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Xilinx参考设计(维基网站)

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This version (14 Feb 2021 22:44) was approved by Dragos Bogdan.The Previously approved version (09 Feb 2021 08:46) is available.Diff

Xilinx Reference Designs

Hardware

Below is a list of hardware, IP Cores, or reference designs. While this content is believed to be reliable, many have not been validated, verified or reviewed by Analog Devices. These boards/platforms may or may not be suitable for end product integration or development, and may not meet datasheet specifications. Since many of these platforms or IP Cores are not designed or reviewed by Analog Devices, care should be taken to ensure that these will meet your needs before purchase. While ADI will always provide chip level support on the EngineerZone™, board level, or reference design support is given by the manufacture or creator of the specific materials.

References to manufacturer or third party software, websites, or to any specific commercial or non-commercial products are suggestions only and do not necessarily constitute or imply an endorsement, recommendation, or favoring by Analog Devices.

22 Sep 2011 16:30

Add on Boards

ADI products can be found on many boards which use industry standard connectors, such as PMODs and FMC.

FMC

Part Number / Purchase Description ADI Parts
EVAL-AD7960FMCZ Reference Design: View Reference Design

The EVAL-AD7960FMCZ board is based on the AD7960, which is an 18-bit, 5 MSPS charge redistribution successive approximation (SAR), analog-to-digital converter (ADC). The SAR architecture allows unmatched performance both in noise and in linearity. The AD7960 contains a low power, high speed, 18-bit sampling ADC, an internal conversion clock and an internal reference buffer. On the CNV± edge, the AD7960 samples the voltage difference between the IN+ and IN- pins. The voltages on these pins swing in opposite phase between 0 V and 4.096 V/5 V. The reference voltage is applied to the part externally. All conversion results are available on a single LVDS self-clocked or echo-clocked serial interface.
AD7960
EVAL-AD7961FMCZ Reference Design: View Reference Design

The EVAL-AD7961FMCZ board is based on the AD7961, which is an 16-bit, 5 MSPS charge redistribution successive approximation (SAR), analog-to-digital converter (ADC). The SAR architecture allows unmatched performance both in noise and in linearity. The AD7961 contains a low power, high speed, 16-bit sampling ADC, an internal conversion clock and an internal reference buffer. On the CNV± edge, the AD7961 samples the voltage difference between the IN+ and IN- pins. The voltages on these pins swing in opposite phase between 0 V and 4.096 V/5 V. The reference voltage is applied to the part externally. All conversion results are available on a single LVDS self-clocked or echo-clocked serial interface.
AD7961
AD9434-FMC-500EBZ cf_ad9434_board.jpg Reference Design: View Reference Design

The AD9434-FMC-500EBZ board is based on the AD9434, which is a 12-Bit monolithic sampling analog-to-digital converter (ADC) optimized for high performance, low power, and ease of use. The part operates at up to a 500 MSPS conversion rate and is optimized for outstanding dynamic performance in wideband carrier and broadband systems.
AD9434 AD9517-4
AD9467-FMC-250EBZ tile_ad9467_150.jpg Reference Design: View Reference Design

The AD9467-FMC-250EBZ board is based on the AD9467, which is a 16-Bit, 250 MSPS analog-to-digital converter that. The AD9467 provides a new level of signal processing performance for test and measurement instrumentation, defense electronics, and communications applications where high resolution over a wide bandwidth is needed.
AD9467 AD9517-4
AD9265-FMC-125EBZ Reference Design: View Reference Design

The AD9265-FMC-125EBZ board is based on the AD9265, which is a 16-Bit, 125 MSPS analog-to-digital converter (ADC) featuring a wide bandwidth differential sample-and-hold analog input amplifier supporting a variety of user-selectable input ranges.
AD9265 AD9517-4
AD9739A-FMC-EBZ tile_ad9739a_150.jpg Reference Design: View Reference Design

The new AD9739A-FMC-EBZ board is based on the AD9739A is a 14-bit, 2.5 GSPS high performance RF DAC capable of synthesizing wideband signals from dc up to 3 GHz.
AD9739A ADF4350
AD-FMCOMMS1-EBZ Reference Design: View Reference Design

