CORRIGENDUM – I dt 03 Jul 2013
CENTRE FOR AIRBORNE SYSTEMS
MINISTRY OF DEFENCE (DRDO)
BANGALORE - 560037
REFER OTE No. : CABS/14ATT021/LP
(For Development of Automated Test Equipment (ATE) for AEW & C Published on
16th Jun 2013 (BNG Edn) (DAVP:10301/11/0235/1314))
1.
The above Open Tender Enquiry was uploaded on DRDO website (www.drdo.org) on
30 May 2013 and Published in The Times of India on 16 Jun 2013. The Due Time & Date for
submitting the Tenders was 1000 Hrs on 10-Jul-2013 and Tender Opening Time & Date was
1030 Hrs 10-Jul-2013.
2.
A Pre Bid meeting was held on 24-Jun-2013. The Clarifications in respect of various
queries raised by the Vendors during the Pre Bid meeting are attached as Appendix A.
3.
2.
Generic Specifications for ATE Instruments as amended are attached as Appendix B.
The Due date & Time for submitting the Tenders has been extended upto 1000 Hrs
on 31 Jul 2013. Tender Opening Time & Date is 1030 Hrs 31 Jul 2013.
3.
All other Terms & conditions remain unchanged.
Director, CABS,
Bangalore.
directorcabs@gmail.com
Tender Enquiry No: CABS/14ATT021/LP
File/Ref No : CABS/LPD/20130004/Lgs
Appendix A
The Clarifications in respect of various queries raised by the Vendors during the Pre Bid
meeting and e-mails are given below:
Sl No
1.
Queries Raised by the Vendor
Broad Specification for all the 
instruments
cards
&
test
equipments mentioned in the RFQ
to be brought out.
CABS Response
Enclosed as Corrigendum Appendix B
2.
All LRU’s will have in built test 
software, will ATE make use of
the same.

3.
Whether ATE will be used for
certification of LRUs purpose.

4.
What is the type and length of the
cable.

The ATE software should have capability to
invoke in built test of LRU and get the result
and make use of the same.
In addition each LRU’s will require specific
measurement and analysis by ATE. The ATE
will need to have both and final decision on
LRU serviceability, will be based on the
combination.
The ATE will be used to evaluate the
serviceability of LRU and to conclude
whether the LRU is usable either in full or
degraded capability. Also may predict the
specific functionality which may degrade or
get affected.
The LRU’s will be located closed to ATE.
Hence the cable length of 2-3 meters may be
assumed.
Max frequency of measurement 18GHz
Power: Appropriate average max power 45A
@28V DC.
Cable: LAN, CAT6, 1553 STP. Discrete
length 50 mtr for AAAU ATE and upto 5 mtr
max for other ATE.
The capacity of RF switch should at least be 8
Full crossbar switch is not necessary
Frequency range :- 0.1 - 18 GHz
The switch may be used in the test scenarios
where, Multiple RF measurement instruments
have to be connected to the same LRU in
different configurations.
IL may be around 1-2dB
The RF switch matrix must have a capacity of
8. (For eg., design may be 24x8 -> 8x8 ->
8x24).which can be configured using 8X8
switches. Hence the vendor can configure
8X8 switches 03 nos in such away to enable
expansion accordingly.
This switch matrix Switch type may be



5.
What is the capacity of RF switch
matrix .







‐1‐ 6.
7.
8.
9.
10.
11.
12.
13.
In the RF switch matrix, is it third
harmonic (Ex 54 GHZ for freq
18GHz) to be considered or not
For quoting the tender whether all
LRUs to be considered as equally
complicated to arrive Go-NO
condition.
If the configuration of equipments,
components or instruments the
specified in RFP does not meet the
specification who is responsible.
Whether strictly PXI based
modular standard to be followed
or not
RF switch matrix applications
significance, it needs to be
elaborated page no 12
Software development for 39 type
of LRUs
How many LRUs to be tested at a
time
Test cases for each LRUs to be
defined, finalized.




Yes, same complexity may be considered for
software implementation

If the requirement is not met due to equipment
limitations
or
lack
of
some
equipments/components/instruments, CABS
is responsible.
Not
Necessary. PXI/PCI/VXI
similar
standards may also be considered
Vendor shall be responsible to integrate and
make them operate seamlessly. Modularity to
be maintained specifically in terms of
enclosure based configuration.
It is clarified that in page no 12 mentioned
under RF switch matrix in the RFQ.
Based on the vendor design RF switch matrix
may be incorporated inside or outside the
rack
Software development of LRU’s is not in
scope of work of this contract.
Only one LRUs is to be tested at a time








14.
15.
Is it the vendor has to provide the

break down details for software

development
As mentioned in the RFQ, it is

required to capture the details from
the work centers

16.
Design & configuration is with the
vendor or CABS
electromechanical/solid state switch. It is
expected vendor to quote for both.
Enclosed as Corrigendum Appendix -B
Not needed to be considered
Enclosed as Corrigendum Appendix B


Since the LRUs are classified in nature,
Hence test cases, algorithms for software
development and Acceptance criteria will be
shared with finalized vendor only.
As mentioned in RFP these will be finalized
for each LRU a part of requirement capture.
Yes,
Detailed break up to be given
CABS is a nodal agency for all the various
work centers, hence any requirement details
will be obtained from the work centers by
CABS.
CABS will felicitate these requirement
capture.
The specification requirement is CABS
responsibility and implementation of the ATE
configuration
is
vendor
+
CABS
responsibility.
Seamless working of equipments, H/W,
instruments in integrated mode will be
vendor’s responsibility.
‐2‐ 17.
18.
19.
Whether LRUS are fixed for
testing in that specific ATE only
No of I/O to be specified in the
RFQ

Why dedicated controller required
for each ATE




20.
21.
22.
Whether DO-178 B standards to
be followed for all the test cases
Whether software modules along
with OS need to be qualified.



Clarification on the Payment terms 
is requested



23.
24.
Any part of the testing software
available with the CABS/ work
centre and the same was requested
for sharing.
What is the level of testing depth?
(diagnostics depth)



25.
Vendor requested to elaborate the
HMI requirement functionality in
terms of single step procedure

26.
Does a special calibration kit
needed.


It will depend upon LRUSs some may have to
be tested with multiple ATEs
Vendor can assume 80 to 100% of the all I/Os
of instrumental boards (as in the RFQ) will be
used. Hence cables, connectors should be
catered for the same.
The modular chassis with instruments should
also be usable in standalone.
Hence each chassis should have its own
controller.
In addition a common controller in terms of
Desktop with display, printer connected
through LAN.
No, DO178B is not a requirement.
OS and cots Software need not be qualified.
ATE application S/W will be IV&V ed and
qualified by CABS appointed team.
15 % of the contract value as an advance.
50 % of the hardware cost on the delivery of
the hardware.
Remaining amount less 10% of the contract
value on the installation and acceptance on
both the locations.
Final 10% of contract value to be released on
either furnishing for equal amount to be valid
for throughout warranty period plus two
months or at the end of completion of
warranty period which ever is earliest.
As on date no automated test software is
available.
Hence this will be ab-intio development.
CABS will define the diagnostic depth
through test procedures which will be shared
with finalized vendor as part of requirement
capture.
The ATE software shall have capability for
automated/manned/semi automated testing i.e
capabilities such as single stepping etc will be
required. All the HMI will be defined as part
of requirement capture.
Standard calibration to be followed as per the
OEM advice and up to the warranty period the
calibration of the equipment to be taken care
within the India.
All standard calibration kit as required by
OEM for the basic equipment calibration
before measurement to be catered for this
particularly for network analyzer etc, where
calibration is essential.
‐3‐ 
27.
(BIT) Health status test for ATE

28.
Power requirement of the mobile
ATE

How many persons to sit inside



29.
Query on the LRU weight

30.
IV & V for the developed software 
31.
Bug fixing and fine tuning of the
software packages
As regard equipment calibration, the
equipment shall be calibrated in India and for
OEM defined schedules. Down time
acceptable for calibration/time to repair shall
be 48 hours.
The health status ( working or serviceable) of
all the equipments in the rack will be
displayed to the user through the GUI based
on the available POST and internal diagnostic
software in the equipment and other status
generic available in equipments.
220 V AC, provision from external source/
DG, maximum two persons sit at a time (in
addition to driver).
The RF cable length is 50 meters appropriate.
The power cable length 50 meters appropriate.
Discrete cable length 50 meters (insulated,
shielded, twisted pair, 22/24 AWG)
Maximum weight of the LRU is 35 Kg and
most of the LRUS around 20 KG
CABS IV& V team will carry out verification
and validation based on the software
documents provided by the vendor.
 This will be on No cost basis.
 Any software bug fixing and fine tuning of
the software package during the user warranty
shall be carried out at No cost basis within the
warranty period. In case of any major
hardware change required after the
installation & commissioning the same shall
be proposed as additional requirement.
 CABS shall reserve the right to either procure
the equipments on its own or through vendor
suitably.
Upgradation

32.
Queried the requirement of vector
signal trans receiver or vector
signal generator and analyser
separately (VSG+ VSA)

33.
Miscellaneous components for
ATE

34.
Page no 36 of RFQ, the qty of 20
nos of RF switch mentioned for


Vendors may assume 12 man month
equivalent over 03 year warranty period for
up gradation for estimation purposes.
It is choice of the vendor to propose the
Generator and Analyser separately or
combination
of
both.
The
transmitter/receiver/transceiver shall have
vector
signal
generation/measurement
capability.
Standard of the shelf components, Refer to
Corrigendum Appendix B.
It is for one ATE set.
One ATE set consists of one mobile ATE, one
each of microwave/Communication ATE.
‐4‐ one ATE or total

All listed components are for one ATE set.
35.
Specify the shell part no of the
deutch connector

Enclosed as Corrigendum Appendix B.
36.
In the appendix B in the RFQ , DC
modules for the above required to
be rechecked

Requirement of DC power analyser . N6705B
and associated DC modules stands deleted.
37.
Whether test equipments will
accommodate two racks or three
racks

Maximum of three racks and the rack
dimension is mentioned in the RFQ
38.
Complete Maintenance activity of
the ATE

39.
Whether pulse network analyser is 

required for the AAAU ATE
40.
The requirement of OEM
certificate for the certain test
equipments
It is fully vendor responsibility and the down
time of maximum of 48 Hrs. In the mean time
if a vendor can propose the achievable lesser
down time , which will be considered during
the TEC.
No
However for VSG/VSA should be capable of
handling pulse signals
Requirement of OEM certificate for
confirming support is waived.
However vender should be fully responsible
to provide the support for maintenance of
equipments and instruments not only during
warranty period but also commit to maintain
the same post warranty.
In case of AMC. Vendor shall indicate AMC
cost and post warranty period in the quote.
After ATP completion, the fist unit will be
installed in CABS. Based on completion of
installation the selected unit will be delivered
and installed at any of the user site. This is
expected to happen within 30 days of the
completion of installation and acceptance of
the first unit.
If any delay, vendor payment will be released.
No Extension, Delivery schedule is to
maintained.



