Evaluation Board For PulSAR 48 Lead ADCs EVAL-AD76XXEDZ Preliminary Technical Data FEATURES
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Evaluation Board For PulSAR 48 Lead ADCs Preliminary Technical Data EVAL-AD76XXEDZ www.Analog.com/PulSAR and should be consulted when utilizing this evaluation board. FEATURES Converter and Evaluation Development (EVAL-CED1Z) compatibility Versatile analog signal conditioning circuitry On-board reference, clock oscillator and buffers Buffered 14, 16 (or 18) bit parallel outputs Buffered serial port interface Ideal for DSP and data acquisition card interfaces Analog and digital prototyping area PC software for control and data analysis The evaluation board is ideal for use with Analog Devices USB based Converter and Evaluation Development EVAL-CED1Z, (CED) or as a stand-alone system. These boards are also compatible for use with the EVAL-CONTROL BRDxZ capture board and software for using this board is available on the website. Since many newer PC’s do not offer a parallel port along with overcomplicated BIOS port settings, the CED board is strongly recommended. GENERAL DESCRIPTION The EVAL-AD76XXEDZ is an evaluation board for the 48 lead AD761X, AD762X, AD763X, AD764X, AD765X, AD766X, AD767X and AD795X 14-bit, 16-bit and 18- bit PulSAR® analog to digital converter (ADC) family. These low power, successive approximation register (SAR) architecture ADCs (see ordering guide for product list ) offer very high performance with 100kSPS to 3MSPS throughput rate range with a flexible parallel or serial interface. The evaluation board is designed to demonstrate the ADC's performance and to provide an easy to understand interface for a variety of system applications. A full description of the ADCs for this board are available at The design offers the flexibility of applying external control signals and is capable of generating conversion results on parallel 14-bit, 16-bit or 18-bit wide buffered outputs. On-board components include a high precision band gap reference, (AD780, ADR431, or ADR435), reference buffers, a signal conditioning circuit with two op-amps and digital logic. The EVAL-AD76XXEDZ interfaces to the CED capture board with a 96-pin DIN connector. A 40-pin IDC connector is used for parallel output, and test points are provided for the serial port. SMB connectors are provided for the low noise analog signal source, and for an externally generated CNVST (convert start input. External CNVST Reference/Buffer 96-Pin CED/ECB Interface PulSAR ADC Analog Inputs Supplies Figure 1. Evaluation Board Rev. PrB Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 www.analog.com Fax: 781.461.3113 ©2009 Analog Devices, Inc. All rights reserved. EVAL-AD76XXCB Preliminary Technical Data TABLE OF CONTENTS FEATURES ........................................................................................ 1 GENERAL DESCRIPTION ............................................................ 1 Overview........................................................................................ 3 Conversion Control/Master Clock............................................. 3 Analog Inputs................................................................................ 3 Power Supplies and Grounding .................................................. 3 Using the Eval-AD762X/AD765X/AD766X/ AD767XCBZ as Stand-Alone................................................................................... 3 Evaluation Board Setting for Bipolar ADC Input Configurations...............................................................................4 Hardware Setup .............................................................................4 Software Installation .....................................................................5 Running the Evaluation Software ..............................................6 Setup Screen...................................................................................6 DC Testing - Histogram ...............................................................6 AC Testing ......................................................................................6 Schematics/PCB Layout............................................................... 4 Evaluation Board Schematics and Artwork............................ 16 Supplying Power for Stand-Alone use ....................................... 4 Ordering Guide .......................................................................... 22 LIST OF FIGURES Figure 1. Evaluation Board .............................................................. 1 Figure 9. Schematic, Digital........................................................... 17 Figure 2. Setup Screen .................................................................... 10 Figure 10. Schematic, Power.......................................................... 18 Figure 3. Context Help ................................................................... 11 Figure 11. Top Side Silk-Screen .................................................... 19 Figure 4. Histogram Screen ........................................................... 12 Figure 12. Top Layer....................................................................... 19 Figure 5. Summary.......................................................................... 