The AD-FMCOMMS1-EBZ is an analog front end hardware platform that addresses a broad range of research, academic, industrial and defense applications. The AD-FMCOMMS1-EBZ enables RF applications from 400MHz to 4 GHz. The module is customizable to a wide range of frequencies by software without any hardware changes, providing options for GPS or IEEE 1588 Synchronization, and MIMO configurations.
AD9122 ADL5375 ADF4351 ADL5602 ADL5380 AD8366 AD9643 ADF4351 AD9548 AD9523-1
AD-FMCOMMS2-EBZ ad_fmcomms2_ebz.jpg Reference Design: View Reference Design

The AD-FMCOMMS2-EBZ is a high-speed analog module designed to showcase the AD9361, a high performance, highly integrated RF agile transceiver intended for use in RF applications, such as 3G and 4G base station applications and software defined radios. The AD-FMCOMMS2-EBZ provides RF engineers the ability to connect the AD9361 to a RF testbench (Vector Signal Analyzer, Signal generator, etc) and measure performance. The external components (which can easily be swapped) on the AD-FMCOMMS2-EBZ have a narrower RF tuning range 2400 – 2500 MHz. It is expected that most engineers will change these external components (pin for pin replacements from various vendors are available) for their specific application/ frequency of interest. Anyone interested in a wider tuning range board should look at the AD-FMCOMMS3-EBZ.
AD9361
AD-FMCOMMS3-EBZ ad_fmcomms3_ebz.jpg Reference Design: View Reference Design

The AD-FMCOMMS3-EBZ is a high-speed analog module designed to showcase the AD9361, a high performance, highly integrated RF agile transceiver intended for use in RF applications, such as 3G and 4G base station applications and software defined radios. The purpose of the AD-FMCOMMS3-EBZ is to provide an RF platform to software developers, system architects, etc, who want a single platform that operates over a much wider tuning range (70 MHz – 6 GHz) than the AD-FMCOMMS2-EBZ.
AD9361
AD-FMCOMMS4-EBZ ad_fmcomms4_ebz.jpg Reference Design: View Reference Design

The AD-FMCOMMS4-EBZ is a high-speed analog module designed to showcase the AD9364, a high performance, highly integrated RF agile transceiver intended for use in RF applications, such as 3G and 4G base station applications and software defined radios. The purpose of the AD-FMCOMMS4-EBZ is to provide an RF platform to software developers, system architects, etc, who want a single platform that operates over a much wider tuning range (70 MHz – 6 GHz) than the AD-FMCOMMS2-EBZ.
AD9364
AD-FMCOMMS5-EBZ ad_fmcomms5_ebz.jpg Reference Design: View Reference Design

The AD-FMCOMMS5-EBZ is a high-speed analog module designed to showcase the AD9361, a high performance, highly integrated RF agile transceiver intended for use in RF applications, such as 3G and 4G base station applications and software defined radios. The board includes two AD9361s in a 4 x 4 RF configuration, which demonstrates how to synchronize multiple devices together.
AD9361
AD-FMCOMMS6-EBZ Reference Design: View Reference Design

The AD-FMCOMMS6-EBZ evaluation board is a 400 MHz to 4.4 GHz receiver based on the AD9652 dual 16-bit ADC, the ADL5566 High Dynamic Range RF/IF Dual Differential Amplifier and the ADL5380 quadrature demodulator. The AD-FMCOMMS6-EBZ is a discrete hardware receiver platform that addresses L and S band radar applications and enables RF applications from 400 MHz to 4 GHz. The module is configurable to a wide range of frequencies small filter hardware changes, providing options for RF up to 4 GHz and IF up to 155 MHz.
AD9652 ADF4351 ADL5380 ADL5566 AD9517 ADCLK925 ADP2370 ADM7150 ADP1740
AD-FMCADC2-EBZ ad_fmcadc2_ebz.jpg Reference Design: View Reference Design

The AD-FMCADC2-EBZ is a data acquisition and signal processing platform that contains a complete signal chain for digitizing wideband RF signals for a variety of high-performance applications. The board has operating software and drivers for seamless connectivity within the Xilinx FPGA development platform ecosystem. This board is comprised of the AD9625-2.5 12-bit, 2.5 GSPS JESD204B ADC, input balun, clock oscillator, and critical power management components.
AD9625
AD-FMCDAQ2-EBZ ad_fmcdaq2_ebz.jpg Reference Design: View Reference Design