41.
Vendor requested for the
maximum time duration for the
installation at the user site
42.
Extension of delivery period
requested
43.
CAN LXI/USB instruments be
suggested as well?
44.
Detailed Switching Requirements



Yes under following conditions
 The instruments shall be located within the
chassis (as defined)
 Should operate seamlessly
 Should be off the self and from reputed
OEM
 ATE vendor shall take full responsibility for
seamless integration, operation, testing and
proving.
Our block diagram is only as an example, however
‐5‐ of all the three ATEs
vendor can propose a their configuration and
technical scrutiny will be carried out
Video switch matrix may be used in a scenario
similar to that of the RF switch matrix.
The frequency range must be from DC to 100MHz
Must have less than 1dB Loss
The switch must be a non-blocking switch
In terms of H/W minor re-configurability is
essential. Major reconfiguration may be taken up
separately as additional requirement
In Terms of S/W absolute re-configurability is
essential
Enclosed in Corrigendum Appendix-B
45.
Where is the 16x16 Video Switch
Matrix going to be used?
Frequency Range?
46.
Reconfigurablility of Test
Scenarios in Test system (in terms
of H/W and S/W changes)
47.
Details of Programmable FPGA
Modules
48.
ATE controller – High
Performance PC or Embedded
controller?
Embedded controller is required for each chassis as
mentioned in the RFQ. In addition on external ATE
controller for RF/ Communication ATE.
49.
Functionality of LVDS cards
It is one of the required interfaces.
50.
List of Measurements that needs
to be done using different ATEs?
Design Details will be discussed with finalized
vendor as part of requirement capture.
Measurement and Stimulus
ranges?
51.
Maximum Voltage and Current
ranges for DMM?
Other Measurements planned on
DMM
DMM current and voltage requirement is
mentioned in the RFQ and as per the standards
/universal requirement of DMM.
Design details will be provided during requirement.
52.
How many Ethernet ports
required on each ATE and what is
the purpose
53.
Yes specification
Can VSG and VSA be quoted
separately instead of Vector signal Appendix B
transceiver?
54.
Measurements using NI-6115
Multifunction Card?
This is required for data I/O operation. However
the spec for generic instruments is enclosed
55.
Why is a DC Chassis required?
56.
Measurements required on S
Series DAQ
This requirement is removed replace with AC
chassis. Refer to corrigendum Appendix B.
Will be part of the requirement capture.
57.
Specifications of the counter timer
card
One managed 24 port Ethernet switch per ATE
enclosed
in
Corrigendum
Enclosed in the corrigendum Appendix B
‐6‐ 58.
Clarification on point C on page 8
Design details will be revealed after identifying the
development finalized vendor
59.
AAAU_ATE block diagram
shows Hand held analyser but
equipment list doesn’t mention
the same.
Hand Held Analyser used for preliminary checking.
Hence it is essential.
60.
Point a page 5 : frequency range
clarification
It is our requirement
61.
Lab VIEW requirement
explanation and programming
environment detail
LAB view real time is well known proven software
for instrumentation. Further trained scientists at
CABS to take over and maintain.
62.
RF switch 1:4, 1:2 specifications
Refer to Corrigendum Appendix-B.
63.
Specs of attenuators
64.
Qualification Agency
65.
Field conditions for Cooling and
Dust Protection
Must work from DC-18GHz and 18-40GHz,
attenuation maybe around 30-40dB
Refer to corrigendum Appendix B
Acceptance or qualification will be done by team
appointed by CABS and may contain members
from CEMILAC/DGAQA/ IAF etc.
AAAU ATE will be field deployable others will be
inside the AC room.
66.
What does 160 mean in the
Section where it is mentioned
“TRMM(160)”??
160 TRMMs are a part of the AAAU. This is only
for reference.
67.
MRDSP, FEA, FER - Abb.
68.
The RF & Microwave ATE has
only one table listed whereas
Other ATEs have three table
listings each.
Do we have more components
than listed on page 43?
Can modular solutions with
additional LCD Display be
suggested?
They are all sub system LRU’s only for reference.
The more details will be available to qualified
vendor
No
RF/ microwave ATE and communication ATE will
be configured according to the table enclosed.
69.
Vendor can suggest
70.
Printer Specifications
Given in RFQ
71.
“(F) Copy No maintaining”
Printing the “Copy Number”
What does this mean?
72.
CABS responsibility for off-site
calibration
CABS will not take any responsibility for transport
of equipment to calibration site. The whole
calibration process is vendor’s responsibility.
‐7‐ 73.
Test case, H/W, OS update
support
74.
a. Criteria/level of
qualification?
b. IEEE-12204/Mil 2678/DO178B which test are applicable
to which LRUs
c. DO-178B has multiple levels
(A-E), which would be
applicable for the different
LRUs?
d. Which portion of the
software needs to be compliant
to the standards.
On Page 25 interface adaptors
are mentioned as 2 sets for
ATE1 & ATE2.
Please advice how many cables
are required for
a. Interfacing ATE to the
Virginia Panel
b. How many Virginia Panel
Interfaces are required
c. What is the scope of the spare
deliverables?
Extension of acceptance
Schedule?
75.
76.
There is no change in the hardware of the LRU, test
cases as and when emerged, updates include OS,
lab view and other third party software.
LRU qualification is not within the scope
DO-178B is not required
IEEE-12204/Mil 2678 only for documentation
Virginia Panel interface connector is a requirement
Strictly no, Delay will invite LD clause and
closure.
77.
Difference between Mobile ATE
and base station ATEs
Mobile ATE is configured mobile shelter/SUV
specified to be procured integrated, installed on
vehicle. Other two types of ATE will be located in
fixed rooms.
Not specific H/w qualification is needed as these
ATE’s are off the self equipments.
Either equipments will be brought by CABS or
payment will be made afterwards.
78.
H/W qualification for ATEs
79.
Payment for additional equipment
if specified equipment doesn’t
meet the requirement.
80.
Does each Rack of the three racks
contain a 24”LCD Display?
one LCD display for each ATE
81.
LRUs to ATE mapping for
Virginia Panel connector
Will be done during the design process.
82.
List of LRUs
Total number is 39 LRUs
83.
Signal Amplitude and Frequencies This is a design detail which will be discussed with
for LRUs
finalized vendor. The identified equipments cover
all these requirements.
‐8‐ 84.
85.
and
Software
developments,
Quantum of work for AAAU ATE Hardware
instruments/equipments specified to be procured,
integrated installed on a vehicle. Vehicle
procurement and Software development. Quantum
of work to be assessed by the vendor.
Will be defined as part of requirement.
Software test requirement and
method of testing not clear.
86.
Connectivity details of AAAU
mobile ATE to A/C System
Through MIL38999 connectors details as below.
87.
System requirement of each ATE
to be shared rather than the
module/model part number as it
restricts the choice of alternate
options
Not feasible as the design of the ATE needs details
which are classified.
88.
Detailed spec of Horn Antenna
S-Band Horn is required with gain of 20 dBi
89.
Page 11 Block diagram - details
of Variables required
Block Diagram is just an example. Vendor may
suggest alternate configuration
90.
3.1.2.3 (F) explanation
91.
RFQ Appendix-A includes the list
of H/W for all the ATEs (1 set).
Can it be considered for the
calculation of cost towards
hardware items procurement?
Power switching may be required to power various
power connectors in different LRUs
However Hot switching may not be required
8x8 switch matrix is required for connecting
multiple supplies if required.
Yes
92.
Equipments for which Part
No(P/N) are not specified
Broad Specifications enclosed in the corrigendum
Appendix-B
96.
Miscellaneous Queries
Instrument Specific queries have been clarified in the Broad specifications as
corrigendum Appendix-B.
Rest of the unanswered queries can be discussed only with finalized vendor as these
include design details and for Line items (E,F,L,M,O under 3.1.1) vendor may refer to
broad specs
Vendors are intimated they can propose an alternate configuration for each ATE and
Instruments are not OEM specific, however they must meet the functionalities specified