13 Figure 13. Ground Layer................................................................ 20 Figure 6. FFT Spectrum ................................................................. 14 Figure 14. Shield Layer................................................................... 20 Figure 7. Oscilloscope .................................................................... 15 Figure 15. Bottom Side Layer ........................................................ 21 Figure 8. Schematic, Analog .......................................................... 16 Figure 16. Bottom Side Silk-Screen.............................................. 21 LIST OF TABLES Table 1. CNVST Generation, Analog Input Range....................... 7 Table 2. Jumper Description............................................................ 8 Table 5.Test Points .............................................................................9 Table 6. Bill of Materials for the Connectors .............................. 22 Table 3. S16 - Configuration Select Switch Description.............. 8 Table 4. S35 - Configuration Select Switch Description.............. 8 Rev. PrB | Page 2 of 23 Preliminary Technical Data EVAL-AD76XXEDZ OVERVIEW ANALOG INPUTS Figure 1 shows the EVAL-AD76XXEDZ evaluation board. When used in stand-alone mode or in conjunction with the EVAL-CED1Z, the gate array, U10, provides the necessary control signals for conversion and buffers the ADC data. The evaluation board is a flexible design that enables the user to choose among many different board configurations, analog signal conditioning, reference, and different modes of conversion data. The analog inputs amplifier circuitry (U6, U7 and discretes) allows configuration changes such as positive or negative gain, input range scaling, filtering, addition of a DC component, use of different op-amp and supplies depending on the ADC. The analog input amplifiers are set as unity gain buffers at the factory. The supplies are selectable with solder pads and are set for the ±12V range. CONVERSION CONTROL/MASTER CLOCK Conversion start (CNVST) controls the sample rate of the ADC and is the only input needed for conversion; all SAR timing is generated internally. CNVST is generated either by the gate array or externally via J3 (SMB) and setting JP22 in the external (EXT) position. The evaluation board is factory configured for the CNVST range shown in Table 1. Externally generated CNVST should have very low jitter and sharp edges for the maximum dynamic performance of the part. Since CNVST jitter usually results in poor SNR performance, it is recommended to use the on-board CNVST generation whenever possible. The master clock (MCLK) source for the gate array is generated from the CED capture board or from U12, the 40MHz local oscillator selectable when using the accompanying software. The range for CNVST in Table 1is a ratio generated from this master clock. In standalone mode, other clock frequencies can be used to change the gate array generated CNVST by this ratio. However, other timings will be affected – namely the slave serial clock (SCLK) interface. In serial slave mode, SCLK = MCLK. While the ADC is converting, activity on the BUSY pin turns on the LED, D2. Additionally, the BUSY signal can be monitored test point TP1. Buffered conversion data (BD) is available at U10 on the output bus BD[0:15] on the 40-pin IDC connector P2, and on the 96-pin connector P3. When operating with the CED, data is transferred using a 16 bit bus and corresponding word and byte modes selectable with the software. For the 18 bit converters two consecutive 16 bit words are read, however, the ADC data is still read into the gate array as 18 bits. Additionally, BD is updated on the falling edge of BBUSY on P3-C17, and on the rising edge of DBUSY on P2-33. When either parallel or serial reading mode of the ADC is used, data is available on this parallel bus. When using Serial Mode, serial data is available at T3, T4, T5, and T6 (SDOUT, SCLK, SYNC and RDERROR) and buffered serial data is output on TP17, TP18, and TP19 (SCLK, SYNC, and SDOUT). When using Slave Serial Mode, the external serial clock SCLK applied to the ADC is the MCLK, U12, frequency (40MHz). Refer to the device specific datasheet for full details of the interface modes. Table 1 shows the analog input range for the available evaluation boards. The default configuration for the single ended (SE) unipolar ADCs sets U6 at mid-scale from the voltage divider (VCM * R6/(R6+R7)) and U7 at mid-scale from the voltage divider (VCM * R29(R29+R60)) for the differential unipolar ADCs. For the bipolar devices (AD7663, AD665, AD7671), the buffer output is centered at 0V (mid-scale) as these boards are configured for the +/-5V input range. Note the input impedance is 1k ohm (R6, R29 =1k ohm to GND). To use another input range, the solder pads S[7:1] need to be reconfigured. These input configurations allows a transition noise test (histogram) without any other equipment. In some applications, it is desired to use a bipolar or wider analog input range, for instance, ± 10V, ± 5V, ± 2.5V, or 0 to -5V. For ADCs which do not use these input ranges directly, simple modifications of the input driver circuitry can be made without any