
2R
2R
2R
1R
C1
HV
IN
RG174/U
XA
TPMHA0162EE
2R
10 kΩ
20 ± 1
SIGNAL OUTPUT
: 0.8D COAXIAL CABLES
C3
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
K
XB
YC
YD
TPMHC0088EE
39
Voltage Distribution Ratios
Interstages for the dynodes of a PMT are supplied by a voltage
divider network consisting of series resistors, as shown on the
right page. The cathode ground scheme (1) is usually used in
scintillation counting because it reduces noise resulting from
glass scintillation. In fast-pulse light applications, use of the
anode ground scheme (2) is suggested. Either scheme requires decoupling (charge-storage) capacitors connected to the
last few stages of dynodes in order to maintain the dynode vol-
tage at a constant value during pulse duration. refer to section
11 and 12 on page 8 and 9 for further details.
To free the user from the necessity of designing voltage divider
and performing troublesome parts selection, Hamamatsu provides a variety of socket assemblies which enable sufficient
performance to be derived from PMT's by making simple connections only.
Voltage Distribution Ratio
Voltage Number
Distribution
of
No.
stages
q
w
6
e
Voltage Distribution Ratios
K
2
2
3
K
No.
r
t
y
u
i
o
!0
!1
!2
stages
No.
!3
stages
8
K
No.
!4
stages
9
K
No.
!5
!6
!7
!8
!9
@0
@1
@2
@3
@4
@5
@6
@7
@8
@9
#0
#1
stages
K
No.
#2
#3
stages
G1
1
1
2
2
3
4
4
4
7
8
Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 P
1
1
1
0.5
1
1
1
1
—
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
—
1
1
1
1
1
1
1
1
2
1
1
1
1
1
1
— 1.5 1.5
1.5
1
1
1
1
1
1
1
—
1.5
1
3.3
1.2 1.5
2
3
1
—
2
1
2
1
1
1
1
1
—
1.5
1
1
1
1
1
1
1
—
G1 Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Acc Dy7 Dy8 P
1.3 4.8 1.2 1.8
1
1
1
1
0.5
3
2.5
G1
4
10
10
Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 P
1.5
1
2
3
1
1
1
2
4
2
1
1
1
2
3
2
1
1
Acc: Grid (Accelerating Electrode)
Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 P
—
1
1
1
1
1.5
1
1
1
1
G1 Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 P
1
1
1
1
1
1
1
1
1
1
—
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1.5
3
2.5
1.3 4.8 1.2 1.8
1
1
1
1
1
1
1
1
1
1
1.5 —
1
1
1
1
1
1.2 1.8 3.6 3.3
1
1.5 —
1
1
1
1
1
1
1
1
1.5 — 1.5 1.5
1
1
1
1
1
1
1
1
1
1
—
2
1
1
1
1
1
1.2 1.5 1.8
2
1
—
2
1
1
1
1
1.2 1.5 2.2 3.6
3
1
—
2
1.5
1
1
1
1
1
1
1 0.75
1
—
2
1
1
1
1
1
1
1
1
2.6 — 1.2 1.2
1
1
1
1
1.5 2.3
3
3.5
2.6 — 1.2 1.2
1
1
1
1
1
1
1
1
1
1
—
3
1.5
1
1
1
1
1
1
1
1
1
—
3
1.5
1
1
1
1
2
3
3.6 3.3
1
—
3
1.5
1
1
1
1
1
1
1
1
1
—
4
1.5
1
1
1
1.2 1.5
2
3.3
3
1
—
4
K
8
8
(Note 1)
Dy1 F1
F3
F2 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 P
1
1
1
1
1
0.18 0 0.17 0.85 1.5
1
1
1
1
1
1
1.2 1.5 1.8
0.18 0 0.17 0.85 1.5
3
2.4
Note 1: Acc should be connected to Dy7 except R4998.
40
<Symbols>
K: Photocathode G: Grid F: Focusing Electrode
Dy: Dynode GR: Guard Ring P: Anode
Acc: Accelerating Electrode
Schematic Diagram of Voltage Divider Networks
(1) Cathode Ground Scheme (+HV)
(2) Anode Ground Scheme (-HV)
CATHODE
CATHODE
ANODE
DY.1 DY.…
ANODE
Cd
DY.1 DY.2…
DY.n
DY.n
Rd
R
R
R : 100kΩ
C : 0.01µF
R
1MΩ
0.1µF
R
R
Rd :
Cd :
R
1MΩ
0.005µF
R
R
R
R
C
C
C
C
R
-HV
+HV
R
R
R
R
R
R : 100k 1MΩ
C : 0.01µF 0.1µF
R
R
R
R
C
C
C
C
TPMOC0043EB
RL
TPMOC0044EB
Voltage Distribution Ratio
Voltage Number
Distribution
of
No.
stages
#4
11
#5
11
Voltage Distribution Ratios
K
G1 Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 P
1
1
1
1
1
1
1
1
0.5 1.5
2
1
0.5
1
1
1
1
1
1
1
1
1
1
—
1
1
No.
#6
stages
11
K
No.
#7
#8
#9
$0
$1
$2
$3
$4
$5
$6
$7
$8
stages
K
No.
$9
stages
12
K
No.
%0
%1
stages
K
G1 Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 Dy12 Dy13 Dy14 P
2.5 7.5 1.2 1.8
3
2.5
1
1
1
1
1
1
1
1.5 1.5
1
2.5 7.5 1.2 1.8
5.7
8
5
1
1
1
1
1.2 1.5
2
2.8
4
No.
%2
%3
%4
stages
K
Dy1 F2 F1 F3 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 Dy12 Dy13 Dy14 P
—
1
—
11.3 0
0.6
3.4
—
—
1
5 3.33 1.67 1
1
0
1
1
3
—
3.4
5
3.3 1.7
2
—
18.5 0
0.6
0
—
—
4
1
1
1
1
3.4
5 3.33 1.67 1
1
1.2 1.5 2.2
0
1
11.3 0
0.6
3
2.4
1
No.
%5
%6
stages
15
19
F2
5
12
10
14
2
F3 Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 P
1
1
0.02 3
1
1
1
1
1
1
1
1
G1 Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 Dy12 P
1
1
1
1
—
1
1
1
1
1
1
1
1
1
1.2 1.8
2.5
1
3
1
1
1
1
1
1
1.5 1.5
3
1.2 1.8
4
1
3
1
1
1
1
1.5 2.5 3.6 4.5 8.6
2.5
1
1
1.2 2.8 1.2 1.8
1
1
1
1
1.5 1.5
3
5
1
1
1.2 2.8 1.2 1.8
1.2 1.5
2
2.8
4
5.7
8
1
1
1
1
—
1
2
1
1
1
1
1
1
1
1
1
2
1
—
1
2
1
1
1
1
1.2 1.5 1.8
2
2
1
1
—
1
2
1
1
1
1
1
1
1
2
2
5
1
—
1
3
1
1
1
1
1
1
2
1.4
1
1
1
0
1
4
1
1
1
1
1
1
1
1.6
1
2
1
0
1
4.3
1
1
1
1
1.6
2
3.3
1.6
1
3
1
0
1
4.3
1
1.2 1.5
2
2.4
3
3.9
1
14
F1
1
K
2
2
(Note 2)
(Note 2)
(Note 2)
P
Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 Dy12 GR
1
1
1
1
1
1
1
1
1
1
1
0.9 0.1
Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 Dy12 Dy13 Dy14 Dy15 Dy16 Dy17 Dy18 Dy19 P
1
1
1
1
—
—
—
—
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Note 2: Shield should be connected to Dy5.
41
Quick Reference for PMT Hybrid Assemblies
PMT Characteristics
Tube Type No. RefeAssembly
/
rence Outline
Tube
Type
Voltage
Page for No.
Diameter
No.
Distribution
PMT
Ratio
Feature
H3164-10
H3695-10
H3165-10
10 mm
(3/8")
H.V
Input
Terminal
Coaxial
Cable *
Coaxial
Cable *
R1635
y
18
q
R2496
i
18
w
!5
18
e
RG-174/U
Coaxial
Cable *
Coaxial
Cable *
Coaxial
Cable *
Coaxial
Cable *
Coaxial
Cable *
Coaxial
Cable *
Coaxial
Cable *
Coaxial
Cable *
Coaxial
Cable *
13 mm
R647-01
(1/2")
H6520
R1166
!8
18
r
H6524
R1450
@4
18
t
H6613
19 mm
R2076
(3/4")
!2
19
y
H6612
R3478
!2
18
u
H8135
R5611-01
@7
18
i
H6533
R4998
!7
18
o
25 mm
R5505-70
(1")
%5
18
!0
R7899-01
@9
18
!1
#0
18
!2
@1
18
!3
SHV
@5
18
!4
SHV
%6
18
!5
Coaxial
Cable *
H6152-70
H8643
H7415
H3178-51
H3178-61
H8409-70
28 mm
R6427
(1-1/8")
R580
38 mm
R580-17
(1-1/2")
R7761-70
Assembly Characteristics
Maximum Rating
1
Signal
Maximum
Case
Output
Overall Divider Average Anode
Material
Terminal
Current
Voltage Current
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
Magnetic Shield
Wrapping
Magnetic Shield
Wrapping
Magnetic Shield
Wrapping
Magnetic Shield
Case
Magnetic Shield
Case
Magnetic Shield
Case
Magnetic Shield
Case
Magnetic Shield
Case
Magnetic Shield
Case
P.O.M Case
Magnetic Shield
Case
Magnetic Shield
RG-174/U
Case
Magnetic Shield
BNC
Case
Magnetic Shield
BNC
Case
RG-174/U
RG-174/U
P.O.M Case
(V)
(mA)
-1500
0.41
17 at 1250 V H3164-11 (with 50 Ω**)
-1500
0.37
15 at 1250 V H3695-11 (with 50 Ω**)
-1250
0.34
14 at 1000 V H3165-11 (with 50 Ω**)
-1250
0.33
13 at 1000 V H6520-01 (with 50 Ω**)
-1800
0.43
18 at 1500 V H6524-01 (with 50 Ω**)
-1800
0.35
17 at 1700 V H6613-01 (with 50 Ω**)
-1800
0.35
17 at 1700 V H6612-01 (with 50 Ω**)
-1250
0.29
12 at 1000 V
-2500
0.36
16 at 2250 V H6610 (R5320)
+2300
0.41
10 at 2000 V +HV
-1800
0.42
18 at 1500 V
-2000
0.41
16 at 1500 V
-1750
0.63
27 at 1500 V
-1750
0.61
26 at 1500 V
+2300
0.33
10 at 2000 V +HV
Note :
1 The maximum average anode current is defined as 5 % of divider current when standard high voltage is applied.
* marks: It's possible to attach an SHV connector fitting RG-174/U to the coaxial cable.
** marks: 50 Ω is a terminal resistor at anode output.
42
Notes
(µA)
H7415-01 (with 50 Ω**)
H7416 (R7056)
PMT Characteristics
Assembly Characteristics
Tube Type No. RefeAssembly
/
rence Outline
Tube
Type
Voltage
Page for No.
Diameter
No.
Distribution
PMT
Ratio
Feature
H.V
Input
Terminal
H6410
R329-02
$8
20
!6
SHV
H7195
R329-02
$7
20
!7
SHV
R1828-01
$0
20
!8
SHV
R1828-01
$0
20
!9
SHV
H2431-50
R2083
!3
20
@0
SHV
H6614-70
R5924-70
%6
20
@1
H8318-70
64 mm
R6504-70
(2.5")
%6
20
@2
Coaxial
Cable *
Coaxial
Cable *
R2238
$2
20
@3
H6525
76 mm
R4143
(3")
#8
20
H6559
R6091
$8
R1250
R1584
H1949-50
H1949-51
51 mm
(2")
Signal
Output
Terminal
1
Maximum
Overall Divider Average Anode
Current
Voltage Current
Maximum Rating
Case
Material
Magnetic Shield
BNC
Case
Magnetic Shield
BNC × 3***
Case
Magnetic Shield
BNC × 3***
Case
Magnetic Shield
BNC
Case
Magnetic Shield
BNC
Case
Notes
(V)
(mA)
(µA)
-2700
0.67
25 at 2000 V
-2700
1.23
46 at 2000 V
-3000
1.39
58 at 2500 V
-3000
0.70
-3500
0.61
26 at 3000 V H3378-50 (R3377)
H6521 (R2256-02)
H6522 (R5113-02)
H3177-50 (R2059)
H4022-50 (R4004)
H3177-51 (R2059)
29 at 2500 V
H4022-51 (R4004)
RG-174/U
P.O.M Case
+2300
0.33
15 at 2000 V +HV
RG-174/U
P.O.M Case
+2300
0.33
15 at 2000 V +HV
RG-174/U
RG-174/U
—
-1500
0.45
19 at 1250 V
@4
SHV
BNC
-3000
0.70
29 at 2500 V H6526 (R4885)
20
@5
SHV
BNC
-2500
0.62
25 at 2000 V
%0
20
@6
SHV
BNC
-3000
1.02
34 at 2000 V
%0
20
@6
SHV
BNC
-3000
1.02
34 at 2000 V
#6
20
@7
RG-174/U
or equiv.
RG-58C/U
—
+2500
0.44
18 at 2000 V
16 ch (4 × 4) $4
22
@8
-1000
0.35
22
@9
P.O.M Case
-1000
H7260
22
#0
P.O.M Case
-900
H8500
64 ch (8 × 8) $9
22
#1
Terminal
PIN
Terminal
PIN
Terminal
PIN
Terminal
PIN
P.O.M Case
Metal 64 ch (8 × 8) $5
Package
PMT 32 ch (1 × 32) !5
Terminal
PIN
Terminal
PIN
Terminal
PIN
Terminal
PIN
—
-1100
R2238-01
H6527
H6528
R3600-06
H8711
H7546B
127 mm
(5")
508 mm
R3600-02
(20")
Magnetic Shield
Case
Magnetic Shield
Case
Magnetic Shield
Case
Magnetic Shield
Case
(14 µA is total anode
current of 16 ch.)
(18 µA is total anode
0.45 18 at 800 V
current of 64 ch.)
(100 µA is total anode
0.37 100 at 800 V
current of 32 ch.)
(100 µA is total anode
0.18 100 at 1000 V
current of 64 ch.)
14 at 800 V
Note :
1 The maximum average anode current is defined as 5 % of divider current when standard high voltage is applied.
* marks: It's possible to attach an SHV connector fitting RG-174/U to the coaxial cable.