in the “Broad Specifications”
All the LRUs requires exclusive interface adaptor.
97.
Calibration required for all the equipments used in all three types of ATE.
98.
Maximum length of the cable loom from LRU to Interface adopter may be from 2 to 3
meters
93.
94.
95.
‐9‐ 99.
Signal from all the I/O cards of the PXI system and the RF equipments can be brought to
the rear side and terminate in the suitable connectors contained in the output panel.
Vendor can propose the signal cable routing based on the rack design
100.
Calibration is required for all the equipments used in all three types of ATE
101.
AMC is to be considered as whole ATE including hardware & software
102.
02 sets of cables loom to be considered for every LRU
‐10‐ Tender Enquiry No: CABS/14ATT021/LP
File/Ref No : CABS/LPD/20130004/Lgs
Appendix B
GENERIC SPECIFICATIONS FOR ATE INSTRUMENTS
1. For Modular Instruments
Following brings out the details of the modular instruments listed in the RFP .vs. the specification
which will be acceptable for the similar items from the alternate OEM’s/ vendors.
Following is the Consolidated list of Modular Instruments for AAAU_ATE_Chassis_1 to
AAAU_ATE_Chassis_3 , Com_ATE_Chassis_1 to Commn_ATE_Chassis.
Indicated Item
from M/s
National
Instruments
NI PXIe-8135
Core i73610QE 2.3
GHz
Controller,
Win 7 (32-bit)
NI 8260, 4Drive, 1 TB
HDD High
Speed Data
Storage
Module
NI PXI-6561
Digital Wfm
(200 Mb/s,
LVDS
signaling, 2
Mb/ch)
NI PXI-6562
Digital Wfm
(400 Mb/s,
LVDS
signaling, 2
Mb/ch)
NI PXIe-6555
200 MHz, 8
Mb/ch Dig
Wfm; with
PPMU
NI PXIe-6556
200 MHz, 64
Mb/ch Dig
Wfm; with
Enhanced
Quantity Required
AAAU_ATE
Comm ATE
Chass
is 1
Chass
is 2
Chass
is 3
Chassi
s1
Chassi
s2
Chassi
s3
Tot
al
Spe
c
Ref
Embedded
Controller
1
1
1
1
1
1
6
S1
High Speed
Data
Storage
1
1
1
3
S2
Arbitrary
Waveform
generator1
1
1
1
3
S3
1
S4
1
S5
1
S6
Generic
Nomenclature
Arbitrary
Waveform
generator2
Digital
Waveform
Generator 1
Digital
Waveform
Generator 2
1
1
1
‐1‐ Indicated Item
from M/s
National
Instruments
PPMU
NI PXI-4065 6
1/2-Digit
DMM (300V,
3A)
NI 8234 Dual
Gigabit
Ethernet
Controller for
Windows
NI PXIe7966R NI
FlexRIO
FPGA Module
(Virtex-5
SX95T,
512MB RAM)
NI PXIe7962R NI
FlexRIO
FPGA Module
(Virtex-5
SX50T,
512MB RAM)
NI PXI-2543
6.6 GHZ 50
OHM SOLID
STATE DUAL
4X1
MULTIPLEX
ER
NI PXI-2796
40 GHz Dual
6x1
Multiplexer
(SP6T)
NI PXIE5644R Vector
Signal
Transceiver
NI PXI-6115
Multifunction
I/O and NIDAQ (High
Memory
Option)
Quantity Required
AAAU_ATE
Generic
Nomenclature
Chass
is 1
Digital
Multi Meter
1
Gigabit
etehrnet
Controller
1
Programma
ble FPGA
module1
1
Programma
ble FPGA
module2
Solid State
Multiplexer
Chass
is 2
1
Data
Acquisition
Module
Chassi
s1
Chassi
s2
Chassi
s3
2
1
1
1
1
1
1
1
1
8
Multiplexer
Module
Vector
Signal
Transciever
Chass
is 3
Comm ATE
2
1
1
1
1
3
1
Tot
al
Spe
c
Ref
5
S7
3
S8
3
S9
2
S10
12
S11
1
S12
2
S13
4
S14
‐2‐ Indicated Item
from M/s
National
Instruments
NI PXI-6132 S
Series
Multifunction
DAQ Device
NI PXI-6608
Counter/Time
r Module and
NI-DAQ
NI PXIe-6368,
X Series DAQ
(16
Simultaneous
AI, 48 DIO, 4
AO)
NI PXI-5122
14-Bit, 100
MHz Digitizer
with 8 MB/ch
NI 5734 16-bit,
120 MS/s, 4
Channel
Digitizer
Adapter
Module
NI 6583 (32 SE
and 16 LVDS,
200 MHz SDR,
300 Mbps
DDR)
NI PXI-7841R
LX30
Multifunction
RIO (8 AI, 8
AO, 96 DIO)
NI PXI-5691 8
GHz
Programmable
RF Amplifier
Module
NI PXI-5695 8
GHz
Programmable
RF Attenuator
NI PXI-8250
System
Monitor
Module
Generic
Nomenclature
Quantity Required
AAAU_ATE
Chass
is 1
Chass
is 2
Multifunctio
n Data Acq
Module
Chassi
s1
Tot
al
Spe
c
Ref
1
S15
1
1
S16
1
1
S17
Chassi
s2
Chassi
s3
1
Counter
Timer
Module
Data
Acquisition
Module
High Speed
Digitizer
Oscilloscope
Module
Digitizer
Adaptor
Module
LVDS
interface
Chass
is 3
Comm ATE
1
1
2
S18
1
1
2
S19
2
S20
1
1
S21
2
Multifunctio
n RIO
Module
RF
Amplifier
Module
1
1
2
S22
RF
Attenuator
Module
1
1
2
S23
System
Monitor
Module
1
1
S24
‐3‐ Indicated Item
from M/s
National
Instruments
2 Channel
1553 PXI
Interface
Module from
AIT (Extended
Function)
8 Channel
ARINC429
PXI Interface
Module from
AIT (PXI4293U-8)
NI PXI-8232,
GIGE and
GPIB
Controller for
Windows and
LabVIEW RT
NI PXIE-5632
VNA, 300 KHz
8.5 GHz, 2Port, w/Time
Domain
Analysis
System
Functional Test
Windows 7 32Bit For NI PXI
Embedded
Controllers
(English)
NI PXIe-1085,
18-Slot 3U PXI
Express
Chassis
NI PXI-1045,
18-Slot 3U
Chassis with
Universal AC
Power Supply
NI PXIe-1085,
18-Slot 3U PXI
Express
Chassis
PXIe-1065, 18Slot 3U
PXIe/PXI
Generic
Nomenclature
Quantity Required
AAAU_ATE
Chass
is 1
Chass
is 2
Chass
is 3
Comm ATE
Chassi
s1
Chassi
s2
Chassi
s3
Tot
al
Spe
c
Ref
1553 module
1
1
S25
Arinc 429
Module
1
1
S26
GPIB
Controller
Module
2
2
S27
1
1
S28
Modular
Vector
Network
Analyser
Module
Windows OS
for
controllers
etc.
1
1
1
1
1
1
6
S29
1
1
1
1
1
1
6
S30
1
ATE
Chassis
1
1
1
1
S31
1
1
1
‐4‐ Indicated Item
from M/s
Generic
National
NomenInstruments
clature
Chassis
NI PXIe1066DC, 18Slot 3U PXI
Express DC
Redundant
Chassis
NI PXIe1066DC, 18Slot 3U PXI
Express DC
Redundant
Chassis
Power Cord,
250V, 10A,
India
NI 14/18-Slot
Chassis Front
Rack Mount
Kit
System
Functional Test
SCB-68A
Noise
Rejecting,
Shielded I/O
Connector
Block
SHC68-68EPM Shielded
Cable, 68-DType to 68
VHDCI Offset,
2m
Accessories
SMB112,
Double
Shielded SMB
to BNC Male
Coax Cable, 50
Ohm, 1m
X2 GPIB
Cable,DoubleShielded,Shield
ed
Plug/Receptacl
es,2 m
Quantity Required
AAAU_ATE
Chass
is 1
Chass
is 2
Chass
is 3
Comm ATE
Chassi
s1
Chassi
s2
Chassi
s3
1
Tot
al
Spe
c
Ref
1
1
1
1
1
1
1
1
1
6
1
1
1
1
1
1
6
1
1
1
1
1
1
6
1
1
1
1
1
1
6
1
1
1
1
1
1
6
1
1
1
1
1
1
6
1
1
1
1
2
1
7
S32
‐5‐ Indicated Item
from M/s
National
Instruments
SMB112,
Double
Shielded SMB
to BNC Male
Coax Cable, 50
Ohm, 1m
SCB-68A
Noise
Rejecting,
Shielded I/O
Connector
Block
SHC68-68RMIO Shielded
Cable, 68 pin
D-Type to 68
pin VHDCI,
2m
TB-2709 PXI
Front-Mount
SMB Terminal
Blk for PXI6123 & PXI6133
SMA-2164
Prototyping
accessory for
NI 656X
SHB12X-B12X
Shielded
Cable, LVDS,
1 Meter
SMA 100,
SMA Male to
SMA Male
Flexible Cable,
38.1cm
TB-2708 PXI
Front-mount
SMB Terminal
Blk for PXI6115 & PXI6120
SMB110, SMB
to BNC Male
Coax Cable,
50 Ohm,1 m
Generic
Nomenclature
Quantity Required
AAAU_ATE
Chass
is 1
Comm ATE
Chass
is 2
Chass
is 3
Chassi
s1
Chassi
s2
Chassi
s3
1
1
1
1
1
1
6
1
1
1
1
1
1
6
1
1
1
1
1
1
6
1
Tot
al
1
1
2
1
1
5
1
2
1
1
5
3
17
1
2
3
1
8
Spe
c
Ref
3
1
4
1
‐6‐ Indicated Item
from M/s
National
Instruments
SMB 100,
SMB Female
to BNC
Female Coax
Cab, 50 Ohms,
2 ft, Qty 8
Generic
Nomenclature
Quantity Required
AAAU_ATE
Chass
is 1
Chass
is 2
Chass
is 3
3
3
Chassi
s1
Comm ATE
Chassi
s2
2
Chassi
s3
Tot
al
Spe
c
Ref
8
‐7‐ S1: Embedded Controller for AAAU_ATE_Chassis and Commn_ATE_Chassis
Processor
L3 cache
Dual-channel 1600 MHz DDR3
RAM, maximum
Hard drive (standard option),
minimum
10/100/1000BASE-TX (Gigabit)
Ethernet ports
Hi-Speed USB ports
GPIB (IEEE 488) controller
Serial port (RS232)
Parallel port
Watchdog/trigger SMB
Installed OS2
Intel Core i7 quad core based
6 MB shared Intel smart cache
16 GB
250 GB SATA (7200 rpm)
2
4
Built in or may be included as a separate
modular board in chassis
✓
✓
✓
Windows 7 Professional, Windows XP
Professional SP3 for Embedded Systems3
S2: High Speed Data Storage
(A) Modular pluggable configuration
(B) At least 1 TB capacity in 4X250 GB modules
(C) Raid-0 and 1 capability
(D) High speed data streaming capability
S3: Arbitrary Waveform Generator 1:
No of Channels
Minimum 16 bidirectional programmable
Or
Data/waveform rate
Channel Voltage level
In built memory
Sample clock sources
On board clock
Clock output
Trigger Types
Trigger Input Sources
16 input and 16 outputs
≥200 Mb/S
LVDS for both inputs and outputs
≥ 64 Mb
1. Onboard clock
2. External CLK IN
Settable from 50 Hz to Max clock rate (atleast
100 Mhz)
LVDS, Programmable
Start trigger, Pause Trigger, Reference trigger
Internal, External from front/Back plane
‐8‐ Pattern Match, Software trigger
Trigger outputs
Data and control channels outputs
Software
To be included
Enable/ Disable trigger sources
To front panel/ back plane
Generation same as above
High speed back plane/ front panel
(A) Driver for Windows
(B) Digital Waveform editor compatible
with labview/lab windows
(C) Script editor compatible with National
instruments Lab windows, lab view
software.