performance degradation. Refer to the datasheet under the Application Hints section for component values or to application note AN594 on the product web page for other input ranges. Note that the AD7663, AD7665, and AD7671 evaluation boards are factory configured for the +/-5V range. For different ranges, the board needs appropriate solder pad configurations. For dynamic performance, an FFT test can be done by applying a very low distortion AC source. POWER SUPPLIES AND GROUNDING The evaluation board ground plane is separated into two sections: a plane for the digital interface circuitry and an analog plane for the analog input and external reference circuitry. To attain high resolution performance, the board was designed to ensure that all digital ground return paths do not cross the analog ground return paths by connecting the planes together directly under the converter. Power is supplied to the board through P3 when using with the EVAL-CED1Z USING THE EVAL-AD762X/AD765X/AD766X/ AD767XEDZ AS STAND-ALONE Using the evaluation board as stand-alone does not require the CED nor does it require use of the accompanied software. When the CONTROL input to the gate array is LOW, which is pulled down by default, the gate array provides the necessary signals for conversion and buffers the conversion data. Rev. PrB | Page 3 of 23 EVAL-AD76XXEDZ Preliminary Technical Data In stand-alone mode, the gate arrays flexible logic buffers the ADC data according to the read data mode configuration (word or byte). In parallel reading mode the board is configured for continuous reading since CS and RD are always driven LOW by the gate array. Thus, the digital bus is not tri-stated in this mode of operation and BD[0:15] will continuously be updated after a new conversion. BD[0:15] is available on P2 after BUSY goes HIGH. Note that with the 18 bit devices the full 18 bits of data BD[-2:15] are output directly on P2 since the evaluation board is not limited to 16 bit wide transfers in stand-alone operation. When either parallel or serial reading mode, the data is available on this parallel bus. Refer to Figure 9 to obtain the data output pins on P2. Configuration Switches The evaluation board is configurable for the different operating modes with 16 positions on the configuration select switches, S16 and S35. A description of each switch setting and jumper position is listed in Figure 9 and the available test points are listed in Table 5. Note that the switches in the ON position define a logic HIGH level (pulled up with 10kΩ,) and that the switches are active only in stand-alone mode. For all interface modes, S16 and S35 allows the selection of: Warp, Normal or Impulse mode conversions (where applicable) Binary or 2s complement data output Reading during or after conversion Resetting the ADC ADC power-down Internal Reference and Buffer power-down (where applicable) In parallel reading mode, s16 allows the selection of: Byte swapping for 8 bit interfacing (LSByte with MSByte) 18-bit, 16-bit and 8-bit interfacing (for 18-bit converters) In serial reading mode, the default settings are Master Read during Conversion Mode using the internal ADC serial clock. Serial data is available at T3, T4, T5 and T6 for SDOUT, SCLK, SYNC and RDERROR respectively. Buffered serial data is output on the three test points TP17, TP18 and TP19 for SCLK, SYNC, and SDOUT respectively. For serial reading mode, S16 allows the selection of: Choice of inverting SCLK and SYNC Choice of using internal or external (slave mode) SCLK SCHEMATICS/PCB LAYOUT The EVAL-AD76XXEDZ is a 4-layer board carefully laid out and tested to demonstrate the specific high accuracy performance of the PulSAR ADC. Figure 8 to Figure 10 show the schematics of the evaluation board. The printed circuit layouts of the board are given in Figure 11 - Figure 16. Note these layouts are not to scale. Top side silk-screen - Figure 11 Top side layer - Figure 12 Ground layer - Figure 13 Shield layer - Figure 14 Bottom side layer - Figure 15 Bottom side silk-screen - Figure 16 SUPPLYING POWER FOR STAND-ALONE USE Power needs to be supplied through the two power supply blocks SJ1 and SJ2. Linear supplies are recommended. SJ1 is the analog supply for the ADC (AVDD), front end op amps and reference circuitry. SJ2 is the digital supply for the ADC (DVDD, OVDD) and gate array. The supplies to the device are configurable through the power supply jumpers shown in . In most applications four supplies are required; ±12V and +5V for analog, and +5V for digital. On board regulators, where applicable, are used to reduce the operating voltages to the correct levels. The analog and digital supplies can be from the same source however, R27 (typically 20Ω) is required from AVDD to DVDD. In this configuration, JP9, DVDD selection, should be left open. Furthermore, the OVDD (ADC digital output supply) may need to be brought up after the analog +5V supply. See datasheet for details. EVALUATION BOARD SETTING FOR BIPOLAR ADC INPUT CONFIGURATIONS The AD7610, AD7612, AD7631, AD7634, AD7663, AD7665, AD7671, AD7951 and AD7952 can use both unipolar and bipolar ranges. The available options are +/-10V, +/-5V, +/-2.5V, 0 to 10V, 0 to 5V and 0 to 2.5V (depending on the ADC). For the AD7663, AD7665 and AD7671 the evaluation