The AD-FMCDAQ2-EBZ module is comprised of the AD9680 dual, 14-bit, 1.0 GSPS, JESD204B ADC, the AD9144 quad, 16-bit, 2.8 GSPS, JESD204B DAC, the AD9523-1 14-output, 1 GHz clock generator, and power management components. It is clocked by an internally generated carrier platform via the FMC connector, comprising a completely self-contained data acquisition and signal synthesis prototyping platform. The module’s combination of wideband data conversion, clocking, and power closely approximates real-world hardware and software for system prototyping and design, with no compromise in signal chain performance.
AD9680 AD9144 AD9523-1 ADN4661 ADP1740 ADP150
AD-FMCJESDADC1-EBZ ad_fmcjesdadc1_ebz.jpg Reference Design: View Reference Design

The AD-FMCJESDADC1-EBZ board features two AD9250, which is a 14-Bit, 250MSPS analog-to-digital converter (ADC). This board shares the 4DSP FMC-176 PCB, which in addition to the ADC, has two AD9129, which is a 14-Bit, 2.8GSPS digital-to-analog converter (DAC).
AD9250 AD9129 AD9517-1
AD-FMCMOTCON2 eval-fmcmotcon2-system.jpg Reference Design: View Reference Design

The AD-FMCMOTCON2-EBZ is a complete high performance servo system on an FPGA Mezzanine Card (FMC) board. Information on the FMC board, and how to use it, the design package that surrounds it, and the software which can make it work, can be found by clicking the documentation link. The purpose of the AD-FMCMOTCON2-EBZ is to provide a complete motor drive system demonstrating efficient and high dynamic control of three phase PMSM and induction motors. The kit consists of two boards: a controller board and a drive board. The system incorporates high quality power sources; reliable power, control, and feedback signals isolation; accurate measurement of motor current & voltage signals; high speed interfaces for control signals to allow fast controller response; industrial Ethernet high speed interfaces; flexible control with a FPGA/SoC interface. An optional AD-DYNO2-EBZ dynamometer can be purchased through Avnet and is intended to be an extension of the drive system.
ADUM7640 ADUM7641 ADM2486 ADUM1400 ADUM1402 ADG3308 AD8646 AD8137 ADUM5000 AD2S1210 ADN4662 ADG759 ADUM1250 CMP04 ADP2301 ADP1621 ADUM7223 ADUM5230 AD8207 AD7403 AD7402 AD7405
23 Sep 2011 21:05 · Robin Getz

Pmods

ADI products can be found on many boards which use industry standard connectors, such as Pmods and FMC.

Pmods are small I/O interface boards that offer an ideal way to extend the capabilities of FPGA/CPLD boards. Pmods communicate with system boards using 6 or 12-pin connectors. Pmods include sensors, I/O, data acquisition & conversion, connectors, and more. Popular systems with Pmod connectors can be found at Digilent or Avnet.

Part Number / Purchase Description ADI Parts
PmodACL Digilent Avnet Silica tile_pmodacl_150.jpg Reference Design: Analog Devices
Reference Design: Digilent
Reference Design: Avnet
Reference Design: Silica

The Digilent PmodACL is a 3-axis digital accelerometer module powered by the Analog Devices ADXL345. It uses a standard 12-pin Pmod connector and can communicate via SPI or I2C.
ADXL345
PmodACL2 pmodacl2icon.jpg Reference Design: Analog Devices

The Digilent Pmod-ACL2 is an ultralow power, 3-axis MEMS accelerometer that consumes less than 2 µA at a 100 Hz output data rate and 270 nA when in motion triggered wake-up mode. Unlike accelerometers that use power duty cycling to achieve low power consumption, the ADXL362 does not alias input signals by undersampling; it samples the full bandwidth of the sensor at all data rates. The ADXL362 always provides 12-bit output resolution; 8-bit formatted data is also provided for more efficient single-byte transfers when a lower resolution is sufficient. Measurement ranges of ±2 g, ±4 g, and ±8 g are available, with a resolution of 1 mg/LSB on the ±2 g range.
ADXL362
PmodAD1 Digilent Avnet Silica tile_pmodad1_150.jpg Reference Design: Analog Devices
Reference Design: Digilent
Reference Design: Avnet
Reference Design: Silica