All cables, connectors, adaptors.
Cable for all data , clock input/output
connectivity to external entity. 2 mtr ,
5 mtrs and 10 mtrs cable
S4: Arbitrary Waveform Generator 2
No of Channels
Minimum 16 bidirectional programmable
Or
Data/waveform rate
Channel Voltage level
In built memory
Sample clock sources
On board clock
Clock output
Trigger Types
Trigger Input Sources
16 input and 16 outputs
≥400 Mb/S
LVDS for both inputs and outputs
≥ 128 Mb
3. Onboard clock
4. External CLK IN
Settable from 50 Hz to Max clock rate (at
least 100 Mhz)
LVDS, Programmable
Start trigger, Pause Trigger, Reference trigger
Internal, External from front/Back plane
Pattern Match, Software trigger
Enable/ Disable trigger sources
‐9‐ Trigger outputs
To front panel/ back plane
Data and control channels outputs
Software
Generation same as above
High speed back plane/ front panel
(D) Driver for Windows
(E) Digital Waveform editor compatible
with lab view/lab windows
(F) Script editor compatible with National
instruments Lab windows, lab view
software.
To be included
All cables, connectors, adaptors.
Cable for all data, clock input/output
connectivity to external entity. 2 mtr ,
5 mtrs and 10 mtrs cable
S5,S6 : Digital Waveform Generator 1 & 2
Digital I/O
Trigger types
Minimum 24
bidirectional I/O
Hardware(digital) and
Software
External and Internal
Hardware And Software
200 Mb/S, 200 Mhz
Clocking
Timing
Maximum Speed/
Channel and Clock
Rate
Logic Levels,
-2.0 to 7.0 V per pin
Programmable
programmable voltage
Levels
Watch Dog timer
Other I/O
Logic State
Control
On board Memory
Other
Software Support
Independently
source or sink up
to at least 30 mA
per channel
To be provided
Handshaking/Control I/O
Direction Programmable
per cycle per pin
At least 32 MB for
digital Waveform
Generator 2
Support Data/Waveform
Delay
Parallel and Serial
Interface support
All drivers for NI Lab
View / Lab windows ,
Waveform Editor etc.
All Drivers
and Software
to be
delivered
‐10‐ S7: Digital Multimeter Module
(A) Number of Channels 1
(B) Number of digits 6.5
(C) Max voltage range : higher than -150 V to + 150
(D) Max frequency range: DC to 100 Khz
S8: Dual Gigabit Ethernet controller
(a) 2 Gb ethernet ports
(b) Form factor same as other cards
S9,S10 : Programmable FPGA Module 1 & Programmable FPGA Module 2FPG
Digital I/O
Data rate / channel
Logic Levels
FPGA
Software Support
Accessories
At least 100 or more bidirectional channels
1 Gb/Ps per channel
1.8 V , LVDS , 1.5 V , LVTTL , 1.2 V , 2.5 V ,
3.3 V
Suitable Xilinx FPGA Virtex 5/Virtex 5S
Windows, Real time, Xilinx FPGA
development systems, Lab windows,/ Lab view
RT
DSP libraries for Lab windows/Lab view/ Mat
lab
All cables, Connectors, Adaptors/adaptor
modules for development to be included.
Adaptor modules, cables etc for
interconnection , programming, testing in lab as
independent card to be included
‐11‐ S11: Solid State 4X1 Multiplexer
Operating Bandwidth
Switch type
Switch Configuration
≥ 6 Ghz
Solid State
2x 1:4 EXPANDABLE
VSWR
1:1.6 or better at max
frequency
In built
Programmable through
standard bus/interface
Back plane
PXI/PXIe/PCI/VXI or
USB/RS 232
50 Ohms
SMA female
≥40 Db
≤1 dB
All cables, connectors,
adaptors etc to be included
Switching control
Programmability
Interface type
Connector Impedance
I/O Connector
Isolation per channel
Loss / channel
Others
Software
The total quantity given in the
list is for dual configuration
from M/s National
Instruments. However vendors
may quote for single 1: 4
switch configuration, in which
case the total quantity must be
doubled
1 Set of short cable for
connecting to ATE adaptor(1
to 2 meter each)
1 Set of ultra short cable (1 Ft
each) for connecting from one
switch to other
All control / digital cables to
be included
Matched terminations 2 sets to
be included to be used for
terminating un used ports
All drivers for programming
through Windows, Lab view/
Lab windows to be included
‐12‐ S12: Multiplexer module
Operating Bandwidth
Switch type
≥ 40 Ghz
Electro mechanical /Solid
State
Switch Configuration
2x 1:6 EXPANDABLE
VSWR
1:1.6 or better at max
frequency
In built
Programmable through
standard bus/interface
Back plane
PXI/PXIe/PCI/VXI or
USB/RS 232
50 Ohms
SMA female
≥60 Db
≤1 dB
All cables, connectors,
adaptors etc to be included
Switching control
Programmability
Interface type
Connector Impedance
I/O Connector
Isolation per channel
Loss / channel
Others
Vendor may quote for both.
Customer will select the
option.
The total quantity given in the
list is for dual configuration
from M/s National
Instruments. However vendors
may quote for single 1: 6
switch configuration, in which
case the total quantity must be
doubled
1 Set of short cable for
connecting to ATE adaptor(1
to 2 meter each)
1 Set of ultra short cable (1 Ft
each) for connecting from one
switch to other
All control / digital cables to
be included
Matched terminations 2 sets to
be included to be used for
terminating un used ports
Software
All drivers for programming
through Windows, Lab view/
Lab windows to be included
S13: Vector Signal Transceiver/Vector Signal Transmitter/Vector Signal Receiver
Type
Signal type
Minimum Frequency
Maximum Frequency
Third Order Intercept (TOI)
Instantaneous Bandwidth
Triggering
Transceiver/Transmitter/Receiver
RF Vector for both transmit and
receive
65 MHz
6 GHz
19 dBm
80 MHz
Software Trigger , Digital ,
Analog , External Trigger ,
Internal Trigger
‐13‐ Output Noise Floor @ -30
dBm
SFDR (Spurious-Free
Dynamic Range)
Maximum Output Power
Maximum Input Power
Digital I/O
Bidirectional Channels
Timing
Maximum Clock Rate
Maximum Data Rate /
Channel
Logic Levels
Digital Interface
Per Cycle Bidirectional
Logic State Control
Supports Hardware Data
Compare?
Supports Linking/Looping
Segments?
FPGA
RF Product Type
Software Support
-168 dBm/Hz
-55 dBc
10 dBm
30 dBm
24
Hardware
125 MHz
250 Mbits/s
TTL
Parallel
Yes
Per Cycle Bidirectional
Yes
Yes
Virtex-6 LX195T
RF Signal Analyzers , RF Signal
Generators , RF Signal
Transceivers
Drivers, Programmes for
Windows, Lab view, Lab
windows
Should include appropriate
RF cables, Connectors,
terminations, adaptors.
Digital, Analog, cables,
connectors, adaptors
The following Signal generator receiver combination will be acceptable . In case of availability of
both transceiver , transmitter and receiver , then all may be quoted as options for selection by
the customer.
Accessories
Cables/Connectors, Adaptors as
required to install operate and
use in lab , as part of ATE or in
stand alone
S13a Vector Signal generator/Transmitter
Equivalent Product model from M/s
National Instruments
Triggering
External Clocking
I/O Connector
RF
Frequency Range
RF Output
Channels
Timing
Output Impedance
PXI-5652
Alternate generic
specifications given as
below
Digital
Yes
SMA female
≤500 kHz to ≥ 6 Ghz
1
Hardware
50 Ohm
‐14‐ On-Board Memory
Frequency Hopping and Sweeping to be
supported
Supports Modulation?
Real-Time Bandwidth (RF only)
Noise Floor (@ -50 dBm output)
Phase Noise
RF Power Range
Power setting resolution
Modulation types
Modulation Input
Software Support
Accessories
≥1024 bits
Yes
No
≥8 MHz
≤-140 dBm/Hz
≤-100 dBc/Hz
≤-30 dBm to ≥ +10 dBm
0.1 dB
FM,FSK,OOK,Pulse
Internal & External
Drivers, Programmes for
Windows, Labview, Lab
windows
Cables/Connectors,
Adaptors as required to
install operate and use in
lab , as part of ATE or in
stand alone
Should include
appropriate RF cables,
Connectors, terminations,
adaptors. Digital, Analog,
cables, connectors,
adaptors
S13b Vector Signal Receiver
Triggering
Synchronization Bus (RTSI)
External Clocking
I/O Connector
Equivalent NI Product Name
Frequency Coverage
Displayed Avg. Noise Level @
1 GHz (DANL)
Channels
Resolution
Bandwidth
Input Impedance
On-Board Memory
Frequency Range
Provides Digital Down
Conversion?
Phase Noise
Noise Floor (@ -50 dBm
output)
Amplitude Accuracy
SFDR
Analysis Measurement
Software Support
Digital , Analog
Yes
Yes
SMA female
NI PXIe-5663E
≤10 MHz to ≥6 Ghz
≤-140 dBm/Hz
1
16 bits
≥50 MHz
50 Ohm
≥256 MB
10 MHz - 6.6 GHz
Yes
≤-100 dBc/Hz
≤-140 dBm/Hz
≤±1 dB
Better than 75 dB
Amplitude, Phase(Wrt to Ref
Signal), Spectrum
Drivers, Programmes for
Windows, Labview, Lab
windows
‐15‐ Accessories
All measurement and Analysis
Software compatible with Lab
windows/Lab view etc..
Cables/Connectors, Adaptors as
required to install operate and use