board is set for the ±5V bipolar input range since these ADCs input ranges are hardware pin strapped. Simple modifications to these evaluation boards can be made to accommodate the different input ranges by changing the INA-IND inputs with the available solder pads. iCMOS ADCs For the AD7610, AD7612, AD7631 AD7634 and AD7951, the evaluation board can use all input ranges since the input range is controlled by software (or S16 DIP switches in stand-alone mode). For operating in unipolar mode for any of the bipolar evaluation boards it is recommended to use the voltage divider consisting of (VCM * R6/(R6+R7)) and (VCM * R29/(R29+R60)). This allows a transition noise test without any additional equipment. HARDWARE SETUP Using EVAL-CED1Z Capture Board • • • • • • • Rev. PrB | Page 4 of 23 EVAL-AD76XXEDZ PulSAR ADC evaluation board EVAL-CED1Z Enclosed World compatible 7V DC supply Enclosed USB to mini USB cable DC source (low noise for checking different input ranges) AC source (low distortion) Band pass filter suitable for 16 or 18 bit testing (value based on signal frequency) Preliminary Technical Data EVAL-AD76XXEDZ • PC operating Windows XP. Proceed to the Software Installation section to install the software. Note: The EVAL-CED1Z board must not be connected to the PC’s USB port until the Software is installed. The 7V DC supply can be connected however to check the board has power (green LED lit). SOFTWARE INSTALLATION It is recommended to close all Windows’ applications prior to installing the software. System Requirements • PC operating Windows XP. • USB 2.0 (for CED board) • Administrator privileges CD-ROM –Navigate to Software\CED Version x.x, double click on setup.exe and follow the instructions on the screen. If another version of Analog Devices PulSAR Evaluation Software is present, it may be necessary to remove this. To remove, click on the Windows “Start” button, select “Control Panel” and “Add or Remove Programs”. When the list populates, navigate to Analog Devices High Resolution sampling ADC’s Evaluation Software or PulSAR Evaluation Software and select Remove. When installed properly, Windows displays the following. Website Download The software versions are also available from the Analog Devices PulSAR Analog to Digital Converter Evaluation Kit page. After downloading the software, it is recommended to use the WinZip “Extract” function to extract all of the necessary components as opposed to just clicking on setup.exe in the zipped file. After extracting, click on seteup.exe in the folder created during the extraction and follow the instructions on the screen. If another version exists, it may be necessary to remove as detailed in the above CD-ROM section. USB Drivers The software will also install the necessary USB drivers. After installing the software, power up the CED board and connect to the PC USB 2.0 port. The Windows “Found New Hardware” Wizard will display. Click on Next to install the drivers automatically. On some PCs, the Found New hardware Wizard may show up again and if so follow the same procedure to install it properly. The “Device Manager” can be used to verify that the driver was installed successfully. Troubleshooting the Install If the driver was not installed successfully the device manager will display a question mark for “Other devices” as Windows does not recognize the CED1Z board. Rev. PrB | Page 5 of 23 EVAL-AD76XXEDZ Preliminary Technical Data • Histogram for determining code transition noise (DC) • Fast Fourier transforms (FFT) for signal to noise ratio (SNR), SNR and distortion (SINAD), total harmonic distortion (THD) and spurious free dynamic range (SFDR) The software is located at C:\Program Files\Analog Devices\ PulSAR ADC Evaluation Software\Eval PulSAR CED.exe. A shortcut is also added to the Windows “Start” menu under “Analog Devices PulSAR ADC Evaluation Software”, “Eval PulSAR CED”. To run the software, select the program from either location. SETUP SCREEN Figure 2 is the setup screen where ADC device selection, test type, input voltage range, sample rate and number of samples are selected. DC TESTING - HISTOGRAM Figure 4 shows a screen shot for the histogram screen. This tests the ADC for the code distribution for DC input and computes the mean and standard deviation, or transition noise of the converter and displays the results. Raw data is captured and passed to the PC for statistical computations. To perform a histogram test, select “Histogram” from the test selection window and click on the “Start” radio button. Note: a histogram test can be performed without an external source since the evaluation board has a buffered VREF/2 source at the ADC input for unipolar parts and at 0V for bipolar devices. To test other DC values, apply a source to the J1/J2 inputs. It is advised to filter the signal to make the DC source noise compatible with that of the ADC. C26/C41 provide this filtering. The “USB Device” can be opened to view it’s uninstalled properties. AC TESTING This is usually the case if the software and drivers were installed by a user without administrator privileges. If so, log on as an administrator with full privileges and reinstall the software. RUNNING THE EVALUATION SOFTWARE The evaluation board includes software for analyzing the