** marks: 50 Ω is a terminal resistor at anode output.
*** marks: It has 2 anode outputs and 1 dynode output.
43
Dimensional Outlines and Circuit Diagrams
For PMT Hybrid Assemblies
q H3164-10
w H3695-10
10.5 ± 0.6
11.3 ± 0.7
8 MIN.
8 MIN.
SIGNAL OUTPUT
: RG-174/U (BLACK)
PMT: R1635
WITH HA COATING
R10
C2
R9
C1
DY8
*MAGNETIC SHIELD
DY6
R8
DY5
P
MAGNETIC
SHIELD (t=0.2 mm)
WITH HEAT
SHRINKABLE TUBE
R7
DY4
R6
DY3
R5
POTTING
COMPOUND
R2
-H.V
: COAXIAL CABLE (RED)
-H.V
: COAXIAL CABLE (RED)
R1 to R11 : 330 kΩ
C1 to C3 : 0.01 µF
SIGNAL OUTPUT
: RG-174/U (BLACK)
R7
DY5
R6
DY4
R5
DY3
R4
DY2
R2
R3
R1
C1
DY6
R3
DY1
K
C2
R8
DY1
R4
10.6 ± 0.2
C3
R9
DY7
DY2
POTTING
COMPOUND
R10
DY8
PMT: R2496
WITH HA COATING
95.0 ± 2.5
DY7
MAGNETIC
SHIELD (t=0.2 mm)
WITH HEAT
SHRINKABLE TUBE
1500
C3
*MAGNETIC SHIELD
P
R11
PHOTOCATHODE
45.0 ± 1.5
PHOTOCATHODE
R1
K
-H.V
: COAXIAL CABLE (RED)
10.6 ± 0.2
1500
95.0 ± 2.5
45.0 ± 1.5
SIGNAL OUTPUT
: RG-174/U (BLACK)
R1 to R4 : 510 kΩ
R5 to R10 : 330 kΩ
C1 to C3 : 0.01 µF
-H.V
: COAXIAL CABLE (RED)
* MAGNETIC SHIELD IS CONNECTED
TO -H.V INSIDE OF THIS PRODUCT.
SIGNAL OUTPUT
: RG-174/U (BLACK)
* MAGNETIC SHIELD IS CONNECTED
TO -H.V INSIDE OF THIS PRODUCT.
TPMHA0309EC
e H3165-10
TPMHA0310EB
r H6520
23.5 ± 0.5
19.3 ± 0.7
14.3 ± 0.6
15 MIN.
1 MAX.
10 MIN.
PHOTOCATHODE
PMT: R647-01
WITH HA COATING
P
R11
C3
R10
C2
R9
C1
88 ± 2
DY9
DY8
130.0 ± 0.8
MAGNETIC
SHIELD (t=0.2 mm)
WITH HEAT
SHRINKABLE TUBE
R8
DY7
R7
DY6
R6
MAGNETIC SHIELD
CASE (t=0.5 mm)
R7
R6
DY5
R4
DY4
R3
DY3
R5
DY3
R4
R3
DY2
R2
-H.V
: RG-174/U (RED)
or EQUIV.
DY1
K
* MAGNETIC SHIELD IS CONNECTED
TO -H.V INSIDE OF THIS PRODUCT.
R1
POTTING
COMPOUND
R1 to R11 : 330 kΩ
C1 to C3 : 0.01 µF
1500
1500
SIGNAL OUTPUT
: RG-174/U (BLACK)
C1
DY6
R2
-H.V
: RG-174/U (RED)
or EQUIV.
C2
R9
DY7
DY4
12.4 ± 0.5
C3
R10
DY8
R5
R1
R11
DY9
R8
DY5
DY1
K
P
DY10
DY2
POTTING
COMPOUND
SIGNAL OUTPUT
: RG-174/U (BLACK)
PHOTOCATHODE
PMT: R1166
WITH HA COATING
DY10
*MAGNETIC SHIELD
116.0 ± 3.0
71 ± 2
SIGNAL OUTPUT
: RG-174/U (BLACK)
-H.V
:COAXIAL CABLE (RED)
R1 : 510 kΩ
R2 to R11 : 330 kΩ
C1 to C3 : 0.01 µF
-H.V
:COAXIAL CABLE (RED)
*
TO MAGNETIC
SHIELD CASE
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
SIGNAL OUTPUT
: RG-174/U (BLACK)
TPMHA0311EC
44
TPMHA0312EB
(Unit: mm)
t H6524
y H6613
15 MIN.
15 MIN.
SIGNAL OUTPUT
: RG-174/U (BLACK)
PHOTOCATHODE
88 ± 2
P
R11
C3
R10
C2
PMT: R2076
WITH HA COATING
DY10
R9
P
C1
DY8
R8
DY7
R7
DY6
MAGNETIC SHIELD
CASE (t=0.5 mm)
R7
R6
DY3
R5
R5
DY2
R4
R4
DY3
DY1
R3
R3
DY2
R2
R2
R1
-H.V
: COAXIAL CABLE (RED)
: 680 kΩ
: 510 kΩ
: 330 kΩ
: 0.01 µF
POTTING
COMPOUND
*
TO MAGNETIC
SHIELD CASE
1500
POTTING
COMPOUND
1500
C1
DY6
DY4
DY4
-H.V
: COAXIAL CABLE (RED)
C2
R9
DY5
DY5
R1
R3
R2, R4 to R11
C1 to C3
C3
R10
DY7
R8
R6
DY1
K
R11
DY8
DY9
130.0 ± 0.8
130.0 ± 0.8
MAGNETIC SHIELD
CASE (t=0.5 mm)
SIGNAL OUTPUT
: RG-174/U (BLACK)
PHOTOCATHODE
65 ± 2
PMT: R1450
WITH HA COATING
1 MAX.
23.5 ± 0.5
18.7 ± 1.0
1 MAX.
23.5 ± 0.5
19.3 ± 0.7
-H.V
: COAXIAL CABLE (RED)
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
SIGNAL OUTPUT
: RG-174/U (BLACK)
SIGNAL OUTPUT
: RG-174/U (BLACK)
K
R1
R1
R2
R3
R4, R6 to R11
R5
C1 to C3
-H.V
: COAXIAL CABLE (RED)
: 1 MΩ
: 750 kΩ
: 560 kΩ
: 330 kΩ
: 510 kΩ
: 0.01 µF
*
TO MAGNETIC
SHIELD CASE
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0313EA
u H6612
TPMHA0314EA
i H8135
23.5 ± 0.5
24.0 ± 0.5
19.3 ± 0.7
19.3 ± 1.0
15 MIN.
15 MIN.
P
65 ± 2
1 MAX.
PHOTOCATHODE
60.0 ± 0.8
1 MAX.
PHOTOCATHODE
SIGNAL OUTPUT
: RG-174/U (BLACK)
PMT: R3478
WITH HA COATING
R11
C3
R10
C2
R9
C1
DY8
MAGNETIC SHIELD
CASE (t=0.5 mm)
PMT: R5611-01
(WITH HA COATING &
HEAT SHRINKABLE
TUBING)
130.0 ± 0.8
R8
POTTING
COMPOUND
DY4
R6
DY7
R7
R1 : 1 MΩ
R2 to R11 : 330 kΩ
C1 to C3 : 0.01 µF
DY5
1500
R4
DY1
R3
R5
-H.V
: RG-174/U (RED)
DY4
R4
DY3
R3
R2
1500
C1
R8
R6
R5
DY2
-H.V
: COAXIAL CABLE (RED)
C2
R9
DY6
DY3
DY2
R2
R1
-H.V
: COAXIAL CABLE (RED)
: 1 MΩ
: 750 kΩ
: 560 kΩ
: 330 kΩ
: 510 kΩ
: 0.01 µF
5 10
R1
R2
R3
R4, R6 to R11
R5
C1 to C3
C3
R10
DY8
DY5
R7
POTTING
COMPOUND
R11
DY9
DY6
K
P
DY10
DY7
MAGNETIC SHIELD
CASE (t=0.5 mm)
SIGNAL OUTPUT
: RG-174/U (BLACK)
*
TO MAGNETIC
SHIELD CASE
SIGNAL OUTPUT
: RG-174/U (BLACK)
DY1
K
R1
-H.V
: RG-174/U (RED)
*
TO MAGNETIC
SHIELD CASE
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
SIGNAL OUTPUT
: RG-174/U (BLACK)
TPMHA0315EA
TPMHA0513EA
45
o H6533
!0 H6152-70
31.0 ± 0.5
26 ± 1
20 MIN.
31.0 ± 0.5
SIGNAL
OUTPUT
: RG-174/U
(BLACK)
P
R19
25.8 ± 0.7
SIGNAL OUTPUT
: RG-174/U
(BLACK)
17.5 MIN.
R23
C4
R22 R18
1 MAX.
1 MAX.
DY10
R17
71 ± 1
PHOTOCATHODE
R16
C3
C6
PMT: R5505-70
WITH SHRINKABLE
TUBING
R21 R15
PMT: R4998 (H6533)
R5320 (H6610)
WITH HA COATING
DY9
R14
C2
120.0 ± 0.8
R20 R13
R12
P
100.0 ± 0.8
R11
DY6
R10
DY5
R9
DY9
R10
DY8
+H.V
: COAXIAL
CABLE (RED)
R1 to R17
R18, R23
R19 to R21
R22
R24
C1 to C5
C6, C7
R9
: 330 kΩ
: 1 MΩ
: 51 Ω
: 100 kΩ
: 10 kΩ
: 0.01 µF
: 0.0047 µF
DY7
R8
R6
POTTING COMPOUND
(SILICONE & EPOXY)
R5
DY6
R7
DY5
R6
DY1
DY4
R5
1500 +50
-0
R4
R3
R2
+H.V
: COAXIAL CABLE (RED)
DY3
R4
DY2
R3
DY1
R1
-H.V
: COAXIAL
CABLE (RED)
*
R1, R3, R19 : 430 kΩ TO MAGNETIC
R2, R7 to R12, R15 to R17 : 330 kΩ SHIELD CASE
R4 : 820 kΩ
R5, R18 : 390 kΩ
R6, R14 : 270 kΩ
R13 : 220 kΩ
R20 to R22 : 51 Ω
C1 to C3 : 0.022 µF
C4 : 0.033 µF
R2
SIGNAL OUTPUT
: RG-174/U (BLACK)
5 10
1500
C1
R11
POM CASE
DY2
10
C2
R13
DY10
R7
5
C3
R14
R12
R8
SIGNAL OUTPUT
: RG-174/U (BLACK)
C4
R19 R15
R24
DY14
DY3
ACC
F
K
R20 R16
DY15
DY11
DY4
-H.V
: COAXIAL CABLE (RED)
C5
DY12
C1
DY7
POTTING
COMPOUND
R21 R17
DY13
DY8
MAGNETIC SHIELD
CASE (t=0.8 mm)
C7
R22
PHOTOCATHODE
R18
K
R1
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0317EB
!1 H8643
TPMHA0470EA
!2 H7415
31.0 ± 0.5
33.0 ± 0.5
26 ± 1
29.0 ± 0.7
22 MIN.
25 MIN.
SIGNAL OUTPUT
: RG-174/U
(BLACK)
1 MAX.
R16
PHOTOCATHODE
C4
R19 R15
85 ± 2
DY10
R14
PMT: R7899-01
(WITH HA COATING &
HEAT SHRINKABLE
TUBING)
C3
DY9
R18 R13
130.0 ± 0.8
120.0 ± 0.8
68 ± 1
1 MAX.
P
SIGNAL OUTPUT
: RG-174/U
(BLACK)
P
R12
C2
DY8
R17 R11
PHOTOCATHODE
PMT: R6427 (H7415)
R7056 (H7416)
WITH HA COATING
R9
R7
DY3
R5
DY2
R4
DY1
R3
R6
POTTING
COMPOUND
DY4
R5
DY3
R2
K
1500
R4
DY2
R3
-H.V
: COAXIAL CABLE (RED)
DY1
R1
-H.V
: COAXIAL CABLE (RED)
R1, R2, R4, R11, R12: 300 kΩ
R3, R5 to R10: 200 kΩ
R13, R14: 360 kΩ
R15, R16: 330 kΩ
R17 to R19: 51 Ω
C1, C2: 0.01 µF
C3: 0.022 µF
C4: 0.033 µF
-H.V
: COAXIAL
CABLE (RED)
5 10
R2
1500
R8
DY5
R1,R2 : 430 kΩ
R3 : 470 kΩ
R5 : 510 kΩ
R4,R6 to R13 : 330 kΩ
R14 to R16 : 51 Ω
C1 to C3 : 0.01 µF
R6
C1
R8
R7
5 10
R10
DY4
DY5
SIGNAL OUTPUT
: RG-174/U (BLACK)
C1
DY8
DY6
MAGNETIC SHIELD
CASE (t=0.5 mm)
DY7
K
C2
R14 R11
DY9
R9
DY6
POTTING
COMPOUND
C3
R15 R12
DY7
R10
MAGNETIC SHIELD
CASE (t=0.5 mm)
R16 R13
DY10
SIGNAL OUTPUT
: RG-174/U (BLACK)
R1
-H.V
: COAXIAL
CABLE (RED)
*
TO MAGNETIC
SHIELD CASE
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
*
TO MAGNETIC
SHIELD CASE
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0514EA
46
TPMHA0318EB
(Unit: mm)
!4 H3178-61
*
TO MAGNETIC
SHIELD CASE
SIGNAL OUTPUT
: BNC-R
47.0 ± 0.5
1 MAX.
39 ± 1
34 MIN.
P
R13
C4
*
TO MAGNETIC
SHIELD CASE
SIGNAL OUTPUT
: BNC-R
47.0 ± 0.5
39 ± 1
1 MAX.
!3 H3178-51
34 MIN.
P
R14
C4
R14 R12
R15 R13
DY10
DY10
R11
C3
PHOTOCATHODE
R12
PHOTOCATHODE
R10
C3
R11
DY9
PMT: R580
WITH HA COATING
R9
C2
R8
C1
PMT: R580-17
WITH HA COATING
DY8
R7
DY6
R6
DY5
R5
R10
C2
R9
162.0 ± 0.8
162.0 ± 0.8
DY7
MAGNETIC SHIELD
CASE (t=0.8 mm)
DY9
DY8
R8
R7
DY6
R6
DY4
DY5
R4
R5
DY3
DY4
R3
R4
DY2
R2
R3
* R580-17 has a plano-concave
face plate.
DY1
K
: 300 kΩ
: 150 kΩ
: 180 kΩ
: 220 kΩ
: 330 kΩ
: 240 kΩ
: 51 Ω
: 10 kΩ
: 0.01 µF
: 0.022 µF
: 0.047 µF
: 0.1 µF
: 4700 pF
SIGNAL
OUTPUT
: BNC-R
R16
R1
R1
R2, R3, R9, R12
R4 to R7
R8, R14
R10
R11
R13
R15
R16
C1
C2
C3
C4
C5
-HV
-H.V
: SHV-R
C5
R2
-H.V
: SHV-R
SIG
R1, R10, R12
R2 to R6, R13
R7
R8
R9
R11
R14
R15
C1
C2
C3
C4
C5
DY2
R15
R1
-HV
SIG
SIGNAL
OUTPUT
: BNC-R
DY3
C5
DY1
K
C1
DY7
MAGNETIC SHIELD
CASE (t=0.8 mm)
-H.V
: SHV-R
* R580-17 has a plano-concave
face plate.