in lab , as part of ATE or in stand
alone
Should include appropriate RF
cables, Connectors,
terminations , adaptors. Digital,
Analog, cables, connectors,
adaptors
S14,S15 : Multifunction I/O and Data Acquisition Unit
Signal Conditioning
Analog Input
Number of Channels
ADC Resolution
Sample Rate
Maximum Voltage Range
On-Board Memory
Analog Output
Channels
Resolution
Max Voltage range
Update Rate
Digital I/O
Bidirectional Channels
Timing
Maximum Clock Rate
Logic Levels
Input Current Flow
Output Current Flow
Current Drive Single
Counter/Timers
Built in Low-pass filtering ,
Anti-aliasing filter
Minimum 4 differential
≥12 bits
≥ 10 MS/s simultaneous
sampling
≥ ± 40 V
≥ 64 MB
2
≥12 bits
±10 V
≥ 2 MS/s
≥8
Hardware
≥10 MHz
TTL
Sourcing , Sinking
Sinking , Sourcing
≥24 mA
2 with pulse generation
capability
Number of DMA Channels
1 with buffered operations
Max Source Frequency
≥20 MHz
Resolution
≥24 bits
Timebase Stability
Better than 100 ppm
Logic Levels
TTL
Timing/Triggering/Synchronization
Digital , Analog , Internal,
Triggering
External
All drivers , libraries for
Software
Windows , Labwindows/
Number of Counters
‐16‐ Others
Labview/Labview RT
All Cables, Connectors,
Adaptors to be included
S16 : Counter Timer Module
Digital I/O
Bidirectional Channels
32 Bidirectional
Timing
Software , Hardware
Logic Levels
TTL
Input Current Flow
Sinking , Sourcing
Output Current Flow
Sourcing , Sinking
Programmable Input Filters
In built
Current Drive Single
4 mA
Counter/Timers
Counters
≥8
Number of DMA Channels
≥2
Buffered Operations
Yes
Debouncing/Glitch Removal
Yes
GPS Synchronization
Optional
Maximum Range
0V-5V
Max Source Frequency
80 MHz
Minimum Input Pulse Width
6.25 ns
Pulse Generation
Yes
Resolution
32 bits
Timebase Stability
≤0.1 ppm
Logic Levels
TTL
Timing/Triggering/Synchronization
Triggering
Digital
All drivers , libraries for Windows ,
Software
Labwindows/ Labview/Labview RT
All Cables, Connectors, Adaptors to
Others
be included
S17 : Data Acquisition Module
Analog Input
Channels
16 programmable differential
Differential Channels
16
Resolution
16 bits
Sample Rate
≥2 MS/s simultaneous
Voltage Range
0 to ±10V
Analog Output
Channels
4
Resolution
16 bits
Voltage input Range
0 to ± 10V
Digital I/O
Bidirectional Channels
48
Timing
Software , Hardware
Clocked Lines
32
Maximum Clock Rate
10 MHz
Logic Levels
TTL
‐17‐ Programmable Input Filters
Yes
Current Drive Single
≥24 mA
Yes
Watchdog Timer
Counter/Timers
Counters
≥4
Number of DMA Channels
≥4
Debouncing/Glitch Removal Yes
Maximum Range
0V-5V
Max Source Frequency
100 MHz
Pulse Generation
Yes
Resolution
32 bits
Timebase Stability
50 ppm
Logic Levels
TTL
Timing/Triggering/Synchronization
Triggering
Digital , Analog
All drivers , libraries for Windows ,
Software
Labwindows/Labview/Labview RT
All Cables, Connectors, Adaptors to
Others
be included
S18 : High Speed Digitizer Oscilloscope Module
Triggering
Edge, window, hysteresis, video, and
digital triggering
Yes
SMB male , BNC connectors
External Clocking
I/O Connector
Analog Inputs
Channels
2 or more simultaneous sampling
Resolution
≥14 bits
Simultaneous Sampling
Yes
Sample Rate
≥100 MS/s
Random Interleaved Sampling
≥1 GS/s
(RIS) Rate
Bandwidth
≥100 MHz
Input Impedance
50 Ohm , 1 MOhm
Maximum Common Mode
≥40 V
Voltage
On-Board Memory
≥256 MB/ch
Frequency Range
0 Hz - 100 MHz
Max Voltage
-10 V - 10 V
Minimum Voltage Range
-100 mV - 100 mV
Spurious-Free Dynamic Range ≥75 dBc
Total Harmonic Distortion
≤-75 dBc
(THD)
Signal-to-Noise-and-Distortion
≥62 dB
Ratio (SINAD)
Phase Noise
≤-130 dBc/Hz
Analog Output
Software
All drivers , libraries for Windows ,
‐18‐ Labwindows/Labview/Labview RT
Measurement and Analysis
software/libraries
All Cables, Connectors, Adaptors to
be included
Others
S19 : Digitizer Adaptor Module
LabVIEW RT Support
I/O Connector
Analog Input
Channels
Resolution
Simultaneous Sampling
Sample Rate
Input Impedance
Frequency Range
Max Voltage
Minimum Voltage Range
Spurious-Free Dynamic Range
Total Harmonic Distortion
(THD)
Digital I/O
Bidirectional Channels
Timing
Maximum Clock Rate
Maximum Data Rate / Channel
Logic Levels
Per Cycle Bidirectional
Gain
Input filtering
Input Coupling
S20 : LVDS Interface
Triggering
External Clocking
I/O Connector
Digital I/O
Bidirectional Channels
Timing
Maximum Clock Rate
Maximum Data Rate /
Channel
Logic Levels
Differential Logic
Digital Interface
Yes
BNC connectors
At least 4 simultaneous
16 bits
Yes
120 MS/s
50 Ohm
0 Hz - 100 MHz
-1 V - 1 V
-0.25 V - 0.25 V
≤-80 dBc
≤-85 dBc
12
Hardware
≥5 MHz
≥10Mbits/s
3.3 V
Yes
Programmable
Elliptic, Bessel, or bypass input
filters
Selectable AC or DC coupling
Digital
Yes
InfiniBand connector , 68-pin
VHDCI female
48
Hardware
200 MHz
300 Mbits/s
1.5 V , LVDS , 1.2 V , 2.5 V , 3.3 V
, 1.8 V
Yes
Parallel
‐19‐ Logic State Control
Software
Others
Bidirectional
All drivers , libraries for Windows ,
Labwindows/Labview/Labview RT
Measurement and Analysis
software/libraries
All Cables, Connectors, Adaptors to
be included
Adaptor/Cable for interfacing to
FPGA boards to be included
S21 : Multi Function RIO Module
Operating System/Target
LabVIEW RT Support
DAQ Product Family
Measurement Type
Analog Input
Channels
Single-Ended Channels
Differential Channels
Resolution
Sample Rate
Maximum Voltage Range
Simultaneous Sampling
Analog Output
Channels
Resolution
Maximum Voltage Range
Current Drive Single
Digital I/O
Bidirectional Channels
Timing
Maximum Clock Rate
Logic Levels(Programmable)
Input Current Flow
Output Current Flow
Programmable Input Filters
Current Drive Single
Watchdog Timer
FPGA , Windows ,
Real-Time
Yes
R Series
LVDT , Quadrature
encoder , Filters ,
RVDT , Frequency ,
Voltage
8
8
8
16 bits
≥100 kS/s
-10 V - 10 V
Yes
8
≥16 bits
-10 V - 10 V
2.5 mA
96
Hardware
≥40 MHz
TTL , 3.3 V , 5 V ,
LVTTL
Sinking , Sourcing
Sourcing , Sinking
Yes
4 mA
Yes
Supports Handshaking I/O and pattern I/O
Yes
support
Counter/Timers
Counters
Number of DMA Channels
Buffered Operations
Control Lines for handshaking
and ability to output patterns
with Clock
96
3
Yes
‐20‐ Debouncing/Glitch Removal
Pulse Generation
Resolution
Timebase Stability
Yes
Yes
64 bits
≥100 ppm
LVTTL , TTL , 3.3 V ,
5V
Logic Levels
Reconfigurable FPGA
FPGA Type
Timing/Triggering/Synchronization
Triggering
Virtex-5 Series
Digital , Analog
All drivers , libraries
for Windows ,
Labwindows/Labview/
Labview RT
Measurement and
Analysis
software/libraries
Software for FPGA
programming
All Cables,
Connectors, Adaptors
to be included
Adaptor/Cable for
interfacing to FPGA
boards to be included
Software
Others
S22 : RF Amplifier Module
I/O Connector
RF Input
SMA female
Channels
2
Input Frequency Range
Input Impedance
Input Power Range
Noise Floor (@ -50 dBm output)
RF Output
Channels
Output Impedance
Max RF Output Power
≤50 MHz to ≥6 GHz
50 Ohm
≤-60 dBm to ≥+10 dBm
≤-150 dBm/Hz
Gain
Noise Floor (@ -50 dBm output)
Noise figure
Software
Can be delivered in two
separate units of single
channel. If so double the
number of units for quantity
2
50 Ohm
≥+20 dBm
≥60 dB programmable in 0.5 dB
steps
≤-163 dBm/Hz
≤ 5dB
All drivers , libraries for
Windows ,
‐21‐ Others
S23:RF Attenuator Module
RF Input
Channels
Frequency Range
RF Power Range
Analog Output
Channels
Attenuation Range(Programmable)
VSWR
Software
Others
Labwindows/Labview/Labview
RT
Measurement and Analysis
software/libraries
Software for FPGA programming
All Cables, Connectors, Adaptors
to be included
Adaptor/Cable for interfacing to
FPGA boards to be included
2
≤50 MHz to ≥6 GHz
≤-60 dBm - ≥30 dBm
2
≥ 40 dB in 0.5 dB steps
1.2:1 typical
All drivers , libraries for Windows
, Labwindows/Labview/Labview
RT
Measurement and Analysis
software/libraries
Software for FPGA programming
All Cables, Connectors, Adaptors
to be included
Adaptor/Cable for interfacing to
FPGA boards to be included
S24: System Monitor Module
This module may be included separately or implemented as part of the chassis/boards etc.
Basically the module or its equivalent should
Actively monitor voltage, fan, and temperature health of systems
Programmatically monitor system power, fan health, and chassis intake temperature
Should have front panel LEDs indicate system status
Front panel relay indicates if any parameters are out of range
Should be part of the chassis
Preferably the information should be available to controller in chassis
S25: 1553 module