The Digilent Analog to Digital Module Converter Board (the AD1) converts signals at a maximum sampling rate of one million samples per second, fast enough for the most demanding audio applications. The AD1 uses a 6-pin header connector, and at less than one square inch is small enough to be located at the signal source.
AD7476
PmodAD2 Digilent tile_pmodad2_150.jpg Reference Design: Analog Devices
Reference Design: Digilent

The Digilent PmodAD2 is an analog to digital converter module with up to 4 channels at 12-bit resolution powered by the Analog Devices AD7991. It uses an 8-pin connector that allows communication via I2C. The PmodAD2 also has a 6-pin connector that allows up to 4 analog inputs or up to 3 analog inputs and a voltage reference.
AD7991
PmodAD3 pmodad3_icon.jpg Reference Design: Analog Devices

The Digilent Pmod-AD3 is a complete low power front-end solution for bridge sensor products, including weigh scales, strain gages, and pressure sensors. It contains a precision, low power, 24-bit sigma-delta (S-?) ADC; an on-chip, low noise programmable gain amplifier (PGA); and an on-chip oscillator.
AD7780
PmodAD4 pmodad4icon.jpg Reference Design: Analog Devices

The Digilent Pmod-AD4 is a 16-bit, successive approximation, analog-to-digital converter (ADC) that operates from a single power supply, VDD.It contains a low power, high speed, 16-bit sampling ADC and a versatile serial interface port. On the CNV rising edge, it samples an analog input IN+ between 0V to REF with respect to ground sense IN-. The reference voltage, REF, is applied externally and can be set independent of the supply voltage, VDD. Its power scales linearely with throughput.
AD7980
PmodAD5 pmodad5icon.jpg Reference Design: Analog Devices

The Digilent Pmod-AD5 is powered by the Analog Devices AD7193, a low noise, complete analog front end for high precision measurement applications. It contains a low noise, 24-bit sigma-delta (S-?) analog-to-digital converter (ADC).
AD7193
PmodAD6 pmodad6icon.jpg Reference Design: Analog Devices

The Digilent Pmod-AD6 is powered by the Analog Devices AD7091R, a a 12-bit successive approximation analog-to-digital converter (ADC) that offers ultralow power consumption (typically 349 µA at 3 V and 1 MSPS) while achieving fast throughput rates (1 MSPS with a 50 MHz SCLK).
AD7091r
PmodAMP3 pmodamp3_icon.jpg Reference Design: Analog Devices

The Digilent Pmod-AMP3 is powered by the Analog Devices SSM2518, a digital input, Class-D power amplifier that com-bines a digital-to-analog converter (DAC) and a sigma-delta (Σ-Δ) Class-D modulator. This unique architecture enables extremely low real-world power consumption from digital audio sources with excellent audio performance. The SSM2518 is ideal for power sensitive applications, such as mobile phones and portable media players, where system noise can corrupt small analog signals such as those sent to an analog input audio amplifier.
SSM2518
PmodCDC1 Digilent pmodcdc1icon.jpg Reference Design: Analog Devices

The Digilent PmodCDC1 delivers a complete signal processing solution for capacitive sensors, featuring an ultralow power converter with fast response time. The AD7156 uses an Analog Devices, Inc., capacitance-to-digital converter (CDC) technology, which combines features important for interfacing to real sensors, such as high input sensitivity and high tolerance of both input parasitic ground capacitance and leakage current. The integrated adaptive threshold algorithm compensates for any variations in the sensor capacitance due to environmental factors like humidity and temperature or due to changes in the dielectric material over time.
AD7156
PmodDA1 Digilent Avnet Silica tile_pmodda1_150.jpg Reference Design: Analog Devices
Reference Design: Digilent
Reference Design: Avnet
Reference Design: Silica

The Digilent PmodDA1 Digital To Analog Module Converter Board (the DA1) converts signals from digital to analog at up to one MSa per second. The DA1 uses a 6-pin header connector and at less than one square inch is small enough to be located where the signal is needed. The DA1 has four simultaneous D/A conversion channels, each with an 8-bit converter that can process a separate digital signal. It is possible to send a single signal, such as a reset signal, to all four channels simultaneously, but multiple unique signals cannot be sent simultaneously.
AD7303
PmodDA3 pmodda3icon.jpg Reference Design: Analog Devices