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
-H.V
: SHV-R
: 390 kΩ
: 180 kΩ
: 150 kΩ
: 220 kΩ
: 160 kΩ
: 270 kΩ
: 300 kΩ
: 51 Ω
: 10k Ω
: 0.01 µF
: 0.022 µF
: 0.047 µF
: 0.1 µF
: 4700 pF
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0320EB
!5 H8409-70
!6 H6410
45.0 ± 0.5
PMT: R7761-70
WITH HEAT
SHRINKABLE TUBING
C7
C6
R27
P
R25 R21
C5
R24 R20
C4
R23 R19
C3
R18
C2
R17
C1
DY19
+50
R26
46 MIN.
P
+H.V
: SHIELD CABLE
(RED)
DY12
DY17
POM CASE
DY16
POTTING COMPOUND
(SILICONE & EPOXY)
DY15
+H.V
: SHIELD CABLE (RED)
R16
R15
DY13
R14
DY12
R13
DY11
SIGNAL OUTPUT
: RG-174/U (BLACK)
PHOTOCATHODE
DY11
PMT: R329-02 (H6410)
R2226 (H6521)
R5113 (H6522)
WITH HA COATING
DY10
DY9
DY8
DY7
DY6
DY5
DY18
DY14
1500 -0
1 MAX.
PHOTOCATHODE
53.0 ± 1.5
R1 to R21
R22, R28
R23 to R25
R26
R27
C1 to C5
C6, C7
: 330 kΩ
: 1 MΩ
: 51 Ω
: 10 kΩ
: 100 kΩ
: 0.01 µF
: 0.0047 µF
200.0 ± 0.5
1 MAX.
50 ± 2
80.0 ± 0.8
R28
27 MIN.
*
TO MAGNETIC
SHIELD CASE
SIGNAL OUTPUT
: BNC-R
60.0 ± 0.5
SIGNAL OUTPUT
: RG-174/U (BLACK)
39 ± 1
5 10
TPMHA0321EB
SH
MAGNETIC SHIELD
CASE (t=0.8 mm)
R12
R11
C5
C4
C3
C2
C1
R7
DY4
DY3
DY2
DY1
G
K
DY10
R18
R21 R17
R16
R20 R15
R14
R19 R13
R12
R11
R10
R9
R8
R6
R5
R4
R3
R2
R1
C6
R22
DY9
-H.V
: SHV-R
R10
DY8
R9
DY7
R8
DY6
R7
DY5
R6
DY4
R5
DY3
R4
SIGNAL
OUTPUT
: BNC-R
R2
K
R22
R1
SIG
R3
DY1
-HV
DY2
-H.V
: SHV-R
R1, R5
R2, R10, R16
R3, R9
R4, R6 to R8, R14, R18
R11, R13, R17
R12, R15
R19
R20, R21
R22
C1
C2
C3
C4
C5
C6
: 240 kΩ
: 220 kΩ
: 180 kΩ
: 150 kΩ
: 300 kΩ
: 360 kΩ
: 51 Ω
: 100 Ω
: 10 kΩ
: 0.022 µF
: 0.047 µF
: 0.1 µF
: 0.22 µF
: 0.47 µF
: 470 pF
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0476EA
TPMHA0324EB
47
!8 H1949-50
*
TO MAGNETIC
SHIELD CASE
ANODE OUTPUT 2
: BNC-R
ANODE OUTPUT 1
: BNC-R
DYNODE OUTPUT
: BNC-R
60.0 ± 0.5
1 MAX.
53.0 ± 1.5
46 MIN.
R25
C7
DY12
PMT: R329-02
WITH HA COATING
DY11
MAGNETIC SHIELD
CASE (t=0.8 mm)
215 ± 1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
G
K
DY
-HV
A1
A2
PHOTOCATHODE
C5
PMT: R1828-01 (H1949-50)
R2059 (H3177-50)
R4004 (H4022-50)
WITH HA COATING
C4
C3
C2
MAGNETIC SHIELD
CASE (t=0.8 mm)
C1
R1
-H.V
: SHV-R
C11
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
Acc
G
K
DYNODE
OUTPUT
: BNC-R
A1
-HV
A2
ANODE
OUTPUT 1
: BNC-R
-H.V
: SHV-R
ANODE
OUTPUT 2
: BNC-R
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
R17
R20 R16
R19 R15
R18 R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
C7
C10
C6
C5
C4
C3
C2
C9
C8
C12
C1
R1
R1, R21
R2, R5
R3, R7 to R12, R16
R4, R6
R13, R14, R17
R15
R18 to R20
C1
C2 to C4, C10
C5, C6
C7
C8, C9
C11, C12
: 10 kΩ
: 110 kΩ
: 100 kΩ
: 160 kΩ
: 51 Ω
: 100 Ω
: 470 pF
: 0.022 µF
: 0.047 µF
: 0.1 µF
: 0.22 µF
: 0.47 µF
: 0.01 µF
DYNODE
OUTPUT
: BNC-R
R21
P
DY
- H.V
: SHV-R
ANODE
OUTPUT 2
: BNC-R
ANODE
OUTPUT 2
: BNC-R
ANODE
OUTPUT 1
: BNC-R
46 MIN.
C6
R1, R25
R2 to R4, R17 to R19
R5, R6, R8 to R13, R15
R16, R20, R21
R7, R14
R22
R23, R24
C1
C2
C3
C4
C5
C6
C7
DYNODE
OUTPUT
: BNC-R
ANODE
OUTPUT 1
: BNC-R
R21
R24 R20
R19
R18
R23 R17
R16
R22 R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
53.0 ± 1.5
235.0 ± 0.5
P
PHOTOCATHODE
*
TO MAGNETIC
SHIELD CASE
60.0 ± 0.5
1 MAX.
!7 H7195
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0325EC
TPMHA0323EB
!9 H1949-51
@0 H2431-50
*
TO MAGNETIC
SHIELD CASE
1 MAX.
53.0 ± 1.5
SIGNAL OUTPUT
: BNC-R
46 MIN.
P
R17
C6
C9
*
TO MAGNETIC
SHIELD CASE
SIGNAL
OUTPUT
: BNC-R
60.0 ± 0.5
53.0 ± 1.5
1 MAX.
60.0 ± 0.5
46 MIN.
P
R16
R20 R16
C5
C8
C4
R12
C3
R11
C2
R10
C1
C7
200 ± 1
DY8
R9
235.0 ± 0.5
PMT: R2083 (H2431-50)
R3377 (H3378-50)
WITH HA COATING
DY6
R8
MAGNETIC SHIELD
CASE (t=0.8 mm)
R7
DY4
R9
C2
R8
C1
R7
DY2
R6
DY1
R5
R5
R4
DY2
R4
ACC
R3
F
K
R3
DY1
-HV
A1
R1, R4
R2, R5
R3, R6 to R11, R17
R12 to R16
R18 to R20
R21
C1 to C7
C8
C9
C10
C11
C3
DY5
DY3
R1
R10
DY3
DY5
R2
C12
R11
DY6
DY4
R6
C11
R21
-H.V
: SHV-R
: 240 kΩ
: 360 kΩ
: 200 kΩ
: 300 kΩ
: 51 Ω
: 10 kΩ
: 0.01 µF
: 0.022 µF
: 0.033 µF
: 0.01 µF
: 470 pF
SIGNAL
OUTPUT
: BNC-R
SIG
-HV
-H.V
: SHV-R
R2
C1
R1
-H.V
: SHV-R
R1: 33 kΩ
R2, R15: 390 kΩ
R3, R4, R13: 470 kΩ
R5: 499 kΩ
R6, R16: 360 kΩ
R7: 536 kΩ
R8 to R11: 300 kΩ
R12: 150 kΩ
R14: 430 kΩ
R17: 51 Ω
C1, C2: 4700 pF
C3 to C11: 0.01 µF
C12, C13: 1000 pF
C14: 2200 pF
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0326EC
48
C5
R12
DY7
-H.V
: SHV-R
C4
C13
R13
R18 R13
DY9
Acc
G1
K
C7
C11
DY7
DY10
MAGNETIC SHIELD
CASE (t=0.8 mm)
C6
C10
R14
PHOTOCATHODE
C10
R19 R14
DY11
PMT: R1828-01 (H1949-51)
R2059 (H3177-51)
R4004 (H4022-51)
WITH HA COATING
C9
DY8
R15
PHOTOCATHODE
C8
R17 R15
DY12
SIGNAL
OUTPUT
: BNC-R
-H.V
: SHV-R
: 10 kΩ
: 120 kΩ
: 100 kΩ
: 180 kΩ
: 150 kΩ
: 300 kΩ
: 51 Ω
: 470 pF
: 0.01 µF
: 0.022 µF
: 0.033 µF
: 4700 pF
: 0.01 µF
TPMHA0327EB
(Unit: mm)
@1 H6614-70
@2 H8318-70
60.0 ± 0.5
PHOTOCATHODE
80- 1
+0
PMT: R5924-70
WITH HEAT
SHRINKABLE TUBING
C6
R28
P
R26 R21
R27
+H.V
: COAXIAL
CABLE (RED)
C5
DY19
R25 R20
C4
R24 R19
C3
R23 R18
C2
64 ± 1
1 MAX.
39 MIN.
C7
71.0 ± 0.5
SIGNAL
OUTPUT
: RG-174/U
(BLACK)
R29
51 MIN.
C7
PHOTOCATHODE
BLACK COATING
DY16
POM CASE
DY15
AL PANEL
DY14
+H.V
: COAXIAL CABLE (RED)
DY13
R17
+0
R25 R20
C4
R24 R19
C3
R23 R18
C2
R17
C1
R27
+H.V
: SHIELD
CABLE (RED)
DY17
DY16
DY15
BLACK COATING
R16
DY14
POM CASE
R13
DY11
R12
DY10
R11
DY9
: 330 kΩ
: 1 MΩ
: 51 Ω
: 10 kΩ
: 100 kΩ
: 0.01 µF
: 0.0047 µF
R15
DY13
+H.V
: COAXIAL CABLE (RED)
R1 to R21
R22, R29
R23 to R26
R27
R28
C1 to C5
C6, C7
R14
DY12
R13
+50
R1 to R21
R22, R29
R23 to R26
R27
R28
C1 to C5
C6, C7
R14
DY12
1500 -0
+50
1500 -0
C5
DY18
C1
R15
DY11
AL PANEL
R12
DY10
R11
DY9
R10
DY8
5 10
R26 R21
DY19
PMT: R6504-70
WITH HEAT
SHRINKABLE TUBING
R16
SIGNAL OUTPUT
: RG-174/U (BLACK)
C6
R28
P
DY18
DY17
SIGNAL
OUTPUT
: RG-174/U
(BLACK)
R29
85- 1
1 MAX.
52 ± 1
R10
SIGNAL OUTPUT
: RG-174/U (BLACK)
R9
DY7
DY8
R9
DY7
5 10
R8
DY6
R8
DY5
: 330 kΩ
: 1 MΩ
: 51 Ω
: 10 kΩ
: 100 kΩ
: 0.01 µF
: 0.0047 µF
R8
DY6
R7
R6
DY5
R5
DY4
R4
DY3
R3
DY2
R2
DY1
R6
DY4
R5
DY3
R4
DY2
R3
DY1
R2
K
R22
R1
K
R22
R1
TPMHA0473EA
TPMHA0472EA
@4 H6525, H6526
@3 R2238-01
*
TO MAGNETIC
SHIELD CASE
84.5 ± 0.5
77 ± 1
1 MAX.
77.0 ± 1.5
70 MIN.
C3
C2
R13
C1
DY10
R12
DY9
R9
DY3
1500
C1
DY7
MAGNETIC SHIELD
CASE (t=0.8 mm)
R9
DY6
R8
C4
DY2
R4
R2
R1
-H.V
: RG-174/U
(RED)
HA
COATING
: 10 MΩ
: 1 kΩ
: 480 kΩ
: 240 kΩ
: 51 kΩ
: 0.01 µF
: 0.02 µF
: 0.03 µF
: 0.0047 µF
DY4
104.0 ± 0.5
(ASSY PARTS LENGTH)
R6
R1
R2
R3
R4 to R15
R16
C1
C2
C3
C4
C2
R10
R7
DY4
R3
C3
R11
DY5
DY5
DY1
K
R12
C10
DY8
R8
R7
SIGNAL OUTPUT
: RG-174/U (BLACK)
C7
DY9
DY6
R5
C8
C4
DY10
PMT: R4143 (H6525)
R4885 (H6526)
WITH HA COATING
285 ± 6
R10
DY7
-H.V
: RG-174/U (RED)
C5
R18 R13
R19 R14
DY11
DY8
PC-BOARD
C9
DY11
R11
60 ± 0.5
C6
R15
PHOTOCATHODE
DY12
R14
R17
R20 R16
DY12
205.0 ± 0.8
55 ± 2
75 ± 2
PMT: R2238
WITH HA COATING
AND HEAT
SHRINKABLE TUBE
R15
P
SIGNAL
OUTPUT
: RG-174/U
(BLACK)
R16
P
PHOTOCATHODE
SIGNAL
OUTPUT
: BNC-R
65 MIN.
R6
DY3
R5
DY2
R4
DY1
R3
G2
Acc
G1
K
67.0 ± 0.5
SIGNAL
OUTPUT
: BNC-R
SIG
-HV
-H.V
: SHV-R
R2
R1
R3, R4
R2, R5
R1, R6 to R11, R17
R12 to R16
R18 to R20
R21
C1 to C7
C8
C9
C10
C11
C11
R21
-H.V
: SHV-R
: 240 kΩ
: 360 kΩ
: 200 kΩ
: 300 kΩ
: 51 Ω
: 10 kΩ
: 0.01 µF
: 0.022 µF
: 0.033 µF
: 0.01 µF
: 470 pF
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
TPMHA0151EA
TPMHA0330EB
49
@6 H6527, H6528
83 ± 1
*
TO MAGNETIC
SHIELD CASE
SIGNAL OUTPUT
: BNC-R
65 MIN.
DY11
DY10
DY9
DY8
DY7
DY6
DY5
218 ± 1
PMT: R6091
WITH HA COATING
SH
G
K
C2
C1
R22
DY9
PMT: R1250 (H6527)
R1584 (H6528)
WITH HA COATING
R11
DY8
R10
DY7
-H.V
: SHV-R
R9
DY6
R8
DY5
R7
74
R6
BLACK TAPE
DY3
SOCKET ASSY
HOUSING
DY2
R5
R4
DY1
: 240 kΩ
: 220 kΩ
: 180 kΩ
: 150 kΩ
: 300 kΩ
: 360 kΩ
: 51 Ω
: 100 Ω
: 10 kΩ
: 0.022 µF
: 0.047 µF
: 0.1 µF
: 0.22 µF
: 0.47 µF
: 470 pF
G2
40
G1
K
SIG
-HV
SIGNAL
OUTPUT
: BNC-R
-H.V
: SHV-R
SIG
-HV
H6527=Flat window, Borosilicate
H6528=Curved window, UV glass
R1, R17 : 240 kΩ
R2 : 360 kΩ
R3 : 390 kΩ
R4 : 120 kΩ
R5 : 180 kΩ
R6 to R13 : 100 kΩ
R14, R15 : 150 kΩ
R16 : 300 kΩ
R18 : 51 Ω
R19, R20 : 100 Ω
R21 : 10 kΩ
R3
R2
R1
C6
R21
-H.V
: SHV-R
C1 : 0.022 µF
C2 : 0.047 µF
C3 : 0.1 µF
C4 : 0.22 µF
C5 : 0.47 µF
C6 : 470 pF
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
@7 R3600-06
508 ± 10
SIGNAL/HV GND
460 MIN.
R17
610 ± 20
PHOTOCATHODE
695 TYP.
C1
R12
DY4
TPMHA0331EB
PMT: R3600-02
254 ± 10
C4
R16
P
R15
DY11
R14
DY10
R13
DY9
R12
DY8
R11
DY7
R10
DY6
R9
DY5
R8
DY4
R7
DY3
R6
DY2
R5
DY1
R4
F3
R3
C3 R18
C2
C1
SIGNAL OUTPUT
: RG-58C/U
(BLACK)
+H.V
: RG-174/U
(WITHOUT SHIELD)
R2
(85)
HEAT
SHRINKABLE
TUBE
CABLE LENGTH
5000
F2
R1
F1
K
R1
R3
R4
R5
R2,R6 to R15
R16
R17, R18
C1, C2
C3, C4
: 1.3 MΩ
: 549 kΩ
: 5.49 kΩ
: 820 kΩ
: 274 kΩ
: 200 kΩ
: 10 kΩ
: 0.001 µF
: 4700 pF
TPMHA0156EC
50
C2
R13
DY10
C6
-H.V
: SHV-R
116
C3
R14
DY11
MAGNETIC SHIELD
CASE (t=0.8 mm)
* MAGNETIC SHIELD IS CONNECTED
TO GND INSIDE OF THIS PRODUCT.