AD7682, AD7689, AD7699 and AD7949. The EVAL-CED1Z is required when using the software. The software is used to perform the following tests: Figure 6 is a screen shot of the fast Fourier transform, FFT. This tests the traditional AC characteristics of the converter and displays an FFT of the result. As in the histogram test, raw data is captured and passed to the PC where the FFT is performed thus displaying SNR, SINAD, THD and SFDR. The data can also be displayed in the time domain. To perform an AC test, apply a sinusoidal signal to the evaluation board at the SMB inputs J1 for IN+ and J2 for IN-. Low distortion, better than 100dB, is required to allow true evaluation of the part. One possibility is to filter the input signal from the AC source. There is no suggested bandpass filter but consideration should be taken in the choice. Furthermore, if using a low frequency bandpass filter when the full-scale input range is more than a few Vpp, it is recommended to use the on board amplifiers to amplify the signal, thus preventing the filter from distorting the input signal. Rev. PrB | Page 6 of 23 Preliminary Technical Data EVAL-AD76XXEDZ Table 1. CNVST Generation, Analog Input Range Part AD7621 AD7622 AD7623 AD7641 AD7643 AD7650 AD7651 AD7652 AD7653 AD7660 AD7661 AD7663 AD7664 AD7665 AD7666 AD7667 AD7671 AD7674 AD7675 AD7676 AD7677 AD7678 AD7679 1 Resolution (bits) 16 16 16 18 18 16 16 16 16 16 16 16 16 16 16 16 16 18 16 16 16 18 18 Sample Rate Analog Input Range Analog Input Type 3 MSPS 2 MSPS 1.33 MSPS 2 MSPS 1.25 MSPS 100 kSPS 100 kSPS 500 kSPS 1 MSPS 100 kSPS 100 kSPS 250 kSPS 570 kSPS 570 kSPS 500 kSPS 1 MSPS 1 MSPS 800KSPS 100 kSpS 500 kSPS 1 MSPS 100KSPS 571KSPS 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 2.5V -5V to +5V1 0 to 2.5V -5V to +5V 0 to 2.5V 0 to 2.5V -5V to +5V 0 to 5V 0 to 2.5V 0 to 2.5V 0 to 2.5V 0 to 5V 0 to 5V Diff, Unipolar Diff, Unipolar Diff, Unipolar Diff, Unipolar Diff, Unipolar Single Ended, Unipolar Single Ended, Unipolar Single Ended, Unipolar Single Ended, Unipolar Single Ended, Unipolar Single Ended, Unipolar Single Ended, Bipolar Single Ended, Unipolar Single Ended, Bipolar Single Ended, Unipolar Single Ended, Unipolar Single Ended, Bipolar Diff, Unipolar Single Ended, Unipolar Single Ended, Unipolar Single Ended, Unipolar Diff, Unipolar Diff, Unipolar Available Input Ranges are 0 to 2.5V, 0 to 5V, 0 to 10V, +/- 2.5V, +/-5V, and +/- 10V. however the board is factory configured for the +/-5V input range. Modify S1 to S7 accordingly (see schematics and datasheets) for different input range configuration. Rev. PrB | Page 7 of 23 EVAL-AD76XXEDZ Preliminary Technical Data Table 2. Jumper Description 1 Jumper Name JP1, JP2 BUFF Default Position BUFF JP3 VDRV- -12V JP4 REFS REF JP6 OVDD 3.3V JP7 VREF+ +12V JP8 VDRV+ +12V JP9 DVDD VDIG/2.51 JP19 JP20 AVDD REFB +5V/2.51 BUF JP21 VIO 3.3V JP22 CNVST INT Function Buffer amplifier: BUFF = use op amps to buffer analog input. NO BUFF = direct input from J1, J2 (SMB). Buffer amplifier negative supply: Selection of -12V, -5V or GND when using EVAL-CED1Z or voltages on SJ1 in stand alone mode. Reference selection: REF = use on board reference output for ADC reference. VDD = use analog supply (AVDD) for ADC reference. ADC digital output supply voltage: Selection of 2.5V, 3.3V and VDIG. VDIG = +5V when using EVAL-CED1Z or voltage on SJ2 in stand-alone mode. Reference circuit positive supply: Selection of +12V, +5V or AVDD when using EVAL-CED1Z or voltages on SJ1 in stand alone mode. Buffer amplifier positive supply: Selection of +12V, +5V or AVDD when using EVAL-CED1Z or voltages on SJ1 in stand alone mode. ADC digital supply voltage: Selection of +2.5V or VDIG (+5V) when using EVAL-CED1Z or voltage on SJ2 in stand-alone mode. ADC analog supply voltage: Selection of +2.5V, +5V or EXT when using EVAL-CED1Z Reference buffer: BUFF = use U2 to buffer or amplify reference source. NO BUFF = use reference directly into ADC. Gate array I/O voltage: Selection of 3.3V or OVDD. Note: gate array will be damaged if >3.3V (ie. when using OVDD = VDIG). CNVST source: INT = use gate array to generate CNVST. EXT = use external source into J3, SMB for CNVST. For AD7621/22/23//25/41/43 these are set to +2.5V. Note that setting these to +5V will permanently destruct the ADC. Table 3. S16 - Configuration Select Switch Description Note: (OFF = LOW, ON = HIGH) Position Name 1 WARP Default Position LOW 2 IMPULSE LOW 3 4 5 BIP TEN A0/M0 LOW LOW LOW 6 BYTE/M1 LOW 7 8 9 OB/2C SER/PAR EXT/INT HIGH LOW LOW 10 INVSYNC LOW 11 INVSCLK LOW 12 RDC LOW Function Conversion mode selection: Used in conjunction with IMPULSE. When HIGH with IMPULSE= LOW, the fastest (Warp) mode is used for maximum throughput. When LOW and IMPULSE = LOW, Normal mode is used. Conversion mode selection: Used in conjunction with WARP. When HIGH with WARP = LOW, a reduced power mode is used in which the power consumption is proportional to the throughput rate. For future use. For future use. A0, input Mux selection: Used for AD7654/AD7655 (refer to datasheet). M0, data output interface selection: Used along with M1 for 18-bit ADCs. BYTESWAP, used for 8-bit interface mode on 16-bit ADCs: MSByte is swapped with LSByte on 8 data lines. M1, data output interface selection: Used along with M0 for 