S26:
Minimum 2 dual redundant MIL-STD-1553 bus interfaces with full error injection and
detection
Concurrent BC, multiple RT (31), and BM operations for extended function interfaces
Onboard timetag clock synchronization to external IRIG or backplane system clock
backplane trigger input/output support (generate PXI triggers on 1553 bus events)
Variable output voltage signal and software-selectable bus coupling modes
Advanced driver for developing applications in LabVIEW, LabVIEW Real-Time, and
Windows-based C/C++
Arinc 429 module
‐22‐ 




At least 8 software-programmable (TX/RX and high/low speed) channels
Rate-oriented, scheduled, and block label transmissions with error injection
Chronological (per channel) data capture with error detection
Onboard timetag clock synchronization to external IRIG or Backplane system clock
Advanced driver for developing applications in LabVIEW, LabVIEW Real-Time, and
Windows-based C/C++
S27: GPIB Controller Module
Source
GPIB Standard Compatibility
Ethernet Compatibility
Port Information
Number of Ports
Max Baud Rate (IEEE 488.1)
Max Baud Rate (HS488)
Max Cable Length
Max Device Connections / Port
I/O Connector
Software
Internally Powered
HS488 , IEEE 488.1 , IEEE
488 , IEEE 488.2
100BaseT , 1000BaseT ,
10BaseT
1
1.5 MB/s
7.7 MB/s
4m
14
24-pin IEEE 488
All drivers , libraries for
Windows ,
Labwindows/Labview/Labview
RT
Measurement and Analysis
software/libraries
Software for FPGA
programming
Others
All Cables, Connectors,
Adaptors to be included
Adaptor/Cable for interfacing
to FPGA boards to be included
‐23‐ S28: Modular Vector Network Analyser Module