82.7 ± 2.0
C4
R18 R15
DY12
77
R1, R5
R2, R10, R16
R3, R9
R4, R6 to R8, R14, R18
R11, R13, R17
R12, R15
R19
R20, R21
R22
C1
C2
C3
C4
C5
C6
70 ± 1
SIGNAL
OUTPUT
: BNC-R
C3
R6
R5
R4
R3
R2
R1
C5
R19 R16
DY13
PHOTOCATHODE
C4
R7
DY4
DY3
DY2
DY1
MAGNETIC SHIELD
CASE (t=0.8 mm)
R20 R17
DY14
140 ± 1
DY12
SIGNAL OUTPUT
: BNC-R
P
C5
259 ± 2
40 ± 1
PHOTOCATHODE
R18
R21 R17
R16
R20 R15
R14
R19 R13
R12
R11
R10
R9
R8
360 ± 6
P
131 ± 2
120 MIN.
56
1 MAX.
77.0 ± 1.5
*
TO MAGNETIC
SHIELD CASE
142.0 ± 0.8
1 MAX.
@5 H6559
TPMHA0332EC
(Unit: mm)
P9
2
0.3
Y
0.95
18.1
25.7
-HV INPUT
TERMINAL PINS
TERMINAL PINS
DY12 OUTPUT
P15 P16
R18
R20
R13
0.8 MAX.
C3
R9
R6
Dy5
P1
2.54
R7
Dy6
GND
12.7
P8
2.54×9=22.86
R8
Dy7
P9
P64
Dy4
P8
R4
Dy3
-HV INPUT
TERMINAL PINS
( 0.64)
Dy7
ANODE OUTPUT
TERMINAL PINS ( 0.64)
2.54 PITCH 8 × 8
Dy5
Dy4
R5
R4
Dy2
R3
Dy1
R2
R1 to R3 : 360 kΩ
R4 to R13 : 180 kΩ
R14 : 1 MΩ
R15 to R17 : 51 Ω
R18 : 10 kΩ
C1 to C4 : 0.01 µF
R2
F
Dy1
R1
F
K
R1, R5 to R14: 100 kΩ
R2 to R4, R15: 200 kΩ
R16: 300 kΩ
R17 to R19: 51 Ω
R20: 10 kΩ
R21: 1 MΩ
C1 to C3: 0.022 µF
C4: 0.01 µF
Dy3
R3
R1
R21
K
-HV INPUT
TERMINAL PIN
( 0.64)
R14
TPMHA0506EB
TPMHC0223EB
#1 H8500
P1 P2
P31 P32
C4
DY10
HOUSING (POM)
DY9
2.54
C2
R8
C1
DY8
DY7
R7
DY6
R6
DY5
R5
DY4
R4
6.08 × 6=36.48
INSULATING TAPE
PLASTIC BASE
3
1
10, 9, 2,
5
12, 11, 4,
GND
57, 50, 49
52, 51
SIG1
SIG2
58,
60, 59
61, 54, 53
SIG3
M3 DEPTH 5
4-SIGNAL OUTPUT CONNECTOR *B
TMM-118-03-G-D, mfg. SAMTEC
PC BOARD
TOP VIEW
62
DY, 64, 63
0.5
SIG4
56, 55
36
2 × 17=34
51.3
51.7 ± 0.5
-HV
16, 15,
14, 13, 6,
8, 7
H8500
2
PHOTOCATHODE (EFFECTIVE AREA)
49
6.26
6.08 × 6=36.48
52.0 ± 0.3
6.26
SIDE VIEW
NOTE *A: Polarized position of omitted pin
*B: Suitable sockets for the signal connectors will be attached.
The equivalent socket is SQT-118-01-L-D (SAMTEC).
As it doesn't have a polarized position marker,
it can be used at any positions.
-HV: SHV-P
(COAXIAL CABLE, RED)
BOTTOM VIEW
K
DY1 DY2 DY3 DY4 DY5 DY6 DY7 DY8 DY9 DY10 DY11 DY12
GR
P8
P64
P7
P63
P6
P62
P5
P61
P4
P60
P3
P59
P2
P58
P1
P57
C7
ANODE #1 to #32 OUTPUT ( 0.46)
(16 PIN × 2 LINE 2.54 PITCH)
R16
R17
R18
C1
C2
C3
R19
R9
DIVIDER CURRENT
: 180 µA(at -1100 V)
TPMHA0455ED
ANODE OUTPUT (P64)
ANODE OUTPUT (P63)
ANODE OUTPUT (P62)
ANODE OUTPUT (P8)
ANODE OUTPUT (P7)
R1 to R7 : 220 kΩ
R8, R9 : 51 Ω
R10 : 1 MΩ
R11 : 10 kΩ
C1 to C4 : 0.01 µF
R1 to R9: 470 kΩ
R16 to R18: 51 Ω
R19: 10 kΩ
R20: 10 kΩ
R21: 1 MΩ
C1: 0.01 µF
C2: 0.022 µF
C3: 0.033 µF
C7: 0.0047 µF
C8, C9: 0.015 µF
ANODE OUTPUT (P6)
-HV
SHV-P
(COAXIAL CABLE, RED)
ANODE OUTPUT (P5)
R10
ANODE OUTPUT (P61)
....
......
ANODE OUTPUT (P60)
TRANSISTOR CIRCUIT
R20
ANODE OUTPUT (P59)
R8
(P49 to P56)
R7
ANODE OUTPUT (P58)
R6
ANODE OUTPUT (P4)
-HV INPUT
TERMINAL ( 0.5)
R5
ANODE OUTPUT (P3)
7.62
5.08
2.54
ANODE #2
R4
C8
C9
DY1
G
K
R3
ANODE OUTPUT (P57)
R2
R2
(P9 to P16)
R1
ANODE OUTPUT (P2)
GND TERMINAL
PIN ( 0.5)
DY OUT A31-ANODE - A1 GND
A32-ANODE - A2 -HV
P57 P58 P59 P60 P61 P62 P63 P64
6.26
CONNECTION FOR SIGNAL CONNECTORS
(BOTTOM VIEW)
GND P7
GND P5
GND P3
GND P1
GND P8
GND P6
GND P4
GND P2
GND P15 GND P13 GND P11 GND P9
GND P16 GND P14 GND P12 GND P10
GND P23 GND P21 GND P19 GND P17
GND P24 GND P22 GND P20 GND P18
GND P31 GND P29 GND P27 GND P25
GND P32 GND P30 GND P28 GND P26
GND P39 GND P37 GND P35 GND P33
GND P40 GND P38 GND P36 GND P34
GND P47 GND P45 GND P43 GND P41
GND P48 GND P46 GND P44 GND P42
GND P55 GND P53 GND P51 GND P49
GND P56 GND P54 GND P52 GND P50
GND P63 GND P61 GND P59 GND P57
GND P64 GND P62 GND P60 GND P58
GND DY12 GND GND
*A GND GND *A
GND GND GND GND
*A GND GND *A
SIG4
SIG3
SIG2
SIG1
R3
DY2
R1
ANODE #32
P49 P50 P51 P52 P53 P54 P55 P56
SIGNAL GND
ANODE #1
P41 P42 P43 P44 P45 P46 P47 P48
R21
DY3
DY10 OUTPUT
PIN ( 0.5)
P33 P34 P35 P36 P37 P38 P39 P40
DY12 OUTPUT
2.54 × 15 = 38.1
C3
R9
ACTIVE BASE CIRCUIT
35.0 ± 0.5
R11 SHIELD
P9 P10 P11 P12 P13 P14 P15 P16
P25 P26 P27 P28 P29 P30 P31 P32
12 × 3=36
4.5 ± 0.3
4
2
4
450 ± 20
SHIELD
P1 P2 P3 P4 P5 P6 P7 P8
P17 P18 P19 P20 P21 P22 P23 P24
6.26
GND TERMINAL PIN
DY10 OUTPUT
0.8
0.8 TYP.
ANODE
WINDOW #1
32.7 ± 1.0
27.4 ± 0.9
14.4 ± 0.5
1.5
START MARK
VOLTAGE DIVIDER CURRENT = 0.37 mA at -900 V (MAX. RATING) INPUT
ANODE
WINDOW #32
ANODE32 OUTPUT
7
ANODE1 OUTPUT
1
ANODE31 OUTPUT
31.8
ANODE2 OUTPUT
8 × 2 LINE
2.54 PITCH
52.0 ± 0.5
-HV INPUT TERMINAL PIN
#0 H7260
3.3
R7
R6
GND TERMINAL
PIN ( 0.64)
TPMHA0487EC
7.5
Dy6
Dy2
BOTTOM VIEW
ANODE #31
R8
P57
Dy12 OUTPUT
TERMINAL PIN
( 0.64)
R5
-HV
P16
GND
2.54
Dy8
DY
P1
2.54 × 7=17.78
4-SCREWS (M2)
ANODE OUTPUT (P1)
3.7
3.2
R10
Dy8
2.54×7=17.78
R9
-HV INPUT
TERMINAL PINS
( 0.46)
R11
2.54
C1
Dy9
7.62
Dy12 OUTPUT
TERMINAL PIN
( 0.46)
R12
Dy9
4.2
5.2
C2
R10
2.54
C1
POM CASE
R15 R11
1.27
R13
R17
Dy10
Dy10
ANODE OUTPUT
TERMINAL PIN
( 0.46,
2.54 PITCH 8 × 4)
R14
C2
R18
Dy12
SIDE VIEW
5.08
R15
Dy12
PMT:
R7600-00-M64
R17
R16 R12
2.54
R16
C3
C4
R19
Dy11
C4
Dy11
4-SCREWS
(M2)
ANODE64 OUTPUT
Dy12 OUTPUT
TERMINAL PIN ( 0.64)
GND TERMINAL PIN
( 0.64) × 2
P64
POM CASE
DIVIDER
ASSEMBLY
24.0 ± 0.5
P63
SOFT TAPE
INSULATING
TAPE
P8
2.54 PITCH
..
( 0.64)
ANODE63 OUTPUT 8 × 8
30.0 ± 0.5
R34
P1 P2
X
GUIDE
MARKS
45 ± 0.8
1 MAX.
PMT:
R7600-00-M16
45 ± 1
GND
GND
GND
GND
GND
GND
GND
ANODE16 OUTPUT
ANODE15 OUTPUT
ANODE9 OUTPUT
TERMINAL PINS
ANODE8 OUTPUT
ANODE2 OUTPUT
TERMINAL PINS
4.2
0.3
1
ANODE1 OUTPUT
2
13
30.0 ± 0.5
ANODE1 OUTPUT
ANODE2
. OUTPUT
P1
P2
..
.
1 2 3 4 5 6 7 8
3
14
TOP VIEW
4- 3 GUIDE MARKS
57 58 59 60 61 6263 64
15
18.1
4- 0.3
GUIDE MARKS
4
16
25.7
4 × 16
4.5 PITCH
5
25.7
GND
@9 H7546B
4
@8 H8711
4-(DOUBLE-ROW 2 mm Pitch) CONNECTOR
TPMHA0498ED
51
Quick Reference for PMT Socket Assemblies
PMT Characteristics
Assembly Characteristics
Tube Type No. RefeAssembly
/
rence Outline
Tube
Type
Voltage
Page for No.
Diameter
No.
Distribution
PMT
Ratio
Feature
E1761-21
E1761-22
E849-90
E849-68
E974-17
E974-22
E2253-05
E974-19
E2037-02
E6133-04
E2924-11
10 mm
(3/8")
13 mm
(1/2")
19 mm
(3/4")
25 mm
(1")
25 mm
(1")
E2924-500
28 mm
(1-1/8")
E2624-14 28 mm
E2624-04 (1-1/8")
E2183-500
38 mm
(1-1/2")
E2183-501
E1198-07 51 mm
E2979-500 (2")
E1198-05
E1198-20
E1198-26
51 mm
(2")
60 mm
(2.4")
76 mm
(3")
E1198-27
E5859
E5859-01
E6316-01
E7693
E7694
51 mm
(2")
76 mm
(3")
127 mm
(5")
R1635
R2248
R2496
R647-01
R2102
R4124
R1166
R1450
R3478
R4125
R1548-07
R5505-70
R7899
y
i
!5
@8
!8
@4
!2
!9
#0
%5
@8
R1924A
18
22
18
18
22
18
18
18
18
18
22
18
19
R7111
204 mm
R5912
(8")
254 mm
R7081
(10")
Signal
Output
Terminal
1
Maximum
Overall Bleeder Average Anode
Current
Voltage Current
Maximum Rating
Output
Signal
(V)
(mA)
(µA)
z
SHV
BNC
DC/PULSE
-1500
0.41
17 at 1250 V
z
SHV
BNC
DC/PULSE
-1500
0.37
15 at 1250 V
x
SHV
BNC
DC/PULSE
-1250
0.34
14 at 1000 V
c
v
v
b
n
m
,
.