18-bit ADCs. Data output select: LOW = Use 2’s complement output. HIGH = Straight binary output. Data output interface select: LOW = Parallel interface. HIGH = Serial interface. Serial clock source select: LOW = Use ADC internal serial clock, SCLK is an output. HIGH= Use external clock, which is MCLK (40 MHz) and SCLK is an input. Not used in parallel reading mode. Serial sync (SYNC) active state: LOW = SYNC is active HIGH. HIGH = SYNC is active LOW. Used only for Master mode (internal SCLK). Not used in parallel reading mode. Serial clock (SCLK) active edge: LOW = Use SCLK falling edge. HIGH = Use SCLK rising edge. Active in all serial modes. Not used in parallel reading mode. Read during convert: LOW = Read data after conversion (BUSY = LOW). HIGH = Read data during conversions (BUSY = HIGH). Used in both parallel and serial interface modes. Table 4. S35 - Configuration Select Switch Description Note: (OFF = LOW, ON = HIGH) Rev. PrB | Page 8 of 23 Preliminary Technical Data Position Name 1 2 RESET PD Default Position LOW LOW 3 PDBUF LOW 4 PDREF LOW EVAL-AD76XXEDZ Function Reset ADC: LOW = Enables the converter. HIGH = Abort conversion (if any). Power down: LOW = Enables the converter . HIGH = Powers down the converter. Power consumption is reduced to a minimum after the current conversion. Internal reference buffer power down: LOW = Enable on chip buffer. HIGH = Power down internal buffer. Internal reference power down: LOW = Enable on chip reference. HIGH = Power down internal reference. Note that when using the on chip reference, the buffer also needs to be enabled (PDREF = PDBUF = HIGH). Table 5.Test Points Test Point TP1 TP2 TP3 TP4 TP5 TP7 TP8 TP9 TP10 TP11 TP12 TP13 TP14 TP15 TP16 TP17 TP18 TP19 TP20 Available Signal BUSY A0/M0 SIG+ AGND REF DGND CNVST AGND CS RD OVDD DVDD AVDD AGND SIGSCLK SYNC SDOUT TEMP Type Description Output Input Input GND Input/Output GND Input GND Input Input Power Power Power GND Input Input/Output Output Output Output TP22 REFIN Input/Output TP23 T3 T4 T5 T6 BVDD SDOUT SCLK SYNC RDERROR Output Output Input/Output Output Output BUSY signal. Same as S16, position 5 Analog +input. Analog ground close to SIG+. Reference input. Output for devices with on-chip reference. Digital ground near SJ2. CNVST signal. Analog ground close to REF. CS, chip select signal. RD, read signal. Digital output supply. Digital core supply. Analog supply. Analog ground close to SIG-. Analog –input for differential parts. Buffered serial clock. Buffered serial sync. Buffered serial data. TEMP, for ADC with internal reference. Outputs temperature dependant voltage (approx. 300mV with TA = 25°C). For ADCs with internal reference, REFBUFIN can be used to connect external reference into the reference buffer input when PDBUF = LOW and PDREF = HIGH. With the internal reference (and buffer) enabled, this pin will produce the internal bandgap reference voltage. Internal reference bandgap supply. Connected to AVDD via s19. Direct ADC serial data. Direct ADC serial clock. Direct ADC serial SYNC. Direct ADC serial read error. Rev. PrB | Page 9 of 23 EVAL-AD76XXEDZ Preliminary Technical Data 1 3 4 5 Figure 2. Setup Screen 2. The part to be evaluated is selected here. Coding – Another subset to the digital interface mode, this can be used to select straight binary or 2’s complement output. Note the time domain chart and data output (F5) plots and saves data in straight binary. 3. The controls are used to set: Reset – Resets the ADC. Sample Frequency – Enter in kHz Units can be used such as 3k (case sensitive) for 3,000,000 Hz or 3MSPS. PD, PDREF, PDBUF – These can be used to power down the ADC, internal reference and internal reference buffer. Clock Source - Selections between control (capture) board or evaluation board. 4. These controls are used for saving, printing, help, etc. and are also accessed in the File menu. Mode – This selects the conversion mode of operation. Some ADCs have different modes Warp, Normal, and Impulse. Save (F5): type – LabView config, allows the current configuration to be saved to a filename.dat file. Useful when changing many of the default controls. To load the saved configuration, use the Load Previous Configuration. 1. The arrow is used to start the software. When running is displayed. Cnv Mode – Conversion mode; this selects between continuous (Cont.) or Burst conversion modes. In continuous mode, the ADC is continuously converting. In Burst mode, the ADC is not converting (sample clock held in inactive state) and the conversions begin once the “Single Capture” or “Continuous Capture” buttons have been selected. Interface mode – This selects the digital interface to the onboard FPGA. Byteswap – A subset of the digital interface mode, this is used to demonstrate byte-wide transfers to the FPGA. Type – Html, saves the current screen shot to an Html file. Type – Spreadsheet, saves the current data displayed in the chart in a tab delimited spreadsheet. Raw ADC Data is time domain in Codes, FFT or Decimated is in dB. can also be 5. Stop (F10) is used to stops the software. The used to stop the software. RESET is used to reset the CED or ECB capture boards. Rev. PrB | Page 10 of 23 Preliminary Technical Data EVAL-AD76XXEDZ 1 Figure 3. Context Help 2 1. To use the on-screen help. Select Help, Show Context Help or click the Help (F1). An example of the Context Help is shown above for the Sample Frequency. Placing the curser on most screen items displays useful help for the particular control or displayed unit. , are used to set axes properties such as format, precision, color, etc. Right mouse click to change to Hexadecimal, number of digits, etc. Displays the cursor. 