The Digilent Pmod-DA3 is a single, 16-bit, serial input, unbuffered voltage output digital-to-analog converter (DAC) that operates from a single 2.7V to 5.5V supply. The DAC output range extends from 0V to Vref and is guaranteed monotonic, providing +- 1 LSB INL accuracy at 16 bits without adjustment.
AD5541A
PmodDA4 pmodda4icon.jpg Reference Design: Analog Devices

The Digilent Pmod-DA4 is a low power, octal, 12 bit, buffered voltage-output DAC. The device operates from a single 2.7 V to 5.5 V supply and is guaranteed monotonic by design. The AD5628 is available in both a 4 mm × 4 mm LFCSP and a 16-lead TSSOP. The AD5628 has an on-chip reference with an internal gain of 2. The AD5628 has a 1.25 V 5 ppm/°C reference, giving a full-scale output range of 2.5 V; the AD5628-2 has a 2.5 V 5 ppm/°C reference, giving a full-scale output range of 5 V.
AD5628
PmodDA5 ASCII Reference Design: Analog Devices

The Digilent Pmod-DA5 is a single 18-bit, unbuffered voltage output DAC that operates from a bipolar supply of up to 33 V. The AD5781 accepts a positive reference input range of 5 V to VDD − 2.5 V and a negative reference input range of VSS + 2.5 V to 0 V. The AD5781 offers a relative accuracy specification of ±0.5 LSB maximum, and operation is guaranteed monotonic with a ±0.5 LSB DNL maximum specification.
AD5781
PmodDPOT pmoddpoticon.jpg Reference Design: Analog Devices

The Digilent Pmod-DPOT is powered by the Analog Devices AD5160, a 256 Position SPI Compatible Digital Potentiometer
AD5160
PmodGYRO2 Digilent tile_pmodgyro2_150.jpg Reference Design: Analog Devices

The Digilent PmodGYRO2 is powered by the Analog Devices ADXRS453, an angular rate sensor (gyroscope) intended for industrial, instrumentation and stabilization applications in high vibration environments.
ADXRS453
PmodIA pmod_ia.jpg Reference Design: Analog Devices

The Digilent PmodIA is powered by the Analog Devices AD5933, a high precision impedance converter system solution that combines an on-board frequency generator with a 12-bit, 1 MSPS, analog-to-digital converter (ADC).
AD5933
PmodIOXP Digilent tile_pmodioxp_150.jpg Reference Design: Analog Devices

The Digilent PmodIOXP is an I/O expansion module powered by the Analog Devices ADP5589. It functions as an I/O port expander and keypad matrix decoder, and uses a standard 8-pin I2C connector allowing it to communicate with a system board via I2C.
ADP5589
PmodMIC2 Digilent pmodmic2icon.jpg Reference Design: Analog Devices

The Digilent PmodMIC2 is powered by the Analog Devices ADMP441, a high performance, low power, digital output, omnidirectional MEMS microphone with a bottom port. The complete ADMP441 solution consists of a MEMS sensor, signal conditioning, an analog-to-digital converter, antialiasing filters, power management, and an industry standard 24-bit I²S interfface.
ADMP441
PmodRS232 Digilent tile_pmodrs232_150.jpg The PmodRS232 Converter Module Board (the RS232 module) translates voltage from the logic levels used by Digilent system boards to the RS232 voltage used for serial communications. ADM3232E
PmodTMP2 Digilent tile_pmodtmp2_150.jpg Reference Design: Analog Devices

The Digilent PmodTMP2 is a high accuracy digital temperature sensor offering breakthrough performance over a wide industrial range, housed in a 4 mm × 4 mm LFCSP package. It contains an internal band gap reference, a temperature sensor, and a 16-bit ADC to monitor and digitize the temperature to 0.0078°C resolution. The ADC resolution, by default, is set to 13 bits (0.0625°C). The ADC resolution is a user programmable mode that can be changed through the serial interface.
ADT7420
23 Sep 2011 21:05 · Robin Getz

Pmod Compatible Boards

CftL Reference Designs

Part Number / Purchase Description ADI Parts
EVAL-CN0179-PMDZ
CN0179 is a 4 mA-to-20 mA current loop transmitter for communication between a process control system and its actuator. Current loop interfaces are usually preferred because they offer the most cost effective approach to long distance noise immune data transmission. Besides being cost effective, this circuit offers the industry’s lowest power solution.
AD5641
AD8657
ADR02
EVAL-CN0216-PMDZ