AWG22
SHV
SHV
SHV
AWG22
AWG24
SHV
AWG22
RG-174/U
BNC
BNC
BNC
RG-174/U
AWG24
BNC
RG-174/U
DC/PULSE
DC/PULSE
DC/PULSE
DC/PULSE
DC/PULSE
DC/PULSE
PULSE
DC/PULSE
-1250
-1800
-1800
-1800
-1800
-1750
+2300
-1800
0.28
0.47
0.43
0.35
0.32
0.18
0.41
0.41
11 at 1000 V
19 at 1500 V
18 at 1500 V
17 at 1700 V
13 at 1500 V
6 at 1250 V 6 µA is for total of 2 anodes.
17 at 2000 V E6133-03 (-HV) is available.
13 at 1250 V For R7899 (Glass Gase Type)
⁄0
SHV
BNC
DC/PULSE
-1250
0.30
11 at 1000 V
⁄1
⁄2
SHV
AWG22
BNC
RG-174/U
DC/PULSE
DC/PULSE
⁄3
SHV
BNC
DC/PULSE
⁄3
SHV
BNC
DC/PULSE
⁄4
⁄5
AWG22
SHV
RG-174/U
BNC
DC/PULSE
DC/PULSE
-2000
-2000
-1750
-1250
-1250
-1750
-1250
-1250
-1750
-3000
0.42
0.49
0.45
0.32
0.32
0.63
0.45
0.45
0.44
0.70
15 at 1500 V
18 at 1500 V
15 at 1250 V
12 at 1000 V
12 at 1000 V
26 at 1500 V
17 at 1000 V
17 at 1000 V
15 at 1250 V
29 at 2500 V with shield case
⁄6
AWG22
RG-174/U
DC/PULSE
-1500
0.46
15 at 1000 V -HV
⁄7
Coaxial
Cable
RG-174/U
PULSE
+1500
0.46
15 at 1000 V +HV
⁄8
Coaxial
Cable
RG-174/U
DC/PULSE
-1500
0.38
12 at 1000 V -HV
⁄8
Coaxial
Cable
RG-174/U
PULSE
+1500
0.38
12 at 1000 V +HV
⁄9
SHV
BNC
DC/PULSE
-2700
-2500
0.67
0.62
18 at 1500 V
⁄9
SHV
BNC
DC/PULSE
-2700
-2500
0.75
0.70
¤0
SHV
BNC
DC/PULSE
-1500
-2000
0.38
0.51
shield case is available.
+HV type (E5859-02) is available.
shield case is available.
20 at 2000 V +HV type (E5859-03) is
available.
15 at 1250 V
shield case is available.
18 at 1500 V
¤1
SHV
BNC
DC/PULSE
-3000
1.03
34 at 2000 V
¤1
SHV
BNC
DC/PULSE
-1800
0.39
15 at 1500 V
18
#0
#1
@1
@3
@1
$0
t
t
u
u
$8
$6
!6
%0
18
18
18
18
18
18
18
18
20
20
20
22
20
20
22
20
20
20
20
20
20
20
20
20
20
20
20
20
20
20
20
20
%2
20
Note: 1 The maximum average anode current is defined as 5 % of divider current when standard high voltage is applied.
52
Notes
18
@7
R6427
R6427
R580
R980
R3886
R580
R980
R3886
R2154-02
R1828-01
R1306
R1538
R1307
R1306
R1538
R1307
R6231
R6232
R6233
R6231
R6232
R6233
R329-02
R6091
R329-02
R331-05
R6091
R877
R1512
R1250
R1584
H.V
Input
Terminal
+HV type (E7694-01) is
available.
PMT Characteristics
Assembly Characteristics
Tube Type No. RefeAssembly
/
rence Outline
Tube
Type
Voltage
Page for No.
Diameter
No.
Distribution
PMT
Ratio
Feature
E5770
E5780
E5996
E7083
E6736
E7514
Signal
Output
Terminal
1
Maximum
Overall Bleeder Average Anode
Current
Voltage Current
Maximum Rating
Output
Signal
(V)
(mA)
Notes
(µA)
22
¤2
PIN
PIN
DC/PULSE
-1000
0.36
14 at 800 V on-board type
22
¤3
AWG22
RG-174/U
DC/PULSE
-1000
0.36
14 at 800 V cable type
@0
22
¤4
RG-174/U
RG-174/U
DC/PULSE
-900
0.33
14 at 800 V
@0
22
¤5
RG-174/U
DC/PULSE
-900
0.33
14 at 800 V
!5
22
¤6
RG-174/U
DC/PULSE
-900
0.38
16 at 800 V
#4
38
¤7
RG-174/U
DC/PULSE
-1000
0.34
13 at 800 V
16 mm
r
R7400U
TO-8
R7400U-06
Type
r
R7600U
R7600U-03
R7600U
30 mm
-00-M4
Square
R5900U
Type
-00-L16
R8520U
-00-C12
H.V
Input
Terminal
Coaxial
cable
Coaxial
cable
Coaxial
cable
Active base type
(E6572) is available.
Note: 1 The maximum average anode current is defined as 5 % of divider current when standard high voltage is applied.
53
Dimensional Outline and Circuit Diagrams
For PMT Socket Assemblies
z E1761-21, E1761-22
E1761-21
SOCKET
PMT PIN No.
6
3
10.6 ± 0.2
SIGNAL OUTPUT
: RG-174/U (BLACK)
BNC CONNECTOR
50.0 ± 0.5
SOCKET: E678-11N
PMT
SOCKET
PIN No.
P
R10 C3
R11 C3
DY8
7
R10 C2
DY7
5
SIGNAL OUTPUT
: RG-174/U (BLACK)
BNC CONNECTOR
DY6
8
DY5
4
-H.V
: RG-174/U
or EQUIV. (RED)
SHV CONNECTOR
DY4
9
DY3
3
DY2
10
DY1
K
SIGNAL OUTPUT
RG-174/U (BLACK)
BNC CONNECTOR
6
P
POM HOUSING
450
E1761-22
R9 C1
R8
R7
R1 to R11 C1:330 kΩ
C1 to C3:0.01 µF
R6
R5
R4
R3
DY8
7
DY7
5
DY6
8
DY5
4
DY4
9
DY3
3
DY2
10
DY1
2
R9 C2
R8 C1
R1 to R4 : 510 kΩ
R5 to R10 : 330 kΩ
C1 to C3 : 10 nF
R6
R5
R4
R3
R2
R1
2
11
R7
R2
R1
-H.V
: RG-174/U
or EQUIV. (RED)
SHV CONNECTOR
K
-H.V
: RG-174/U or
COAXIAL CABLE (RED)
SHV CONNECTOR
11
TACCA0075EA
x E849-90
TACCA0076EB
c E849-68
PMT
SIGNAL GND
SIGNAL OUTPUT
RG-174/U (BLACK)
SOCKET
PIN No.
6
P
12.6
0.5 MAX.
PMT
SIGNAL OUTPUT
RG-174/U (BLACK)
BNC CONNECTOR
DY10
12.4
7
R10 C2
HOUSING
(INSULATOR)
45.0 ± 0.5
R11 C3
DY9
5
DY8
8
R9 C1
R1 to R11: 330 kΩ
C1 to C3: 10 nF
14.0 ± 0.3
10 5
14.0 ± 0.3
12.6
12.4
4
DY6
9
450 ± 10
3
DY4
10
2
11
DY1
1
K
13
C3
R10
C2
R9
C1
POWER SUPPLY GND
AWG22 (BLACK)
9
DY7
5
DY6
10
DY5
4
R7
R5
11
DY3
3
R3
DY2
12
R2
DY1
K
2
R4
DY3
6
DY4
R5
DY2
DY9
R11
R6
POTTING
COMPOUND
R6
DY5
8
DY8
HOUSING
(INSULATOR)
R7
POTTING
COMPOUND
DY10
R8
R8
DY7
P
450 ± 10
0.5 MAX.
7
10 5
45.0 ± 0.5
SOCKET
PIN No.
R1: 1 MΩ
R3: 510 kΩ
R2, R4 to R11: 330 kΩ
C1 to C3: 10 nF
R4
R3
R2
R1
-HV
COAXIAL CABLE (RED)
SHV CONNECTOR
R1
-HV
AWG22 (VIOLET)
13
TACCA0077EC
TACCA0210EB
v E974-17, E974-22
E974-17
PMT
SOCKET
PIN No.
SIGNAL OUTPUT
RG-174/U (BLACK)
BNC CONNECTOR
5
P
23.0 ± 0.5
DY10
DY9
4
DY8
7
DY7
3
DY6
8
DY5
2
C3
C2
DY10
6
R9
C1
DY9
4
DY8
7
P
450 ± 10
R8
DY7
3
DY6
8
DY5
2
DY4
9
DY3
1
DY2
10
DY1
12
R7
R1 : 510 kΩ
R2 to R11 : 330 kΩ
C1 to C3 : 10 nF
9
R4
DY3
R11 C3
R9 C1
R6
DY4
R5
R4
1
10
R3
R2
R2
E974-17, -18 attaches BNC
and SHV connector at the
end of cables.
DY1
K
12
R1
11
-HV
COAXIAL CABLE (RED)
SHV CONNECTOR
TACCA0212EB
54
R1:680 kΩ
R3:510 kΩ
R2, R4 to R11:330 kΩ
C1 to C3:10 nF
R6
R3
DY2
SIGNAL OUTPUT
RG-174/U(BLACK)
BNC CONNECTOR
R10 C2
R5
POTTING
COMPOUND
5
R10
R7
HOUSING
(INSULATOR)
PMT
R11
6
R8
43.0 ± 0.5
47.5 ± 1.0
17.4 ± 0.2
E974-22
SOCKET
PIN No.
R1
K
11
-HV
COAXIAL CABLE(RED)
SHV CONNECTOR
TACCA0078EC
(Unit: mm)
b E2253-05
n E974-19
SOCKET
PIN No.
PMT
SIGNAL OUTPUT
: RG-174/U (BLACK)
5
SOCKET
PIN No.
P
SIGNAL OUTPUT
RG-174/U (BLACK)
BNC CONNECTOR
5
55.0 ± 0.5
6.2
18.6 ±
0
0.4
HOUSING
(INSULATOR)
P
R11
DY8
7
DY7
3
DY6
8
DY5
2
DY4
9
C3
R10
C2
R9
C1
R8
R7
450 ± 10
POTTING
COMPOUND
1
DY2
10
DY1
12
R14
R13
C2
R12
R11
POM
HOUSING
DY9
4
R10
C1
R9
R5
DY8
7
R8
R4
-HV
: AWG22 (VIOLET)
+20
-HV
COAXIAL CABLE (RED)
SHV CONNECTOR
DY7
3
DY6
8
DY5
2
R7
R1: 499 kΩ
R2 to R7: 330 kΩ
R8,R11 to R13: 390 kΩ
R9, R10: 300 kΩ
R14 to R16: 360 kΩ
C1 to C3: 0.01 µF
R6
GND
: AWG22 (BLACK)
450 -0
R3
R2
R1
11
K
C3
6
SOCKET
: E678-12H
R6
DY3
R15
17.4 ± 0.2
DY10
R1:1 MΩ
R2:750 kΩ
R3:560 kΩ
R4, R6 to R11:330 kΩ
R5:510 kΩ
C1 to C3:10 nF
GND
: AWG22 (BLACK)
R16
23.0 ± 0.5
47.5 ± 1.0
43.0 ± 0.5
PMT
R5
DY4
SIGNAL OUTPUT
: RG-174/U (BLACK)
9
R4
DY3
1
DY2
10
DY1
12
R3
5 10
5
R2
K
R1
-HV
: AWG22
(VIOLET)
11
TACCA0079EB
m E2037-02
, E6133-04
PMT
SOCKET
PIN No.
2
2
24.0 ± 0.5
R11
C3
R10
C2
22.0 ± 0.5
POWER SUPPLY GND
: AWG24(BLACK)
9
DY9
6
DY8
10
DY7
11
R9
P
SOCKET:
E678-17C
2
21.9
POM HOUSING
R19
SIGNAL OUTPUT1
: AWG24(YELLOW)
SIGNAL GND
: AWG24(BLACK)
7
SOCKET: E678-17C
C1
POM
HOUSING
DY15
9
DY14
11
DY13
8
DY12
12
DY11
7
R18
C5
R23
R17
C4
R22
R16
C3
R15
C2
R14
C1
R13
DY10
13
R12
POTTING
COMPOUND
DY9
6
DY8
14
SIGNAL OUTPUT
: RG-174/U (BLACK)
BNC CONNECTOR
DY7
5
DY6
15
+H.V
: SHIELD CABLE (RED)
SHV CONNECTOR
DY5
4
DY4
16
DY3
3
R3
DY2
17
R2
DY1
2
5
R1 : 2.7 MΩ
R2, R4 to R11 : 680 kΩ
R3 : 1 MΩ
C1 to C3 : 0.01 µF
450 ± 10
R7
DY6
12
R6
DY5
4
DY4
13
450 ± 10
DY7
R5
R11
DY2
DY1
R1: 10 kΩ
R2 to R18: 330 kΩ
R19: 100 kΩ
R20, R21: 1 MΩ
R22 to R24: 51 Ω
C1 to C5: 0.01 µF
C6, C7: 4700 pF
R9
R8
R7
R6
3
R5
14
R4
2
R3
K
R1
K
+H.V
: SHIELD CABLE
(RED)
SHV CONNECTOR
R10
R4
DY3
C7
R1
R24
R8
POTTING
COMPOUND
SIGNAL OUTPUT
: RG-174/U (BLACK)
BNC CONNECTOR
10
24 ± 0.5
P
DY10
SOCKET
R20
PIN No. C6
SIGNAL OUTPUT2
: AWG24(RED)
8
55.0 ± 0.5
PMT
30.0 ± 0.5
TACCA0230EA
R2
R21
-HV
: AWG24(VIOLET)
17
1
TACCA0028EB
. E2924-11
TACCA0231EA
⁄0 E2924-500
44.0 ± 0.3
30.0 ± 0.3
P
10
DY9
6
DY8
R12
C2
R11
C1
DY7
5
DY6
12
DY5
4
43.0 ± 0.5
R9
R1 to R13 : 330 kΩ
C1 to C3 : 10 nF
R8
R7
28.0 ± 0.5
HOUSING
(INSULATOR)
DY4
13
DY3
3
R6
DY2
450 ± 10
POTTING
COMPOUND
14
R4
DY1
2
R3
SIGNAL OUTPUT
RG-174/U (BLACK)
BNC CONNECTOR
7
2- 3.5
P
Dy10
10
Dy9
6
Dy8
11
28.0 ± 0.5
HOUSING
(INSULATOR)
POTTING
COMPOUND
R5
450 ± 10
43.0 ± 0.5
R10
26.0 ± 0.3
PMT SOCKET
PIN No.
26.0 ± 0.3
11
7
3.5
DY10
0.8
2-
R13
SIGNAL GND
SIGNAL OUTPUT
RG-174/U (BLACK)
POWER SUPPLY GND
C3 AWG22 (BLACK)
7
35.0 ± 0.3
35.0 ± 0.3
SOCKET
PIN No.