300 kHz to 8.5 GHz frequency range
10 Hz to 500 kHz IF bandwidth
>110 dB dynamic range
-30 to +15 dBm source power range
Dual sources with independent frequency and power tuning
Measurement frequency Range
IF Bandiwdth
≤300 Khz to ≥ 6 Ghz
≤10 Hz to ≥ 500 Khz in
programmable steps
Dynamic Range
≥100 dB
Source Power Range
≤-20 dBm to ≥+10 dBm
Number of sources
Dual Source with Individual
Power tuning
Measurements capability
S11,S21,S12,S22,User Defined,
Sweep Capability
Min Frequency to Max
Frequency
Number of Points
1 to ≥10000
Steps
≤ 10 Hz
Data /Information
Magnitude (log),
Magnitude(linear),Phase, group
delay,VSWR,Impedance,complex
reflection and transmission
coefficients
Averaging
1 to 4096
Calibration methods
Auto, Manual
Calibration types
1 PORT SOL, 2 Port SOLT,2
Port SOLR, TRL(LRL,LRM),
Transmission response, reflection
response, source power
calibration, receiver power
calibration
Source
Inbuilt
Source Power Range
+10 dBm to -30 dBm(Levelled)
Power settability
≤0.1 dB steps
Harmonics(measured at 0dBm power) ≤-20 dBc
LO Out Power
≥-10dBm
Time Domain
Time domain option with all
software and associated hardware
to be quoted
Receiver dynamic range
≥100 dB
All drivers , libraries for Windows ,
Software
Labwindows/Labview/Labview RT
Measurement and Analysis
‐24‐ software/libraries compatible with
Labwindows/Labview
All drivers
All Cables, Connectors, Adaptors
to be included
Others
Adaptor/Cable for interfacing to
FPGA boards to be included
Calibration Kits
Calibration kits for auto and
manual to be included for BNC,
SMA , SMB connector types
Test port cables to be included
Cal Kits for TRL calibration to be
included
S29:System functional test:
This involves integration of all modules, test them in integrated condition and certify them for the
performance if required from OEM.
This option if available may be quoted separately. The same will be exercised by the customer.
S30: Windows OS for all the controllers:
Latest professional windows version for the controllers and other units must be supplied along with
original licenses.
S31: Chassis for ATE’s
All modular instruments shall be packaged into standard Chassis. The chassis shall be commensurate
with the number of instruments as indicated in the table. The chassis shall have following
(A) Standard back plane (PXI/PXIe/VXI/PCI/VME or any others)
(B) In case any modular instrumentation with USB or other Standard architecture,
appropriate slot for the same must be provided.
(C) Power supply shall be from 100V to 240 V , 50-60 Hz
(D) Should have adequate power capacity for all instruments installed
(E) Should have adequate cooling / fans built in
(F) Should have power on off , reset switches
(G) Should have LED’s for showing the status of power supply cooling fans, boards
(H) Should have system monitor function as mentioned above
(I) The chassis must be light weight, aluminum
(J) All wiring in back plane, cables, connectors etc. must be part of contract.
(K) All chassis shall be provided with rack mount kits.
‐25‐ S32: Accessories
All accessories such as cables, connectors, adaptors, match terminations etc. equivalent to listed ones
as required for the instrument connections, operation, interfacing etc. must be included and quoted.
The list shall be comprehensive and indicate whether the same is essential or optional so that
appropriate options can be exercised.
The cost will be compared based after including all the essential accessories. In case user feels any of
the accessories listed as options is essential then users decision will be final as the same will be
included in the cost comparison for L1.
For all the boards specifically for FPGA boards appropriate adaptors to take out the digital signals
must be provided.
Configuration Basic Requirements:
The configuration shall be based on the standard architecture such as PXI/PXIe/VXI/VXIe/VME /PCI
etc. Also modular instruments with USB/RS232/Standard Lan etc. Interfaces may be used where
available. However the responsibility to integrate these in chassis and make to seamlessly operate
whall be vendor’s sole responsibility.
Software Development Environment
For the ease of maintenance , the software shall be developed in Lab view/Lab windows environment.
Towards this vendor shall be solely responsible to get the appropriate driver packages for all the
modular instruments and test equipments. As mentioned in the original RFP, all of these should be
licensed version and genuine.
For instruments such as FPGA boards, the Vendor shall also provide all required software packages
for building custom codes, programming the FPGA. In addition, vendor shall provide DSP libraries
under Lab windows/Labview/Matlab etc. usable by these boards.
All the instruments shall have a software drivers, analysis packages, control software etc.
RF/Microwave ATE
1. Microwave Network Analyzer
Source
2-port single source and 4-port dual source
10 MHz to 43.5 GHz
Frequency Range
Frequency Resolution
Frequency Accuracy
System Dynamic Range
Receiver Dynamic Range
1 Hz
+/- 1 ppm
75 dB (spec) & 94 (char)
100 dB@ Environmental temperature 23° ±3 °C,
‐26‐ Max. leveled power
with < 1 °C deviation from calibration
temperature
0 dBm (spec) & 4 dBm (Characteristic)
Power Level Accuracy
≤ +/-1.5dB
Power Level Linearity
≤ +/-2.0 ( -25 dBm ≤ P < -20 dBm )
Power Sweep Range
≥25 dB
Power Resolution
≤0.1 dB
Total average (rms) noise power
≤-75 dBm
Trace Noise Magnitude
≤0.200 dB rms @1 kHz IFBW
Trace Noise Phase
≤1.000 deg rms @ 1 kHz IFBW
Reference Level Magnitude
Magnitude (dB)
(degrees)
Range
Resolution
Stability
+/- 500
0.001
Magnitude (dB/°C)
Phase
+/- 500
0.01
Phase
(°/°C)
0.02
RF (dBm)
Damage Level
0.25
DC
System IF Bandwidth Range
(VDC)
Ports 1, 2
30
1 Hz to 15 MHz, nominal
CPU
Intel® with ≥ 4 GByte RAM
RF Connectors
Test Ports
2.4 mm (male), 50 ohm, (nominal), 0.002 in.
(characteristic)
4 ports
USB 2.0 Ports
Display
40
VGA Video Output
10.4 inch diagonal color active matrix LCD; 1024
(horizontal) X 768 (vertical) resolution
15-pin mini D-Sub;
Trigger Inputs/Outputs
BNC(f), TTL/CMOS compatible
GPIB
Two ports
LAN
10/100BaseT Ethernet, 8-pin configuration
Line Power
Frequency, Voltage
VAC
50/60/ Hz for 100 to 120
50/60 Hz for 220 to 240
VAC
Max power
350 watts
2. Oscilloscope 4 GHz with options
S.
Parameters
Specifications Required
No.
4 GHz
Analog Bandwidth(500MHz
3dB) 50Ω
1M Ω
‐27‐ Typical Rise Time / Fall
Time 10% to 90% at 50 Ω
Memory
Input channels
Input impedance
Input sensitivity
Maximum input voltage
Analysis
Probe Correction
RMS Noise Floor (V
RMS AC)
Digital Channels:
Input channels
Threshold selections
Maximum input voltage
Threshold accuracy
Input dynamic range
Minimum input voltage
swing
Resolution
Display
Bandwidth limit
Vertical resolution
Channel-to-channel
isolation
Glitch detect
Main time base range
Horizontal position
range
Sampling Modes
85 ps
20 Mpts per channel memory, upgradeable to 1
Gpts
4 analog + 16 digital
50 Ω ± 2.5%, 1 MΩ ± 1% (11pF typical)
1 MΩ: 1 mV/div to 5 V/div
50 Ω: 1 mV/div to 1 V/div
1 MΩ: 150V RMS or DC, CAT I
± 250 V (DC + AC) in AC coupling
50 Ω: 5 Vrms
Software required for Offline analysis on PC
Required for correction of uncertainty in specific
cable or
probe to avoid loss.
10 mV (Volts/div) = 263 uV (full BW)
20 mV (Volts/div) = 424 uV (full BW)
50 mV (Volts/div) = 1.12 mV (full BW)
100 mV (Volts/div) = 2.16 mV (full BW)
200 mV (Volts/div) = 4.15 mV (full BW)
500 mV (Volts/div) = 11.26 mV (full BW)
1V (Volts/div) = 21.9 mV (full BW)
16 digital channels
TTL (1.4V), CMOS, (5.0V, 3.3V, 2.5V), ECL (1.3V), PECL (3.7V), user defined (±8.00 V in 100
mV increments)
±40 V peak CAT I
±(100 mV + 3% of threshold setting)
±10 V about threshold
500 mV peak-to-peak
1 bit
15 inch color XGA TFT-LCD with touch screen
20 MHz on 1 MΩ input ; 500 MHz up to full
scope bandwidth in increments of 500 MHz
8 bits, ≥12 bits with averaging
DC to 50 MHz: 50 dB
>50 MHz to 2.5 GHz: 40 dB or better
>2.5 GHz to 4 GHz: 25 dB
≥ 2.0 ns
5 ps/div to 20 s/div
0 to ± 200 s
Real-time, Real-time with peak detect
Real-time with high resolution, Real-time with roll
mode (200 ms to 20 sec.), Equivalent-time,
Segmented memory
‐28‐ Trigger Modes
Waveform update rate
Operating system
CPU
Hard drive
Peripherals
I/O ports
Operating Temperature
Power
Weight
Safety
Accessories
Edge(analog and Digital), Edge then edge,
Glitch(analog and Digital), Line, Pulse width
(analog and Digital) (Minimum detectable pulse
width: 125 ps), Runt (analog), Timeout(analog and
Digital), Pattern/pulse range(analog and Digital),
State(analog and Digital), Setup/hold, Window
(analog), Video (analog), Zone-qualified (up to 8
user-drawn zones)
Maximum up to 250,000 waveforms/sec (Using
Segmented Memory)
Windows 7 Embedded Standard
Intel® Core 2 Duo, M890, 3.0 GHz
microprocessor
≥ 250-Gb internal hard drive
Optical USB mouse and compact keyboard
LAN, RS-232 (serial), PS/2, USB 2.0 Hi-Speed,
Video output
5 °C to + 40 °C
100-240 V, ± 10% 50/60 Hz
Not more than 12 KGs
Meets IEC1010-1 Second Edition, certified to
UL61010-1 and CAN/CSA-C22.2 No 61010-1
Second Edition (IEC61010-1:2001, MOD).
500 MHz passive probes-4 No.s
Probe Amplifier 1.5GHz with Differential/Singleended Connectivity Kit.
probe accessory pouch, power cord, front panel
cover, keyboard, mouse, and touchscreen pen.
3. Spectrum Analyzer (N9030A-543)
Sl. No.
1
2
3
Parameters
Frequency Range
Specifications
3 Hz to 43 GHz
Frequency Reference Accuracy
Aging Rate ± 1 × 10-7/year
Temperature Stability
Accuracy one year after last
adjustment
20 °C to 30 °C : 10-8
5 °C to 50 °C : 10-8
4
5
6
SSB Phase Noise
(20 °C to 30 °C, CF = 20 GHz)
Offset 100 Hz
< -80 dBc/Hz
Displayed Average Noise Level
(DANL)
( Freq. 37GHz to 40 GHz)
< -140 dBm
Frequency Span ( Frequency Readout
Accuracy)
Range 0 Hz (zero span), 10 Hz to
maximum
‐29‐ 8
(FFT and swept mode)
Resolution Bandwidth:
Range (–3.01 dB bandwidth)
Video Bandwidth
9
Display Range
7
frequency of 40 GHz , Resolution 2
Hz.
1 Hz to 3 MHz (10% steps), 4, 5, 6,
8 MHz
Range: 8 MHz , Accuracy ± 6 %
Nominal
Log scale 0.1 to 1 dB/division in 0.1