CN0216 is a precision weigh scale signal conditioning system. Ultralow noise, low offset voltage, and low drift amplifiers are used at the front end for amplification of the low-level signal from the load cell.
AD7791
ADA4528-1
ADP3301
EVAL-CN0326-PMDZ

CN0326 is a completely isolated low power pH sensor signal conditioner and digitizer with automatic temperature compensation for high accuracy. This circuit supports a wide variety of pH sensors that have very high internal resistance that can range from 1 MΩ to several GΩ, and digital signal and power isolation provides immunity to noise and transient voltages often encountered in harsh industrial environments. Suitable for a variety of industrial applications such as chemical, food processing, water, and wastewater analysis.
AD7793
AD8603
ADUM5401
EVAL-CN0332-PMDZ

CN0332 is a single-supply, low cost, high-speed magnetoresistive (MR) signal conditioner solution that amplifies the small output voltage of the magnetoresistive sensor and converts it into a digital output signal. The circuit provides a compact and cost effective robust solution for high speed rotational sensing in industrial and automotive applications and is an excellent alternative to Hall effect sensors.
ADCMP601
AD8027
ADA4897-2
EVAL-CN0335-PMDZ

CN0335 processes ±10 V input signals using a single 3.3 V supply. The total error after room temperature calibration is less than ±0.1% FSR over a ±10°C temperature change, making it ideal for a wide variety of industrial measurements. Both data and power are isolated, thereby making the circuit robust to high voltages and also ground-loop interference often encountered in harsh industrial environments.
AD7091R
AD8606
ADUM5401
EVAL-CN0336-PMDZ

CN0336 processes 4 mA to 20 mA input signals using a single 3.3 V supply. The total error after room temperature calibration is ±0.06% FSR over a ±10°C temperature change, making it ideal for a wide variety of industrial measurements. Both data and power are isolated, thereby making the circuit robust to high voltages and also ground-loop interference often encountered in harsh industrial environments.
AD7091R
AD8606
ADUM5401
EVAL-CN0337-PMDZ

CN0337 processes the output of a PT100 RTD and includes an innovative circuit for lead-wire compensation using a standard 3-wire connection. The circuit operates on a single 3.3 V supply.
AD7091R
AD8606
ADUM5401
EVAL-CN0346-PMDZ

CN0346 is a relative humidity sensing circuit which can be connected up to any Pmod compatible host controller board.
AD7156
AD8615
ADP125
EVAL-CN0349-PMDZ

CN0349 is a fully Isolated conductivity measurement data acquisition system.
AD5934
AD8606
ADUM5000
ADUM1250
ADG715
EVAL-CN0350-PMDZ

CN0350 processes charge input signals from piezoelectric sensors using a single 3.3 V supply and has a total error of less than 0.25% FSR after calibration over a ±10°C temperature range.
AD7091R
AD8608
EVAL-CN0354-PMDZ

CN0354 is a low power multichannel thermocouple measurement system with cold junction compensation.
AD7787
AD8495
ADM8829
ADG1609
ADR3412
REF194
EVAL-CN0355-PMDZ

CN0355 is a low power signal conditioner for resistive bridge type sensors and includes a temperature compensation channel.
AD7793
AD8420
ADA4096-2
EVAL-CN0357-PMDZ

CN0357 is an electrochemical gas sensing signal conditioning solution, designed to work with many electrochemical gas sensors down to resolutions of 1 part per million (ppm).
AD7790
ADA4528-2
AD8500
ADR3412
AD5270

ADC Drivers

Resolution Sampling Speed Part Number / Purchase Description ADI Parts Device Driver
14-Bits 250 KSPS EVAL-AD7942-PMDZ

AD7942 is a 14-bit PulSAR® ADC 250 kSPS, unipolar, single-ended input.
AD7942
ADA4841
AD7942 IIO Serial ADC Linux Driver
14-Bits 500 KSPS EVAL-AD7946-PMDZ

AD7946 is a 14-bit PulSAR® ADC 500 kSPS, unipolar, single-ended input.
AD7946
ADA4841
AD7946 IIO Serial ADC Linux Driver
16-Bits 100 KSPS EVAL-AD7988-1-PMDZ

AD7988-1 is a 16-bit PulSAR® ADC 100 kSPS, unipolar, differential input.
AD7988-1
ADA4841
AD7988-1 IIO Serial ADC Linux Driver
16-Bits 250 KSPS EVAL-AD7685-PMDZ