7
0.8
PMT
30.0 ± 0.3
44.0 ± 0.3
Dy7
5
Dy6
12
Dy5
4
Dy4
13
Dy3
3
Dy2
14
Dy1
2
K
R13
C3
R12
C2
R11
C1
R10
R9
R8
R6
R5
R4
R3
R2
1
R1 to R13: 330 kΩ
C1 to C3: 10 nF
C4: 4.7 nF
R7
R1
C4
-HV
SHIELD CABLE (RED)
SHV CONNECTOR
R2
K
R1
1
-HV
AWG22 (VIOLET)
TACCA0032EC
TACCA0081EC
55
⁄1 E2624-14
⁄2 E2624-04
44.0 ± 0.3
35.0 ± 0.3
30.0 ± 0.3
PMT SOCKET
PIN No.
32.0 ± 0.5
P
HOUSING
(INSULATOR)
28.0 ± 0.5
450 ± 10
POTTING
COMPOUND
Dy9
5
Dy8
9
Dy7
4
Dy6
10
Dy5
3
Dy4
11
Dy3
2
Dy2
12
K Dy1
R13 R10
C2
R12 R9
C1
14
R1:
R3:
R2, R4 to R11:
R12 to R14:
C1 to C3:
C4:
R8
1320 kΩ
510 kΩ
330 kΩ
51 Ω
10 nF
4.7 nF
PMT SOCKET
PIN No.
SOCKET
: E678-14T
R7
P
Dy10
8
Dy9
5
Dy8
9
Dy7
4
Dy6
10
Dy5
3
Dy4
11
Dy3
2
Dy2
12
K Dy1
14
POM
HOUSING
R6
R5
POTTING
COMPOUND
R4
R3
R2
C4
-H.V
: COAXIAL CABLE (RED)
SHV CONNECTOR
R1
13
SIGNAL OUTPUT
: RG-174/U (BLACK)
7
4
8
-H.V
: AWG22/TFE
(VIOLET)
450 ± 10
0.8
7
26.0 ± 0.3
25.2 ± 0.5
C3
49.0 ± 0.5
R14 R11
Dy10
2- 3.5
43.0 ± 0.5
SIGNAL OUTPUT
: RG-174/U (BLACK)
BNC CONNECTOR
7
GND
: AWG22 (BLACK)
C5
R13 R10
C4
R12 R9
C3
R8
C2
R7
C1
C6
GND
: AWG22 (BLACK)
R1
R2, R4 to R6
R3, R8
R7
R9
R10
R11
R12 to R14
C1
C2, C3
C4 to C6
R6
R5
:800 kΩ
:200 kΩ
:300 kΩ
:240 kΩ
:400 kΩ
:660 kΩ
:600 kΩ
:51 Ω
:0.01 µF
:0.022 µF
:0.033 µF
R4
R3
R2
-H.V
: AWG22/TFE
(VIOLET)
R1
13
5 10
SIGNAL OUTPUT
: RG-174/U (BLACK)
R14 R11
TACCA0082EC
TACCA0084EC
⁄3 E2183-500, E2183-501
E2183-500
SOCKET
PIN NO.
6
PMT
E2183-501
SIGNAL OUTPUT
:RG-174/U (BLACK)
BNC CONNECTOR
PMT SOCKET
PIN No.
P
P
DY10
52.0 ± 0.5
8.2
34.0 ± 0.3
40.0 ± 0.5
DY8
C3
R11
C2
R10
C1
5
8
R9
POM HOUSING
DY7
4
DY6
9
R1
R2
R3 to R12
C1 to C3
C4
R8
POTTING
COMPOUND
R7
DY5
: 10 kΩ
: 660 kΩ
: 330 kΩ
: 0.01 µF
: 4700 pF
DY4
10
Dy9
5
Dy8
8
Dy7
4
Dy6
9
C4
R12
R11
C3
R10
C2
R9
C1
DY3
2
DY2
11
DY1
1
R1:10 kΩ
R2, R11, R13:300 kΩ
R3 to R7, R14:150 kΩ
R8:180 kΩ
R9:220 kΩ
R10:330 kΩ
R12:240 kΩ
R15 :51 Ω
C1:0.01 µF
C2:0.022 µF
C3:0.047 µF
C4:0.1 µF
C5:4700 pF
R8
R7
3
Dy4
10
Dy3
2
Dy2
11
K Dy1
1
R6
R5
R4
C5
R3
-H.V
: COAXIAL CABLE (RED)
SHV CONNECTOR
R2
12
R5
-H.V
: COAXIAL CABLE (RED)
SHV CONNECTOR
R14
R15 R13
7
Dy5
3
R6
SIGNAL OUTPUT
: RG-174/U (BLACK)
BNC CONNECTOR
450 ± 10
Dy10
7
SOCKET: E678-12A
DY9
R12
SIGNAL OUTPUT
: RG-174/U (BLACK)
BNC CONNECTOR
6
R1
R4
K
R3
C4
R2
R1
12
-HV
: COAXIAL CABLE(RED)
SHV CONNECTOR
TACCA0166EB
⁄4 E1198-07
TACCA0086EB
⁄5 E2979-500
62.0 ± 0.5
SOCKET
PIN No.
11
P
SIGNAL GND
R11
DY10
10
DY9
9
DY8
8
64.0 ± 0.3
DY7
7
56.0 ± 0.3
DY6
6
R10
C2
R9
C1
DY12
MAGNETIC
SHILD CASE
R8
DY5
5
38.0 ± 0.5
R5
DY4
R1 : 680 kΩ
R2 to R11 : 330 kΩ
C1 to C3 : 10 nF
C4 : 4.7 nF
4
3-M2
11
C4
82.0 ± 0.5
R7
R6
HOUSING
(METAL)
R4
DY3
HOUSING
(METAL)
3
R3
DY2
2
450 ± 10
R2
DY1
1
R1
K
14
SIG
-H.V
SIGNAL
OUTPUT
: BNC-R
TACCA0220EB
56
11
DY11
8
DY10
12
DY9
7
DY8
13
DY7
6
DY6
14
DY5
5
DY4
15
DY3
3
DY2
17
DY1
G2
ACC
G1
K
2
19
20
R18
R21 R17
C7
C10
R16
R20 R15
C6
C9
R19 R14
R13
C5
C8
R12
R11
C3
C11
C4
R1: 10 kΩ
R2, R5: 240 kΩ
R3, R7 to R12, R18: 200 kΩ
R4, R6: 360 kΩ
R13 to R17: 300 kΩ
R19 to R21: 51 Ω
C1: 470 pF
C2 to C8, C11: 10 nF
C9: 22 nF
C10: 33 nF
C2
R10
R9
R8
R7
R6
R5
R4
R3
R2
C1
R1
-HV
AWG22 (VIOLET)
The housing is internally
connected to the GND.
SIGNAL OUTPUT
BNC CONNECTOR
10
P
POWER SUPPLY GND
AWG22 (BLACK)
C3
SOCKET
PIN No.
PMT
SIGNAL OUTPUT
RG-174/U (BLACK)
164.0 ± 0.5
PMT
-H.V
: SHV-R
-HV
SHV CONNECTOR
The housing is internally
connected to the GND.
TACCA0093EB
(Unit: mm)
⁄6 E1198-05
⁄7 E1198-20
PMT
SOCKET
PIN No.
PMT
11
P
DY8
SIGNAL OUTPUT
RG-174/U (BLACK)
7
DY6
6
DY5
5
GND
AWG22 (BLACK)
R10
C3
R9
C2
DY8
8
R8
C1
DY7
7
P
DY4
4
DY3
3
R7
64.0 ± 0.3
DY6
64.0 ± 0.3
R1 to R10 : 330 kΩ
C4 C1 to C3 : 0.01 µF
C4 : 4700 pF
R5
2
DY1
1
R2
13
R1
-HV
AWG22
(VIOLET)
14
450 ± 10
R9
C2
R8
C1
+HV
SHIELD CABLE (RED)
R1 to R11: 330 kΩ
C1 to C3: 0.01 µF
C4, C5: 4700 pF
The housing is internally
connected to the GND.
5
R6
DY4
4
DY3
3
DY2
2
DY1
1
R4
R3
AL
HOUSING
R2
13
G
R1
K
450 ± 10
G
K
C3
R5
R3
HOUSING
(METAL)
R10
6
DY5
56.0 ± 0.3
38.0 ± 0.5
38.0 ± 0.5
R4
DY2
C4
R7
R6
56.0 ± 0.3
SIGNAL OUTPUT
RG-174/U (BLACK)
C5
R11
8
DY7
SOCKET
PIN No.
11
14
The housing is internally
connected to the GND.
TACCA0221EB
TACCA0223EB
⁄8 E1198-26, E1198-27
E1198-26
PMT
SOCKET
PIN No.
E1198-27
SIGNAL GND
PMT
SIGNAL OUTPUT
RG-174/U (BLACK)
12
SOCKET
PIN No.
12
R13
SIGNAL GND
SIGNAL OUTPUT
RG-174/U (BLACK)
C5
C4
R11
R12
64.0 ± 0.3
P
DY8
11
DY7
10
R11
DY6
7
DY5
6
P
C3
R10
C2
R9
C1
R1: 10 kΩ
R2, R3: 680 kΩ
R4 to R11: 330 kΩ
C1 to C3: 10 nF
C4: 4.7 nF
R8
56.0 ± 0.3
R7
DY4
5
38.0 ± 0.5
R6
DY3
DY8
11
DY7
10
DY6
7
DY5
6
DY4
5
DY3
4
3
DY1
1
450 ± 10
C1
POWER SUPPLY GND
R1 to R2 : 680 kΩ
R3 to R11 : 330 kΩ
R12 : 10 kΩ
R13 : 1 MΩ
C1 to C3 : 10 nF
C4, C5 : 4.7 nF
R4
DY2
3
DY1
1
R3
R3
R2
C4
13
R2
K
C2
R8
R5
R4
G
R9
+HV
SHIELD CABLE (RED)
R6
4
DY2
C3
R7
R5
HOUSING
(METAL)
R10
13
G
R1
-HV
SHIELD CABLE (RED)
14
The housing is internally
connected to the GND.
POWER SUPPLY GND
R1
K
14
The housing is internally
connected to the GND.
TACCA0224EB
TACCA0225EB
⁄9 E5859, E5859-01
E5859
PMT
SOCKET
PIN No.
SIGNAL OUTPUT
: BNC-R
7
P
R24
R27 R23
Dy12
8
58.0 ± 0.5
Dy11
6
51.0 ± 0.4
Dy10
12
12.5 9
55.0 ± 0.5
AL HOUSING
Dy9
5
Dy8
Dy7
13
Dy6
Dy5
14
60.0 ± 0.5
SIG
-H.V
SIGNAL
OUTPUT
:BNC-R
-H.V
:SHV-R
4
3
R26 R20
R19
R25 R18
R17
R16
R15
R14
Dy4
Dy3
15
Dy2
Dy1
G
R9
R8
R7
16
K
R24
2
1
17
21
R6
R5
R4
R3
R2
8
Dy11
6
Dy10
12
Dy9
5
Dy8
Dy7
13
Dy6
Dy5
14
C4
R1 : 10 kΩ
R2, R12, R16, R17, R20, R21 : 180 kΩ
R3, R13, R18, R19, R22 to R24 : 226 kΩ
R4, R5, R7, R8 : 121 kΩ
R6, R9 to R11, R14, R15 : 150 kΩ
R25 : 51 kΩ
R26, R27 : 100 Ω
C1 : 470 pF
C2 : 22 nF
C3 : 47 nF
C4 : 0.1 µF
C5 to C7 : 0.22 µF
C3
C2
4
3
R13
R12
R11
Dy2
Dy1
G
R9
R8
R7
16
1
K
21
R1 : 10 kΩ
R2 to R6,R9 to R13 : 220 kΩ
R7,R8 : 154 kΩ
R14 to R21,R23,R24 : 110 kΩ
R22 : 0 Ω
R25 : 51 Ω
R26,R27 : 100 Ω
C1 : 470 pF
C2,C3 : 10 nF
C4 : 22 nF
R14
R10
17
C2
R15
15
2
C3
R17
R16
Dy4
Dy3
C1
-HV
SHV-R
R26 R20
R19
R25 R18
10
SH
C4
R22
R21
R1
The housing is internally
connected to the GND.
R27 R23
Dy12
C5
R11
R10
SIGNAL OUTPUT
BNC CONNECTOR
7
C7
R13
R12
10
SH
C6
SOCKET
PIN No.
P
R22
R21
3-M2
(THREADED HOLES
FOR INSTALLATION
OF MAGNETIC
SHIELD CASE)
E5859-01
PMT
R6
R5
R4
R3
R2
C1
R1
TACCA0176EB
The housing is internally
connected to the GND.
-HV
SHV CONNECTOR
TACCA0178EB
57
¤0 E6316-01
TO AL HOUSING
PMT SOCKET
PIN No.
SIGNAL OUTPUT
: BNC-R
11
P
64.0 ± 0.5
Dy10
10
Dy9
9
Dy8
8
Dy7
7
Dy6
6
SOCKET: E678-14A
51.5 ± 0.5
THREADED HOLES
FOR INSTALLATION
OF MAGNETIC
SHIELD CASE
(e. g; E989-60 FOR R877
E989-61 FOR R878)
AL HOUSING
Dy5
5
Dy4
4
Dy3
3
Dy2
2
Dy1
1
G
R13
C3
R12
R11
C2
R1:10 kΩ
R2 to R13:330 kΩ
C1 to C3:0.01 µF
C4:4700 pF
R9
R8
R7
R6
R5
R4
C4
R3
R2
13
K
C1
R10
14
-H.V
: SHV-R
R1
SIG
-H.V
SIGNAL
OUTPUT
: BNC-R
The housing is internally
connected to the GND.
-H.V
: SHV-R
Note: Magnetic shield case is available
to order separately.
TACCA0089EA
¤1 E7693, E7694
E7693
PMT
SOCKET
: E678-20A
SOCKET
PIN No.
10
P
74.0 ± 0.5
Dy14
11
Dy13
8
Dy12
13
Dy9
6
100.0 ± 0.5
7
Dy10
AL
HOUSING
Dy8
14
Dy7
5
Dy6
15
Dy5
4
Dy4
16
Dy3
3
17
Dy1
2
G1 G2
Dy2
SIGNAL OUTPUT
: BNC-R
R21
R18
C5
R20
R17
C4
R19
R16
C3
R15
C2
R14
C1
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
C6
SIG
-H.V
20
R2
R1
SIGNAL OUTPUT
: BNC-R
8
Dy10
12
Dy9
7
Dy8
13
Dy7
R1 : 10 kΩ
R2, R18 : 240 kΩ
R3 : 360 kΩ
R4 : 390 kΩ
R5 : 120 kΩ
R6 : 180 kΩ
R7 to R14 : 100 kΩ
R15, R16 : 150 kΩ
R17 : 300 kΩ
R19 : 51 Ω
R20, R21 : 100 Ω
C1 : 0.022 µF
C2 : 0.047 µF
C3 : 0.1 µF
C4 : 0.22 µF
C5 : 0.47 µF
C6 : 470 pF
R20
R17
C3
R19
R16
C2
R18
R15
C1
R14
5
Dy6
14
Dy5
4
Dy4
16
Dy3
3
Dy2
17
Dy1
F3
F2
F1
1
2
19
18
K
20
R13
R1 : 10 kΩ
R2, R3, R7 : 750 kΩ
R4, R9 : 200 kΩ
R5 : 91 kΩ
R6 : 510 kΩ
R8 : 300 kΩ
R10 : 100 kΩ
R11 to R17 : 150 kΩ
R18 to R20 : 51 Ω
C1 to C3 : 0.01 µF
C4 : 4700 pF
R12
R11
R10
R9
R8
R7
R6
-HV
: SHV-R
R5
R4
C4
R3
R1
R2
-HV
: SHV-R
The housing is internally
connected to the GND.