dB steps 1 to 20 dB/division in 1 dB
steps (10 display divisions)
Linear scale 10 divisions
Scale units dBm, dBmV, dBµV,
dBmA, dBµA, V, W, A
10 Reference Level
Range
Log scale :
–150 dBm to +30 dBm in 0.01 dB
steps
Linear scale: 707 pV to 7.07 V in
0.11% (0.01dB) resolution
11 Amplitude range
Displayed Average Noise Level
(DANL) to maximum safe input
level.
0 to 70 dB in 2 dB steps
12 Input attenuator range
(20 Hz to 26.5 GHz)
13 Maximum safe input level
average total power : +30 dBm (1
W)
Peak Pulse Power : +50 dBm (100
W),< 10 µS pulse width
14 Third Order Inter modulation
Distortion (TOI)
TOI ≥ 11 dBm
15 Trace Detectors
Normal, Peak, negative peak, log
power average, sample, RMS
average and voltage average
16 Auto Tune
Must have the capability to tune the
frequency and scale the amplitude
using a single key.
17 Vector Signal Analysis capability
The Signal Analyzer must be
capable of performing vector signal
analysis for complex radar signals.
18 Pulse Measurement
The Signal Analyzer must be
capable of performing pulse analysis
of radar signals.
160 MHz
19 Signal Analysis Band width
‐30‐ 20 Data Storage
Internal : 160 GB nominal
(removable hard disk drive)
External : Supports 2.0 compatible
memory devices
21 Power requirements
Voltage and frequency : 220 to 240
V, 50/60 Hz
Power consumption : ON : ≤ 450 W
Standby : ≤ 40 W
22 RF I/P Connector Type
N-Type(Female), 50Ohm Nominal
23 Accessories
Noise Sources 10 MHz to 26.5 GHz
(ENR 15 dB), noise source cable,
Power Chord
4. Signal Generator(44 Ghz)
S. No.
Particulars
Specifications Required
1
2
Frequency
Resolution
3
CW Switching speed
250 kHz to 44 GHz
CW 0.001 Hz
All sweep modes 0.01 Hz
< 16 ms
4
Phase offset
5
External Reference
5
Digital (Step) sweep
Adjustable in nominal 0.1 °
increments
Freq: 10MHz
Lock Range: ±1.0
ppm
Input: 5 dBm ±
5 dB
Operating modes:
(a) Step sweep of frequency or
amplitude or both (start to stop).
(b) List sweep of frequency or
amplitude or both (arbitrary list).
Sweep range:
(a) Frequency sweep Within
instrument frequency range.
(b) Amplitude sweep Within
attenuator hold range.
Dwell time 1 ms to 60 s
Number of points
(a) 2 to 65535 (step sweep).
(b) 2 to 1601 per table (list sweep).
Triggering Auto, external, single, or
GPIB
‐31‐ 6
Analog (Ramp) sweep
7
Output
8
Spectral Purity
9
Internal baseband generator
10
Modulation
Settling time
Frequency < 8 ms
Amplitude < 5 ms
Operating modes:
(a) Synthesized frequency sweep
(start/stop), (center/span), (swept
CW)
(b) Power (amplitude) sweep
(start/stop)
(c) Manual sweep: RPG control
between start and stop frequencies
(d) Alternate sweep: Alternates
successive sweeps between current
and stored states.
Power : –130dBm to +18dBm
Step Attenuator : 0 to 115 dB in 5
dB steps
Temperature stability 0.01 dB/ °C
Output impedance 50 Ω (nom)
SWR: > 2 GHz to 20 GHz < 1.6:1
: > 20 GHz < 1.8:1
(typ)
Maximum reverse power : 1/2
Watt, 0 VDC
Harmonics (at +10 dBm or
maximum specified output power,
whichever is lower)
< 10 MHz –28 dBc (typical below 1
MHz)
10 MHz to 2 GHz –30 dBc
> 2 GHz to 20 GHz –55 dBc
> 20 to 44
–45 dBc
GHz
(typ)
Sub-harmonics1 (At +10 dBm or
maximum specified output power,
whichever is lower).
250 kHz to 10 GHz None
> 10 GHz to 20 GHz < –60 dBc
Should Generate arbitrary and real
time I/Q.
64 MSa memory waveform (80 MHz
of RF modulation bandwidth).
Modes : Free-run, triggered,
triggered with delay, Doublet, and
gated. Triggered with delay, Doublet,
and gated modes require an external
trigger source.
AM, FM. Phase Modulation and LF
Output to generate analog modulated
signal. (150nSec minimum pulse
width).
‐32‐ 11
Signal Creation Software
12
13
RF Output
Remote Programming
14
Power Requirement
Compatible signal creation software
for pulse building. Should generate
customized pulse patterns for
simulation.
Output Impedance 50 Ohms
GPIB (IEEE-488.2,1987) with listen
and talk, RS-232,and 10BaseT LAN
interface
90-132 V 47 to 64 Hz or 365 to 435
Hz; or
195 to 267 VAC 47 to 64
Hz,(automatically selected)
< 250 W typically, 300 W maximum
17
Storage Registers
18
Connectors, Cables and Documents
Memory should be properly shared
by instrument states and sweep list
files. Depending on how the memory
is used, a maximum of 1000
instrument states should be saved.
Instrument should have all proper
connectors in front and real panel
with proper care in voltage levels
and impedance value for each
connector.
5. Arbitrary waveform generator
S. No.
1
Particulars
Specifications Required
Waveform Types
• Standard waveforms: pulse, sine,
square, ramp, noise, arbitrary
• Predefined arbitrary waveforms:
exponential rise, exponential fall,
sin(x)/x, cardiac and DC
• Pulse, sine, ramp, noise and
arbitrary measured with 50 Ω source
impedance into 50 Ω load
impedance.
Pulse characteristics
Frequency range
High bandwidth amplifier
High voltage amplifier
1 μHz to 330 MHz
1 μHz
Frequency resolution
1.5 ns to (period - 1.5 ns) spec.
Pulse width
Range
100 ps, 6 digits
‐33‐ High bandwidth amplifier
High voltage amplifier
± 300 ps ± 50 ppm
Resolution
Accuracy
Sine characteristics
Frequency range
High bandwidth amplifier
High voltage amplifier
1 μHz to 500 MHz
Frequency resolution
1 μHz
Harmonic distortion
(High bandwidth amplifier
50 Ω into 50 Ω)
Modulation
1 VPP
3 VPP
1 μHz to 2 MHz
< -65dBc
spec. < -63 dBc spec.
2 MHz to 10 MHz
< -62dBc
spec. < -53 dBc spec.
10 MHz to 50 MHz
< -50 dBc
spec. < -40 dBc spec.
50 MHz to 200 MHz
< -30 dBc
spec. < -27 dBc spec.
200 MHz to 500 MHz
< -22 dBc
spec. < -20 dBc spec.
AM, FM, PM, FSK, PWM
Sweep
for frequency sweeps
Bursts
repeats selected waveform n times
6. Power Source/Analyzer
S. No.
Parameters
1.
Number of phases
2.
Specifications Required
1
Output ratings (Maximum)
Power
rms voltage
rms current
Repetitive & non-repetitive peak
current
DC power
DC voltage
DC current
Output frequency range
4 MHz, 2 MHz, 1 MHz, 400 kHz,
200 kHz, 100 kHz
1750 VA
300 V
13 A
80 A
1350 W
± 425 V
10.0 A
DC; 45 Hz to 1 kHz
Constant voltage ripple and noise (20
kHz to 10 MHz)
Line regulation (% of full scale)
Load regulation (% of full scale)
Maximum total harmonic distortion
–60 dB
(relative to full scale)
0.1%
0.5%
0.25% at 50/60 Hz
1% worst case
‐34‐ 45 to 1 kHz
Measurement accuracy
Rms. voltage (45 - 100 Hz)
DC voltage
AC Input Ratings
Voltage range (VAC)
Maximum input current (rms)
Input power (max)
Input frequency
Supplemental characteristics
Average programming accuracy
Average programming resolution
rms voltage
DC voltage
Overvoltage programming (OVP)
rms current
Peak current
Output frequency
0.03% + 100 mV
0.05% + 150 mV
174 to 220 VAC
22 A (200/208 VAC)
3800 VA/2600 W
47 to 63 Hz
1.2% + 50 mA
125 mV
250 mV
2 V peak
4 mA
25 mA
10 μHz
7. Noise figure measurement/meter
S. No.
1.
Parameters
Frequency Range
Specifications Required
10MHz to 26.5GHz
2.
3.
Measurement BW
Measurement
Upto 4 MHz
Sweep
Number of points 2 to 401, or fixed
frequency
Setting Start/stop, center/span,
Frequency list of up to 401 points
Sweep trigger Continuous or single
Modes
Amplifier:
Down-converter in DUT: With fixed
or variable IF.
Instrument capable of controlling an
external
LO via dedicated 'LO GPIB'
connector
Up-converter in DUT: With fixed or
variable IF.
Instrument capable of controlling an
external
LO via dedicated 'LO GPIB'
connector
System down converter: Allows the
use of an external down converting
mixer as part of the measurement
system.
Instrument capable of controlling an
external
‐35‐ 4.
Display
5.
Data storage
6.
Power requirements
7.
Noise figure
LO via dedicated 'LO GPIB'
connector.
17cm Color LCD,
Display channels:2
Display Unit:
Noise figure: Noise figure (F dB),
or as a ratio (F)
Gain Gain: (G dB), or as a ratio (G)
Y-factor: Y-factor (Y dB) or as a
ratio (Y)
Internal drive, 30 traces, states or
ENR tables
On (line 1) 90 to 132 V rms, 47 to
440 Hz
195 to 250 V rms, 47 to 66 Hz
Power consumption< 300 W
Standby (line 0) < 5 W
Noise source ENR
4-7 dB
12-17 dB
dB
Measurement range
Instrument uncertainty
Gain
Measurement range
Instrument uncertainty
0 to 20 dB
dB
± < 0.15 dB
0.2 dB
0 to 30 dB
± < 0.15 dB
20-22
0 to 35
±<
-20 to +40 dB
± < 0.17 dB
8.
Instrument’s own noise figure
9.
Interface
10 MHz to 3.0 GHz < 4.8 dB +
(0.00124 * freq in MHz)
> 3.0 GHz to 13.2 GHz < 12.0 dB
> 13.2 GHz to 26.5 GHz < 16.0 dB
GPIB, RS-232, VGA output
8. Frequency counter
S. No.
1.
Parameters
Microwave B.W
Specifications Required
44 GHz
2.
3.
Additional Measurements
Interface
DC volts and Power
GPIB, RS-232
9. Power supply 28 V(DC), 1000 watt
10. Programmable
Attenuator
Frequency range
(Qty: 10)
: DC to 4GHz
‐36‐ Step
: 0.5dB
IP3
: 52 dBm
Return Loss
: 20 dB
Accuracy
: 0.1dB
VSWR
: 1.5 to 2
11. Switch 1:2
(Qty: 30)
Frequency range
: 10 to 3000 MHz
Switch Time
: 4µS max
1dB Compression
: +20 dBm
Control
: TTL
Isolation
: 40dB
12. Switch 1:4
(Qty: 20)
Frequency range
: 10 to 2500 MHz
Switch Time
: 4µS max
1dB Compression
: +20 dBm
Control
: TTL
Isolation
: 40dB
13. Power Detector
(Qty: 25)
Frequency range
: 10 to 8000MHz
Input Power
: +18dBm
Dynamic Range
: -50dBm to 5dBm typical
Pulse Response Time
: Rise : 400ns, Fall : 10ns
Slope
: -25 mV/dB
14. Power Splitter/
Combiner
(Qty: 30)
Frequency range
: 2000 to 4200MHz
Isolation
: 25dB Typical
Loss
: ~6dB
Phase unbalance
: 16dB max
Amplitude
: 0.8 dB max
Items Components other than the equipments required for ATE’s(Per Set) Qty for 1 ATE set.
15. Power divider (1:2, 1:4,1:8,1:12)
Gain and phase matched L-Band and S Band
(Qty: 05)
‐37‐ 16. SFPDP Interface(PXI/standalone)
(Qty: 03) For All ATEs
17. Deutsch Connectors for adaptor boxes
732-8250-00 (Mounted in Unit) and
732-8251-00
18. Circulators:
4 Port, L band, S Band, & Ku Band
(Qty: 5, for each Band)
19. Pin Diode Switches:
(Qty: 5)
1:2, 1:4, 1:8 L , S, Ku Band, Ka Band, TTL Control
20. Phase trimmers :
VHF,UHF,L, S, Ku and Ka Band(Upto 40 Ghz)
(Qty: 10)
21. Attenuators:
L Band, S Band Programmable (TTL drive)
(Qty: 10)
22. Fixed Attenuators:
(Qty: 10)
L Band, S Band.\, Ku-Band & Ka-Band 3 dB, 6dB, 10dB
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