2. These controls are used for axes and zooming panning. Is used For zooming in and out. Locks the graph axis to automatically fit the data. Uses last axis set by user. automatic values. , Is used for panning. rescale the axes to the Is used to set various graph properties such as graph type, colors, lines, etc. Rev. PrB | Page 11 of 23 EVAL-AD76XXEDZ Preliminary Technical Data 1 Figure 4. Histogram Screen 3 2 1. These radio buttons are used to perform a Single Capture or Continuous Capture of data set in the # of Samples field. The results are displayed in the chart. Note that the results can be displayed as: Or an (time domain) 2., 3.These display the statistics for the X and Y-axes, respectively. A Rev. PrB | Page 12 of 23 Preliminary Technical Data EVAL-AD76XXEDZ Figure 5. Summary The charts can be displayed together when the tab is selected. Rev. PrB | Page 13 of 23 EVAL-AD76XXEDZ Preliminary Technical Data 1 1 3 Figure 6. FFT Spectrum 2 1. Displays the FFT when the Spectrum chart is selected 2., 3. Display the data for the X and Y-axes, respectively. . Rev. PrB | Page 14 of 23 Preliminary Technical Data EVAL-AD76XXEDZ 1 Figure 7. Oscilloscope 1. Time domain data can be viewed with the oscilloscope also. Rev. PrB | Page 15 of 23 A B C +VA -VS GND VREF+ 1 TP15 AGND S32 DAC+ GND J2 AIN- AIN- S33 DAC- GND J1 AIN+ AIN+ DAC- TP4 GND DAC+ +VA -VS GND VREF+ C52 .1uF R7 590 R29 590 0.0 GND C41 R61 49.9 R34 R42 49.9 R43 C36 R44 GND GND R59 C26 VCMT IN 3 2 U6A U7A 2 0.0 R90 10pF-NPO 0.0 R91 10pF-NPO C35 VDRV- .1uF GND C42 5 6 GND VDRV+ C37 .1uF VDRV- C34 GND C6 1uF 1 VDRV- .1uF GND C22 5 6 .1uF C20 GND VDRV+ AD8021 3 2 VDRV+ C64 5 6 AD158X OUT C29 .1uF TRIM VOUT AD8021 49.9 0 0.0 VCMT R35 R6 590 U5A R31 R3 C19 TEMP R5 R1 R2 GND GND 590 R60 AIN- VCM VCM C53 .1uF AIN+ C28 .1uF 3 ADR43X GND 3 GND 2 VREF+ 2 +VIN GND 2.5/3v 4 8 REF BUF JP2 JP1 JP4 REFS NOBUF BUF NOBUF VDD A AVDD REFOUT NOTE: R9 C59 SIG- SIG+ SIG- SIG+ 3 TP16 SIG- R97 0.0 R96 0.0 TP3 SIG+ C38 0.0 R45 0.0 R46 3 2 C9 1uF 10K R37 ANY PASSIVE COMPONENTS WITHOUT VALUE ARE NOT POPULATED 10K R4 GND R10 C60 15 1 BUF C39 C40 GND -VS S17 S1 +VS S3 S21 VCM S2 C25 .1uF VREF+ AGND TP9 AD8032AR GND R47 15 R48 U2A 8 4 4 S5 S4 A S20 BVDD TP23 S15 GND S8 TP22 VBG 1uF C31B REF REF GND S7 S6 C31T NOBUF BUF JP20 REFB S14 S10 TEMP S9 5 C55 C13 S34 46 44 45 43 42 41 40 39 38 37 OVDD C9B .1uF DVDD C5B .1uF DVDD C56 REFIN/INA1 INA2 INAN/TEMP AVDD GND GND AD76XX IN_D/IN+ IN_C IN_B/INB2 IN_A/INBN INGND/IN-/INB1 REFGND REF U1 GND GND IN_D IN_C IN_B IN_A INGND S31 GND VCM S13 C8 10uF TP5 REF S12 7 TP20 TEMP S19 TEMP S18 S11 AVDD S30 U2B REFOUT 47uF C32B 5 6 DVDD TP13 DVDD AVDD TP14 AVDD AVDD 18 OVDD C27 .1uF 5 19 DVDD D 4 2 AVDD U5B 3 1 C5T .1uF C9T .1uF AGND 2 OVDD 17 D0 D1 D2 D3 D4 D5 D6 D7 D8 D9 D10 D11 D12 D13 D14 D15 3 A0 31 RD 32 CS 47 36 30 48 8-Feb-2005 A0 RD CS PDRT0 T0PDR T1/EOC PDBT1 6 Rev. : J ANALOG EVAL-AD76XXCB GND D[0..15] 6 35 CNVST CNVST 29 BUSY BUSY 9 10 11 12 13 14 15 16 21 22 23 24 25 26 27 28 TP12 OVDD OB/2C WARP IMPULSE IMPULSE SER/PAR SER/PAR RESET RESET BYTE/M1 PD PD A0 RD CS PDREF/T0 T0/PDREF T1/EOC PDBUF/T1 CNVST BUSY C7B .1uF GND OVDD D0 D1 D2/DIVSCLK(0) D3/DIVSCLK(1) D4/EXT/INT D5/INVSYNC D6/INVSCLK D7/RDC/SDIN D8/SDOUT D9/SCLK D10/SYNC D11/RDERROR D12 D13 D14 D15 DGND NOTE: EITHER U5A OR U5B IS USED AT A TIME 7 4 20 DGND PD BYTESWAP RESET SER/PAR IMPULSE WARP OB/2C A/B 1 7 Rev. PrB | Page 16 of 23 34 4 33 8 7 6 5 Figure 8. Schematic, Analog 4 C7T .1uF M.M D[0..15] A B C D EVAL-AD76XXEDZ Preliminary Technical Data EVALUATION BOARD SCHEMATICS AND ARTWORK A B C D GND P3C P3B GND GND B25 B24 B23 B22 B21 A29 A26 A25 A24 A23 A32 B32 C32 A31 B31 C31 C30 A8 B8 C8 A30 A4 A12 A16 A20 B4 B12 B16 B20 C4 C12 C16 C20 B26 B27 B28 B29 B30 C21 C22 C23 C24 C25 C26 C29 A21 A22 J3 CNVSTIN CNVOUT 1 GND PDREF PDBUF PD RESET BYTE/M1 A0/M0 TEN BIP IMPULSE -12V VDIG +12V -VA +VA R28 100 EXT INT WARP A JP22 CNV SEL R77 1K 10K R99 1K R101 10K R98 1K R100 10K R93 1K R89 10K R92 R88 1K 10K 1K R81 10K R76 1K R22 10K R71 1K R21 10K R70 1K R20 10K R69 1K R19 10K R33 R15 -12V VDIG +12V -VA +VA R30 100 R36 1M 3.3V 4 3 2 1 6 5 4 3 2 1 S35D S35C S35B S35A S16F S16E S16D S16C S16B S16A R83 TP8 CNVST 5 6 7 8 19 20 21 22 23 24 PDREF PDBUF PD RESET BYTE/M1 A0/M0 TEN BIPOLAR IMPULSE WARP VIO JP11 R85 10K 3.3V CNVST VIO 2 RDC INVSCLK INVSYNC EXT/ INT SER/PAR OB/ 2C VIO CNVST 2 13 14 15 16 17 18 S16L S16K S16J S16I S16H S16G 12 11 10 9 8 7 1K 10K R79 10K R78 1K R14 1K R16 10K R75 1K R17 10K R74 1K R13 1K R12 10K R73 10K R72 R11 PDRT0 A0 GND C57 BUSY RD CS GND TP2 A0 TP10 CS D7 D6 D5 D4 SER/PAR OB/2C PDBT1 T1/EOC T0PDR GND TP21 GND D[0..15] VIO S29 T1 S28 S23 S22 3 100 R54 10K JP14 S26 TEMP GND R55 10K 61 60 59 TEMP 41 PDBUF 62 TEN BIP PDREF 58 26 25 T1 24 T2 23 22 21 16 15 T3 14 T4 12 T5 11 T6 10 144 143 142 141 13 140 139 138 137 R68 134 49.9 2 39 BYTE/M1 RESET 136 37 WARP OB/2C 38 35 SER/PAR 