The housing is internally
connected to the GND.
-H.V
: SHV-R
SOCKET
PIN No.
P
19
K
SIGNAL
OUTPUT
: BNC-R
12
Dy11
E7694
PMT
TACCA0227EB
¤2 E5770
TACCA0229EB
¤3 E5780
SIGNAL OUT
6
6
SOCKET
RG-174/U
GND or +HV
P
R9
C3
R8
C2
R7
C1
DY8
GUIDE MARK
GND (BLACK)
DY7
Top View
P
GUIDE MARK
DY6
R6
R5
10±0.5
DY3
15 ± 0.5
R2
DY1
7
R1
-HV or GND
R5
DY4
R4
HOUSING
(INSULATOR)
R1 to R8 : 330 kΩ
R9 : 160 kΩ
C1 to C3 : 10 nF
DY3
R3
DY2
R2
R1 to R8 : 330 kΩ
R9 : 160 kΩ
C1 to C3 : 0.01 µF/ 200 V
10.16
C1
DY5
R3
DY2
Side View
C2
R7
R6
R4
K
R8
DY6
DY4
0.45
C3
DY7
17 ± 0.2
DY5
17±0.2
R9
DY8
SIGNAL OUTPUT
: RG-174/U
DY1
K
R1
-HV (VIOLET)
-HV
2.54
2.54
5.08
GND
450
SIGNAL OUT
-HV
: AWG22 (VIOLET)
GND
: AWG22 (BLACK)
For +HV, it will be necessary to use a
coupling capacitor between the output
and the customer's signal processing
circuit.
Bottom View
TACCA0057EF
58
TACCA0060EE
(Unit: mm)
¤5 E7083
PMT
30.0 ± 0.5
SOCKET
PIN No.
SIGNAL GND
SIGNAL OUTPUT
RG-174/U (BLACK)
30
PIN No.1
DY10
15.0 ± 0.5
HOUSING
(INSULATOR)
R14
R11
C3
R13
R10
C2
23
DY8
22
R12
R9
C1
P4
15
P3
R1 to R3 : 330 kΩ
R4 to R11 : 220 kΩ
R12 to R14 : 51 Ω
R15 : 1 MΩ
C1 to C3 : 10 nF
R7
20
DY5
19
DY4
7
450 ± 10
R6
DY10
24
DY9
23
DY8
DY2
5
DY1
4
C3
R13
R10
C2
R12
R9
C1
22
DY7
21
DY6
20
DY5
19
P3
DY4
7
-HV
RG-174/U (RED)
DY3
6
DY2
5
DY1
4
R1 to R3 : 330 kΩ
R4 to R11 : 220 kΩ
R12 to R14 : 51 Ω
R15 : 1 MΩ
C1 to C3 : 10 nF
R6
R5
P2
POTTING
COMPUND
R3
R4
R3
R2
K
R11
R7
R4
6
R14
R8
R5
DY3
P1
P4 P3 P2 P1
450 ± 10
21
DY6
SIGNAL OUTPUT
P2 : 0.8D-QEV (GRAY)
31
HOUSING
(INSULATOR)
R8
DY7
SIGNAL GND
27
11
24
DY9
SOCKET
PIN No.
PMT
30.0 ± 0.5
15.0 ± 0.5
30.0 ± 0.5
P
PIN No.1
30.0 ± 0.5
¤4 E5996
R2
R15
GUIDE MARK
R1
-HV
1
K
P4
P1
R15
: RG-174U (RED)
POWER SUPPLY GND
R1
-HV
: RG-174U (RED)
1
P1 to P4 :SIGNAL OUTPUT
COAXIAL CABLE (GRAY)
POWER SUPPLY GND
TACCA0234EC
¤6 E6736
¤7 E7514
P9
P1
P2
-HV
RG-174/U (RED)
P4
P7 P5
P6
P8
P10
K
P15
P16
P14
P1 to P16 : SIGNAL OUTPUT
COAXIAL CABLE (GRAY)
26
Dy9
10
Dy8
24
Dy7
8
Dy6
P12
GUIDE MARKE
Dy10
25.4 ± 0.5
PX6
P8
•
•
•
•
•
•
C3
R13 R10
C2
R12 R9
C1
R8
PX5
PY5
SIGANL OUTPUT
: 0.8D-QEV (GRAY)
P1
R14 R11
PY6
25.4 ± 0.5
•
•
•
•
•
•
•
P16
P15
P14
P13
P12
P11
P10
P9
P8
P7
P6
P5
P4
P3
P2
P1
POM
HOUSING
PIN No. 1
P16
PX4
15.0 ± 0.5
30.0 ± 0.5
Pin No.1
450 ± 10 15.0 ± 0.5
P11
SIGNAL GND
28
29
27
3
23
4
22
5
21
6
20
7
19
11
13
12
5 10
P13
PMT
SOCKET
PIN No.
PMT
R1 to R11 : 220 kΩ
R12 to R14 : 51 Ω
R15 : 1 MΩ
C1 to C3 : 10 nF
R7
2
POM
HOUSING
PY3
PX2
PY2
PX1
R6
Dy5
18
Dy4
31
PY4
PX3
450 ± 10
30.0 ± 0.5
P3
TACCA0162ED
SOCKET
PIN No.
PX6
24
PY6
15
PX5
23
PY5
14
PX4
22
PY4
12
PX3
20
PY3
11
PX2
19
PY2
10
PX1
R5
Dy3
15
Dy2
32
Dy1
16
DY11
8
DY10
27
DY9
7
R3
R2
R15 R1
17
-HV
RG-174/U (RED)
POWER SUPPLY GND
R18 R14
C3
R17 R13
C2
R16 R12
C1
R11
PX2
PX1
TACCA0158ED
SIGNAL OUTPUT
: 0.8D-QEV (GRAY)
PY1
13
PY1
R4
SIGNAL GND
16
-H.V
: RG-174/U (RED)
POTTING
COMPOUND
GUIDE MARK
DY8
28
DY7
6
R10
PY1 PX4
PX5
PX3
PX6
R9
PY2
PY3
DY6
29
DY5
5
DY4
30
R8
R1, R14: 110 kΩ
R2: 330 kΩ
R3 to R13: 220 kΩ
R15: 1 MΩ
R16 to R18: 51 Ω
C1 to C3: 10 nF
R7
PY4
PY5
PY6
R6
DY3
4
DY2
31
DY1
3
R5
R4
R3
G
K
R2
1
R15
32
R1
-H.V
: RG-174/U (RED)
POWER
SUPPLY GND
TACCA0236EB
59
Dimensional Outline
For E678 Series Sockets
E678-11N
E678-12A
47
4.3
40
17
10.5
3
9.5
11
2- 3.2
8
5
9.5
15
3
34
TACCA0043EA
E678-12L
TACCA0009EB
E678-12M
E678-13A
35
28.6
12.5
2- 3.2
13
24
2.54
2-R4
18
360
13
9
(23.6)
6.7
6.0
2- 2.2
1.83
18
10.16
13
3
10
4.2
2.8
3.4
(8)
3.2
2
7
10.5
9.5
3.3 3.7
2
0.53
13
11
18
TACCA0047EA
E678-13E
TACCA0164EB
E678-14C
TACCA0005EA
E678-14V
12.4
30
19.8
19.1
44
35
11.6
11
5.5
2- 3.5
62
7
25
TACCA0013EB
60
30
2
9
17 11
7
56
2.5
3
10.5
26
TACCA0004EA
TACCA0200EA
(Unit: mm)
E678-15B
E678-17A
E678-19E
50
4
21.9
2
22.8
6.5
12.0
5
2
11.5
12
16.3
0.1
5
14.0
5
45
45
40
4
40
24.0
60
50
18.0
60
40
40
TACCA0201EA
TACCA0046EB
E678-19F
TACCA0202EA
E678-20A
60
45
40
4
20
50
58
5
13
6
52.5
2
21
10
12
12
40
52
6.5
56
TACCA0203EA
E678-21C
TACCA0003EA
E678-32B
51
22.86
19
4.45 2.92
12.7
20.32
R5
22.86
56.8
2.54
20.32
0.51
1.57
13
5
12.7
6.5
4
MATERIAL: Glass Epoxy
TACCA0066EC
TACCA0094ED
61
Index by Type No.
Type Number
Product
R329-02 ...................
R331 ........................
R331-05 ...................
R580 ........................
R580-17 ...................
R647-01 ...................
E678 SERIES ..........
R750 ........................
R760 ........................
R762 ........................
E849-68 ...................
E849-90 ...................
R877 ........................
R877-01 ...................
R960 ........................
E974-17 ...................
E974-19 ...................
E974-22 ...................
R980 ........................
R1166 ......................
E1198-05 .................
E1198-07 .................
E1198-20 .................
E1198-26 .................
E1198-27 .................
R1250 ......................
R1288A-06 ...............
R1306 ......................
R1306-15 .................
R1307 ......................
R1307-07 .................
R1450 ......................
R1512 ......................
R1538 ......................
R1538-01 .................
R1548-07 .................
R1584 ......................
R1635 ......................
E1761-21 .................
E1761-22 .................
R1828-01 .................
R1840 ......................
R1924A ....................
R1924A-01 ...............
H1949-50 .................
H1949-51 .................
E2037-02 .................
R2059 ......................
R2076 ......................
R2083 ......................
R2102 ......................
R2154-02 .................
51mm (2") dia. PMT ......................... 20
51mm (2") dia. PMT ......................... 21
51mm (2") dia. PMT ......................... 20
38mm (1-1/2") dia. PMT ................... 18
38mm (1-1/2") dia. PMT ................... 18
13mm (1/2") dia. PMT ...................... 18
Socket ........................................ 60, 61
19mm (3/4") dia. PMT ...................... 19
13mm (1/2") dia. PMT ...................... 19
19mm (3/4") dia. PMT ...................... 19
Socket Assembly .............................. 52
Socket Assembly .............................. 52
127mm (5") dia. PMT ....................... 20
127mm (5") dia. PMT ....................... 21
13mm (1/2") dia. PMT ...................... 19
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
38mm (1-1/2") dia. PMT ................... 18
19mm (3/4") dia. PMT ...................... 18
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
127mm (5") dia. PMT ....................... 20
25mm (1") dia. PMT ......................... 18
51mm (2") dia. PMT ......................... 20
51mm (2") dia. PMT ......................... 21
76mm (3") dia. PMT ......................... 20
76mm (3") dia. PMT ......................... 21
19mm (3/4") dia. PMT ...................... 18
127mm (5") dia. PMT ....................... 20
60mm (2.5") Hexagon PMT .............. 22
60mm (2.5") Hexagon PMT .............. 23
25mm (1" Dual) Square PMT ........... 22
127mm (5") dia. PMT ....................... 20
10mm (3/8") dia. PMT ...................... 18
Socket Assembly .............................. 52
Socket Assembly .............................. 52
51mm (2") dia. PMT ......................... 20
51mm (2") dia. PMT ......................... 20
25mm (1") dia. PMT ......................... 18
25mm (1") dia. PMT ......................... 19
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 43
Socket Assembly ............................. 52
51mm (2") dia. PMT ......................... 21
19mm (3/4") dia. PMT ...................... 19
51mm (2") dia. PMT ......................... 20
13mm (1/2") Square PMT ................ 22
51mm (2") dia. PMT ......................... 20
62
Page
Type Number
Product
Page
E2183-500 ...............
E2183-501 ...............
R2238 ......................
R2238-01 .................
R2248 ......................
E2253-05 .................
R2256-02 .................
H2431-50 .................
R2486-02 .................
R2496 ......................
E2624-04 .................
E2624-14 .................
E2924-11 .................
E2924-500 ...............
E2979-500 ...............
R3149 ......................
H3164-10 .................
H3164-11 .................
H3165-10 .................
H3165-11 .................
H3177-50 .................
H3177-51 .................
H3178-51 .................
H3178-61 .................
R3292-02 .................
R3377 ......................
H3378-50 .................
R3478 ......................
R3479 ......................
R3600-02 .................
R3600-06 .................
H3695-10 .................
H3695-11 .................
R3878 ......................
R3886 ......................
R3991-04 .................
R4004 ......................
H4022-50 .................
H4022-51 .................
R4124 ......................
R4125 ......................
R4141 ......................
R4143 ......................
R4177-04 .................
R4177-06 .................
R4607-06 .................
R4885 ......................
R4998 ......................
R5133-02 .................
R5320 ......................
R5325 ......................
R5330 ......................
Socket Assembly .............................. 52
Socket Assembly .............................. 52
76mm (3") dia. PMT ......................... 20
Hybrid Assembly .............................. 43
10mm (3/8") Square PMT ................. 22
Socket Assembly .............................. 52
51mm (2") dia. PMT ......................... 21
Hybrid Assembly .............................. 43
Position Sensitive PMT .................... 38
10mm (3/8") dia. PMT ...................... 18
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
51mm (2") dia. PMT ......................... 21
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Position Sensitive PMT .................... 38
51mm (2") dia. PMT ......................... 21
Hybrid Assembly .............................. 43
19mm (3/4") dia. PMT ...................... 18
19mm (3/4") dia. PMT ...................... 19
508mm (20") dia. PMT ..................... 20
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
10mm (3/8") dia. PMT ...................... 19
38mm (1-1/2") dia. PMT ................... 18
19mm (3/4") dia. PMT ...................... 18
51mm (2") dia. PMT ......................... 21
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 43
13mm (1/2") dia. PMT ...................... 18
19mm (3/4") dia. PMT ...................... 18
13mm (1/2") dia. PMT ...................... 19
76mm (3") dia. PMT ......................... 20
13mm (1/2") dia. PMT ...................... 19
13mm (1/2") dia. PMT ...................... 18
51mm (2") dia. PMT ......................... 20
76mm (3") dia. PMT ......................... 21
25mm (1") dia. PMT ......................... 18
51mm (2") dia. PMT ......................... 21
25mm (1") dia. PMT ......................... 19
19mm (3/4") dia. PMT ...................... 18
38mm (1-1/2") dia. PMT ................... 18
Type Number
Product
Page
R5364 ......................
R5380 ......................
R5505-70 .................
R5505-70 .................
R5611 ......................
R5611-01 .................
E5770 ......................
E5780 ......................
E5859 ......................
E5859-01 .................
E5859-02 .................
E5859-03 .................
R5900U-00-L16 .......
R5912 ......................
R5912-02 .................
R5924-70 .................
R5924-70 .................
E5996 ......................
R6091 ......................
E6133-03 .................
E6133-04 .................
H6152-70 .................
R6231 ......................
R6231-01 .................
R6232 ......................
R6232-01 .................
R6233 ......................
R6233-01 .................
R6234 ......................
R6234-01 .................
R6235 ......................
R6235-01 .................
R6236 ......................
R6236-01 .................
R6237 ......................
R6237-01 .................
E6316-01 .................
H6410 ......................
R6427 ......................
R6504-70 .................
R6504-70 .................
H6520 ......................
H6520-01 .................
H6521 ......................
H6522 ......................
H6524 ......................
H6524-01 .................
H6525 ......................
H6526 ......................
H6527 ......................
H6528 ......................
H6533 ......................
19mm (3/4") dia. PMT ...................... 19
25mm (1") dia. PMT ......................... 18
25mm (1") dia. PMT ......................... 18
Fine Mesh PMT ................................ 22
19mm (3/4") dia. PMT ...................... 19
19mm (3/4") dia. PMT ...................... 18
Socket Assembly .............................. 53
Socket Assembly .............................. 53
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Metal Package PMT ......................... 22
204mm (8") dia. PMT ....................... 20
204mm (8") dia. PMT ....................... 20
51mm (2") dia. PMT ......................... 20
Fine Mesh PMT ................................ 22
Socket Assembly .............................. 53
76mm (3") dia. PMT ......................... 20
Socket Assembly .............................. 52
Socket Assembly .............................. 52
Hybrid Assembly .............................. 42
51mm (2") dia. PMT ......................... 20
51mm (2") dia. PMT ......................... 21
60mm (2.5") dia. PMT ...................... 20
60mm (2.5") dia. PMT ...................... 21
76mm (3") dia. PMT ......................... 20
76mm (3") dia. PMT ......................... 21
60mm (2.5") Hexagon PMT .............. 22
60mm (2.5") Hexagon PMT .............. 23
76mm (3") Hexagon PMT ................. 22
76mm (3") Hexagon PMT ................. 23
60mm Square PMT .......................... 22
60mm Square PMT .......................... 23
76mm (3") Square PMT .................... 22
76mm (3") Square PMT .................... 23
Socket Assembly .............................. 52
Hybrid Assembly .............................. 43
28mm (1-1/8") dia. PMT ................... 18
64mm (2.5") dia. PMT ...................... 20
Fine Mesh PMT ................................ 22
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 42
Type Number
Product
H6559 ......................
E6572 ......................
R6594 ......................
H6610 ......................
H6612 ......................
H6612-01 .................
H6613 ......................
H6613-01 .................
H6614-70 .................
E6736 ......................
R7056 ......................
R7081 ......................
R7081-20 .................
E7083 ......................
R7111 ......................
H7195 ......................
R7250 ......................
H7260 ......................
R7354 ......................
R7373A-01 ...............
R7375-01 .................
R7400U ....................
R7400U-03 ..............
R7400U-06 ..............
H7415 ......................
H7415-01 .................
H7416 ......................
E7514 ......................
R7525 ......................
H7546B ....................
R7600U ...................
R7600U-00-M4 ........
R7600U-03 ..............
E7693 ......................
E7694 ......................
E7694-01..................
R7723 ......................
R7724 ......................
R7725 ......................
R7761-70 .................
R7761-70 .................
R7899 ......................
R7899-01 .................
R8055 ......................
H8135 ......................
R8143 ......................
H8318-70 .................
H8409-70 .................
H8500 ......................
R8520U-00-C12 ......
H8643 ......................
H8711 ......................
Hybrid Assembly .............................. 43
Socket Assembly .............................. 53
127mm (5") dia. PMT ....................... 20
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 43
Socket Assembly .............................. 53
28mm (1-1/8") dia. PMT ................... 19
254mm (10") dia. PMT ..................... 20
254mm (10") dia. PMT ..................... 20
Socket Assembly .............................. 53
28mm (1-1/8") dia. PMT ................... 18
Hybrid Assembly .............................. 43
508mm (20") dia. PMT ..................... 20
Hybrid Assembly ........................ 22, 43
2π Shape PMT ................................. 22
2π Shape PMT ................................. 22
2π Shape PMT ................................. 22
Metal Package PMT ......................... 22
Metal Package PMT ......................... 23
Metal Package PMT ......................... 22
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Hybrid Assembly .............................. 42
Socket Assembly .............................. 53
28mm (1-1/8") dia. PMT ................... 18
Hybrid Assembly ........................ 22, 43
Metal Package PMT ......................... 22
Metal Package PMT ......................... 22
Metal Package PMT ......................... 23
Socket Assembly .............................. 52
Socket Assembly ............................. 52
Socket Assembly ............................. 52
51mm (2") dia. PMT ......................... 20
51mm (2") dia. PMT ......................... 21
51mm (2") dia. PMT ......................... 21
38mm (1-1/2") dia. PMT ................... 18
Fine Mesh PMT ................................ 22
25mm (1") dia. PMT ......................... 19
25mm (1") dia. PMT ......................... 18
332mm (13") dia. PMT ..................... 20
Hybrid Assembly .............................. 42
2π Shape PMT ................................. 22
Hybrid Assembly .............................. 43
Hybrid Assembly .............................. 42
Hybrid Assembly ........................ 22, 43
Position Sensitive PMT .................... 38
Hybrid Assembly .............................. 42
Hybrid Assembly ........................ 22, 43
Page
63
CAUTIONS AND WARRANTY
WARNING
HIGH
VOLTAGE
Take sufficient care to avoid an electric shock hazard
ate interlocks to protect the operator and service personnel.
A high voltage used in photomultiplier tube operaThe metal housing of the Metal Package PMT R7400 series,
tion may present a shock hazard. Photomultiplier
R5900 series and R7600 series are connected to the phototubes should be installed and handled only by
cathode (potential) so that it becomes a high voltage potential
qualified personnel that have been instructed in
when the product is operated at a negative high voltage
handling of high voltages. Designs of equipment
(anode grounded).
utilizing these devices should incorporate appropri-
PRECAUTIONS FOR USE
● Handle tubes with extreme care
Photomultiplier tubes have evacuated glass envelopes. Allowing the glass to be scratched or to be subjected to shock
can cause cracks. Extreme care should be taken in handling,
especially for tubes with graded sealing of synthetic silica.
● Keep faceplate and base clean
do not touch the faceplate and base with bare hands. Dirt
and fingerprints on the faceplate cause loss of transmittance
and dirt the base may cause ohmic leakage. Should they become soiled, wipe it clean using alcohol.
● Do not expose to strong light
Direct sunlight and other strong illumination may cause damage the Photocathode. They must not be allowed to strike the
photocathode, even when the tube is not operated.
● Handling of tubes with a glass base
A glass base (also called button stem) is less rugged than a
plastic base, so care should be taken in handling this type of
tube. For example, when fabricating the voltage-divider circuit, solder the divider resistors to socket lugs while the tube
is inserted in the socket.
● Cooling of tubes
When cooling a photomultiplier tube, the photocathode section is usually cooled. However, if you suppose that the base
is also cooled down to -30 °C or below, please consult our
sales office in advance.
● Helium permeation through silica bulb
Helium will permeate through the silica bulb, leading to an increase in noise. Avoid operating or storing tubes in an environment where helium is present.
Data and specifications listed in this catalog are subject
to change due to product improvement and other factors.
before specifying any of the types in your production
equipment, please consult our sales office.
WARRANTY
All Hamamatsu photomultiplier tubes and related products
are warranted to the original purchaser for a period of 12
months following the date of shipment. The warranty is limited to repair or replacement of any defective material due to
defects in workmanship or materials used in manufacture.
A: Any claim for damage of shipment must be made directly
to the delivering carrier within five days.
B: Customers must inspect and test all detectors within 30
days after shipment. Failure to accomplish said incoming
inspection shall limit all claims to 75 % of invoice value.
C: No credit will be issued for broken detectors unless in the
opinion of Hamamatsu the damage is due to a bulb crack
or a crack in a graded seal traceable to a manufacturing
defect.
64
D: No credit will be issued for any detector which in the judgment of Hamamatsu has been damaged, abused, modified
or whose serial number or type number have been obliterated or defaced.
E: No detectors will be accepted for return unless permission
has been obtained from Hamamatsu in writing, the shipment has been returned prepaid and insured, the detectors are packed in their original box and accompanied by
the original data sheet furnished to the customer with the
tube, and a full written explanation of the reason for rejection of each detector.
F: When products are used at a condition which exceeds the
specified maximum ratings or which could hardly be anticipated, Hamamatsu will not be the guarantor of the products.
Typical Photocathode Spectral Response
and Emission Spectrum of Scintillators
TPMHB0342EC
100
C
F
B
10
E
A
PWO
LSO
Nal (Tl)
PLASTIC YAP
1
CsI (Tl)
BGO
100
80
60
BaF2
40
20
0.1
0
100
200
300
400
500
600
10
700
RELATIVE INTENSITY (%)
QUANTUM EFFICIENCY (%)
D
WAVELENGTH (nm)
A: Borosilicate Glass
B: UV Glass
C: Synthetic Silica
D: Bialkali Photocathode
E: High Temp. Bialkali Photocathode
F: Extended Green bialkali photocathode
65
HAMAMATSU PHOTONICS K.K., Electron Tube Division
314-5, Shimokanzo, Toyooka-village, Iwata-gun, Shizuoka-ken, 438-0193, Japan
Telephone: (81)539/62-5248, Fax: (81)539/62-2205
http://www.hamamatsu.com
Main Products
Sales Offices
Electron Tubes
Photomultiplier Tubes
Light Sources
Microfocus X-ray Sources
Image Intensifiers
X-ray Image Intensifiers
Microchannel Plates
Fiber Optic Plates
ASIA:
HAMAMATSU PHOTONICS K.K.
325-6, Sunayama-cho,
Hamamatsu City, 430-8587, Japan
Telephone: (81)53-452-2141, Fax: (81)53-456-7889
Opto-semiconductors
Si Photodiodes
Photo IC
PSD
InGaAs PIN photodiodes
Compound semiconductor photosensors
Image sensors
Light emitting diodes
Application products and modules
Optical communication devices
High energy particle/X-ray detectors
Imaging and Processing Systems
Video Cameras for Measurement
Image Processing Systems
Streak Cameras
Optical Measurement Systems
Imaging and Analysis Systems
U.S.A.:
HAMAMATSU CORPORATION
Main Office
360 Foothill Road, P.O. BOX 6910,
Bridgewater, N.J. 08807-0910, U.S.A.
Telephone: (1)908-231-0960, Fax: (1)908-231-1218
E-mail: usa@hamamatsu.com
Western U.S.A. Office:
Suite 110, 2875 Moorpark Avenue
San Jose, CA 95128, U.S.A.
Telephone: (1)408-261-2022, Fax: (1)408-261-2522
E-mail: usa@hamamatsu.com
United Kingdom:
HAMAMATSU PHOTONICS UK LIMITED
Main Office
2 Howard Court, 10 Tewin Road Welwyn Garden City
Hertfordshire AL7 1BW, United Kingdom
Telephone: 44-(0)1707-294888, Fax: 44-(0)1707-325777
E-mail: info@hamamatsu.co.uk
South Africa Office:
PO Box 1112, Buccleuch 2066,
Johannesburg, South Africa
Telephone/Fax: (27)11-802-5505
France, Portugal, Belgiun, Switzerland, Spain:
HAMAMATSU PHOTONICS FRANCE S.A.R.L.
8, Rue du Saule Trapu, Parc du Moulin de Massy,
91882 Massy Cedex, France
Telephone: (33)1 69 53 71 00
Fax: (33)1 69 53 71 10
E-mail: infos@hamamatsu.fr
Swiss Office:
Richtersmattweg 6a
CH-3054 Schüpfen, Switzerland
Telephone: (41)31/879 70 70,
Fax: (41)31/879 18 74
E-mail: swiss@hamamatsu.ch
SEPT. 2004 REVISED
Information in this catalog is
believed to be reliable. However,
no responsibility is assumed for
possible inaccuracies or omission.
Specifications are subject to
change without notice. No patent
rights are granted to any of the
circuits described herein.
© 2004 Hamamatsu Photonics K.K.
Germany, Denmark, Netherland, Poland:
HAMAMATSU PHOTONICS DEUTSCHLAND GmbH
Arzbergerstr. 10,
D-82211 Herrsching am Ammersee, Germany
Telephone: (49)8152-375-0, Fax: (49)8152-2658
E-mail: info@hamamatsu.de
Danish Office:
Skyttehusgade 36, 1tv. DK-7100 Vejle, Denmark
Telephone: (45)4346/6333, Fax: (45)4346/6350
E-mail: lkoldbaek@hamamatsu.de
Netherlands Office:
PO Box 50.075, 1305 AB Almere The Netherland
Telephone: (31)36-5382123, Fax: (31)36-5382124
E-mail: info@hamamatsu.nl
Poland Office:
02-525 Warsaw, 8 St. A. Boboli Str., Poland
Telephone: (48)22-660-8340, Fax: (48)22-660-8352
E-mail: info@hamamatsu.de
North Europe and CIS:
HAMAMATSU PHOTONICS NORDEN AB
Smidesvägen 12
SE-171 41 Solna, Sweden
Telephone: (46)8-509-031-00, Fax: (46)8-509-031-01
E-mail: info@hamamatsu.se
Russian Office:
Riverside Towers
Kosmodamianskaya nab. 52/1, 14th floor
RU-113054 Moscow, Russia
Telephone/Fax: (7)095 411 51 54
E-mail: info@hamamatsu.ru
Italy:
HAMAMATSU PHOTONICS ITALIA S.R.L.
Strada della Moia, 1/E
20020 Arese, (Milano), Italy
Telephone: (39)02-935 81 733, Fax: (39)02-935 81 741
E-mail: info@hamamatsu.it
Rome Office:
Viale Cesare Pavese, 435, 00144 Roma, Italy
Telephone: (39)06-50513454, Fax: (39)06-50513460
E-mail: inforoma@hamamatsu.it
Belgian Office:
7, Rue du Bosquet
B-1348 Louvain-La-Neuve, Belgium
Telephone: (32)10 45 63 34
Fax: (32)10 45 63 67
E-mail: epirson@hamamatsu.com
Spanish Office:
Centro de Empresas de Nuevas Tecnologies
Parque Tecnologico del Valles
08290 CERDANYOLA, (Barcelona) Spain
Telephone: (34)93 582 44 30
Fax: (34)93 582 44 31
E-mail: spain@hamamatsu.com
Quality, technology, and service are part of every product.
TPMO0007E01
SEPT. 2004 IP
Printed in Japan (6,000)