36 IMPULSE 135 PD A0/M0 57 D0 D1 D2 D3 D4 D5 D6 D7 D8 D9 D10 D11 D12 D13 D14 D15 D9 10k GND R32 R82 S25 S24 BYTE/M1 RESET WARP OB/2C SER/PAR IMPULSE PD CNVOUT PDRT0 A0 49.9 R86 TP11 TP1 RD BUSY S27 D[0..15] 3 TEMP PDBUF EPF6010ATC144-3 TEST1_OUT EOC TEST0 PDREF D0 D1 D2 D3 D4 D5 D6 D7 D8 D9 D10 D11 D12 D13 D14 D15 SCLKIN BUSY RD CS CNVST CNVSTOUTB CNVSTOUT BYTE RESET WARP OB/2C SER/PAR IMPULSE PD A0 U10A 4 DSPCLK MCLK SCLK0 TFS0 RFS0 DT0 DR0 MODE0 AD2 AD1 AD0 MODE1 MODE2 MODE3 BWR BRD RESETD RESETS CONTROL BCS FSYNC BBUSY DBUSY ADCOK BD-1 BD-2 BD0 BD1 BD2 BD3 BD4 BD5 BD6 BD7 BD8 BD9 BD10 BD11 BD12 BD13 BD14 BD15 CONF_D STATUS CONFIG CE MSEL DCLK DATA 4 71 69 116 118 119 121 122 47 95 96 93 46 45 44 114 113 86 43 130 111 131 85 40 49 107 108 129 124 123 120 117 115 112 110 109 94 87 84 72 81 82 73 105 56 53 4 33 128 125 GND R51 10K 10K 10K C47 10K 10K 10K 0 R49 TP19 SDOUT TP18 SYNC TP17 SCLK R65 R64 R63 10K R66 10K R58 10K R57 10K R62 GND DSPCLK SCLK TFS0 SYNC SDIN SDOUT M0 AD2 AD1 AD0 M1 M2 M3 BWR BRD 1K U11 1 3 R80 100 6 5 3 4 VDIG U12 GND 3.3V GND SYNC-FFT TP6 GND OE CS CASC OUT EPC1441 3.3V DCLK DATA 3.3V 3.3V R67 10K RESETS R56 RESETD D2 2 1 8 7 R41 CONTROLR52 BCS FSYNC BBUSY DBUSY ADCOK BD-1 BD-2 BD0 BD1 BD2 BD3 BD4 BD5 BD6 BD7 BD8 BD9 BD10 BD11 BD12 BD13 BD14 BD15 CONF_D STATUS CONFIG DCLK DATA 3.3V R38 1K VIO BD15 BD14 BD13 BD12 BD11 BD10 BD9 BD8 BD7 BD6 BD5 BD4 BD3 BD2 BD1 BD0 DBUSY BD-1 BD-2 BCS 5 1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 R40 1K 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 3.3V P2 R39 1K GND VDIG 7 19 32 55 78 91 104 127 6 31 77 103 EPF6010ATC144 C30 .1uF 2 4 5 GND 3.3V GND TP7 GND U10B 126 5 18 30 54 76 90 102 Rev. PrB | Page 17 of 23 C17 .1uF VIO VIO VIO VIO VIO VIO VIO VIO 3.3V 3.3V 3.3V 3.3V Figure 9. Schematic, Digital GND GND GND GND GND GND GND GND 1 GND C21 .1uF C16 .1uF .1uF C18 GND 3.3V .1uF C4 C24 .1uF C3 .1uF DIGITAL 6 Rev. : J .1uF C11 GND 3.3V C19 C18 B18 A18 B17 B15 B14 B13 B11 B10 B9 B7 B6 B5 B3 B2 C14 A14 C15 C10 C17 A9 C9 A17 B1 A5 A6 A19 C5 C7 C6 A27 C27 VIO GND .1uF C12 BD15 BD14 BD13 BD12 BD11 BD10 BD9 BD8 BD7 BD6 BD5 BD4 BD3 BD2 BD1 BD0 AD2 AD1 AD0 BCS BBUSY BRD BWR RESETD CONTROL SDIN TFS0 DSPCLK SDOUT SCLK SYNC DAC+ DAC+ DACDAC- .1uF C10 EVAL-AD76XXCB .1uF C7 8-Feb-2005 .1uF C5 C23 .1uF GND R53 10K 3.3V 6 M.M P3A A B C D Preliminary Technical Data EVAL-AD76XXEDZ A B C 1 GND VDIG VDIG SJ2 C1 10uF VDIG C32 1uF GND GND VDIG C45 1uF 4 7 8 4 7 8 NC IN IN 2 FB OUT FB OUT OUT U4 ADP3334ARM NC IN OUT U5 ADP3334ARM IN 2 GND SD 5 6 GND SD 5 6 Rev. PrB | Page 18 of 23 3 2 1 3 2 1 C46 1uF C33 1uF GND R26 78.7K R23 140K 3.3V GND R24 94.5k R8 106.1k 2.5V VDIG VDIG 3.3V 1 2 1 2 3 JP9 JP6 3 4 C48 10uF 3 GND C49 10uF DVDD GND 3 R27 AVDD 3.3V C43 1uF D1 GND +VA JP21 R84 0 OVDD VIO VIO 4 7 8 GND NC IN IN FB OUT OUT U8 ADP3334ARM C14 10uF GND SD Figure 10. Schematic, Power 5 6 D 1 3 2 1 4 GND EXT +12V +5V -5V -12V 4 +12V EXT 4 5 GND R25 94.5k R18 106.1k +VA 3 GND -VA 2 6 -12V 1 C44 1uF SJ1 3 2 1 2 EXT 1 +12V GND -VA -12V JP10 JP5 5 3 4 5 JP3 C31 10uF 3 2 1 GND +VS GND -VS JP19 JP7 GND JP8 1 2 3 -VS C2 10uF -VS VDIG VIO OVDD DVDD AVDD GND VREF+ 3.3V +12V +VA -VA -12V +VA GND AVDD C51 10uF VDRVC50 10uF C15 10uF 4 4 VDIG VIO OVDD DVDD AVDD GND VREF+ 3.3V +12V +VA -VA -12V +VA GND VREF+ VDRV+ 6 Rev. : J POWER EVAL-AD76XXCB GND VDRV+ 8-Feb-2005 C54 10uF VDRV- 6 M.M A B C D EVAL-AD76XXEDZ Preliminary Technical Data Preliminary Technical Data EVAL-AD76XXEDZ Figure 11. Top Side Silk-Screen Figure 12. Top Layer Rev. PrB | Page 19 of 23 EVAL-AD76XXEDZ Preliminary Technical Data Figure 13. Ground Layer Figure 14. Shield Layer Rev. PrB | Page 20 of 23 Preliminary Technical Data EVAL-AD76XXEDZ Figure 15. Bottom Side Layer a Figure 16. Bottom Side Silk-Screen Rev. PrB | Page 21 of 23 EVAL-AD76XXEDZ Preliminary Technical Data Table 6. Bill of Materials for the Connectors Ref Des J1 – J3 P2 P3 Connector Type RT Angle SMB Male 0.100 X 0.100 straight IDC header 2X20 32X3 RT PC MOUNT CONNECTOR Manf. Pasternack 3M ERNI Part No. PE4177 2540-6002UB 533402 ORDERING GUIDE These evaluation boards are compatible with both EVAL-CED1Z and EVAL-CONTROL BRDxZ. For simplicity, this document was made especially for EVAL-CED1Z usage. Refer to Analog Devices PulSAR Evaluation Kit product page for the user’s guide specific to EVALCONTROL BRDxZ usage. Evaluation Board Model EVAL-AD7621CBZ EVAL-AD7622CBZ EVAL-AD7623CBZ EVAL-AD7641CBZ EVAL-AD7643CBZ EVAL-AD7650CBZ EVAL-AD7651CBZ EVAL-AD7652CBZ EVAL-AD7653CBZ EVAL-AD7660CBZ EVAL-AD7661CBZ EVAL-AD7663CBZ EVAL-AD7664CBZ EVAL-AD7665CBZ EVAL-AD7666CBZ EVAL-AD7667CBZ EVAL-AD7671CBZ EVAL-AD7674CBZ EVAL-AD7675CBZ EVAL-AD7676CBZ EVAL-AD7677CBZ EVAL-AD7678CBZ EVAL-AD7679CBZ EVAL-CED1Z Product AD7621ASTZ/ACPZ AD7622BSTZ/BCPZ AD7623ASTZ/ACPZ AD7641BSTZ/BCPZ AD7643BSTZ/BCPZ AD7650ASTZ/ACPZ AD7651ASTZ/ACPZ AD7652ASTZ/ACPZ AD7653ASTZ/ACPZ AD7660ASTZ/ACPZ AD7661ASTZ/ACPZ AD7663ASTZ/ACPZ AD7664ASTZ/ACPZ AD7665ASTZ/ACPZ AD7666ASTZ/ACPZ AD7667ASTZ/ACPZ AD7671ASTZ/ACPZ AD7674ASTZ/ACPZ AD7675ASTZ/ACPZ AD7676ASTZ/ACPZ AD7677ASTZ/ACPZ AD7678ASTZ/ACPZ AD7679ASTZ/ACPZ USB Capture Board Rev. PrB | Page 22 of 23 Preliminary Technical Data EVAL-AD76XXEDZ NOTES ©2009 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. PR07201-0-3/09(PrB) Rev. PrB | Page 23 of 23