AD7685 is a 16-bit PulSAR® ADC 250 kSPS, unipolar, single-ended input.
AD7685
ADA4841
AD7685 IIO Serial ADC Linux Driver
16-Bits 250 KSPS EVAL-AD7687-PMDZ

AD7687 is a 16-bit PulSAR® ADC 250 kSPS, unipolar, differential input.
AD7687
ADA4841
AD7687 IIO Serial ADC Linux Driver
16-Bits 250 KSPS EVAL-AD7691-PMDZ

AD7691 is a 16-bit PulSAR® ADC 250 kSPS, unipolar, differential input.
AD7691
ADA4841
AD7691 IIO Serial ADC Linux Driver
16-Bits 500 KSPS EVAL-AD7686-PMDZ

AD7686 is a 16-bit PulSAR® ADC 500 kSPS, unipolar, single-ended input.
AD7686
ADA4841
AD7686 IIO Serial ADC Linux Driver
16-Bits 500 KSPS EVAL-AD7688-PMDZ

AD7688 is a 16-bit PulSAR® ADC 500 kSPS, unipolar, differential input.
AD7688
ADA4841
AD7688 IIO Serial ADC Linux Driver
16-Bits 500 KSPS EVAL-AD7693-PMDZ

AD7693 is a 16-bit PulSAR® ADC 500 kSPS, unipolar, differential input.
AD7693
ADA4841
AD7693 IIO Serial ADC Linux Driver
16-Bits 500 KSPS EVAL-AD7988-5-PMDZ

AD7988-5 is a 16-bit PulSAR® ADC 500 kSPS, unipolar, single-ended input.
AD7988-5
ADA4841
AD7988-5 IIO Serial ADC Linux Driver
16-Bits 1000 KSPS EVAL-AD7980-PMDZ

AD7980 is a 16-bit PulSAR® ADC 1000 kSPS, unipolar, single-ended input.
AD7980
ADA4841
AD7980 IIO Serial ADC Linux Driver
16-Bits 1333 KSPS EVAL-AD7983-PMDZ

AD7983 is a 16-bit PulSAR® ADC 1333 kSPS, unipolar, single-ended input.
AD7983
ADA4841
AD7983 IIO Serial ADC Linux Driver
18-Bits 400 KSPS EVAL-AD7690-PMDZ

AD7690 is a 18-bit PulSAR® ADC 400 kSPS, unipolar, differential input.
AD7690
ADA4841
AD7690 IIO Serial ADC Linux Driver
18-Bits 1000 KSPS EVAL-AD7982-PMDZ

AD7982 is a 18-bit PulSAR® ADC 1000 kSPS, unipolar, differential input.
AD7982
ADA4841
AD7982 IIO Serial ADC Linux Driver
18-Bits 1333 KSPS EVAL-AD7984-PMDZ

AD7984 is a 18-bit PulSAR® ADC 1333 kSPS, unipolar, differential input.
AD7984
ADA4841
AD7984 IIO Serial ADC Linux Driver

Adapter Boards

An Adapter Board is an electrical interface routing between one socket or connection to another. The purpose of these adapters are to reroute one connector (normally an ADI standard connector) to a different connector (normally a standard Xilinx connector).

AD-DAC-FMC Adapter Board

ad-dac-fmc-adp_sm.jpg
The AD-DAC-FMC adapter board allows any of Analog Devices' DPG2-compatiable High-Speed DAC Evaluation Boards to be used on a Xilinx® evaluation board with a FMC connector. The adapter board uses the Low Pin Count (LPC) version of the FMC connector, so it can be used on either LPC or HPC hosts.

More information about this adapter board can be found at the product page.

Existing projects which can be used with the AD-DAC-FMC Adapter Board.

Part Number Description ADI Parts
AD9739-R2-EBZ Reference design: Analog Devices

14-Bit, 2500 MSPS, RF Digital-to-Analog Converter
AD9739
AD9789-EBZ Reference design: Analog Devices

4 Channel QAM encoder/interpolator/upconverter with 2400 MSPS, 14-bit RF digital-to-analog converter
AD9789
EVAL-AD9122 Reference design: Analog Devices

Dual 16-bit, 1200MSPS digital-to-analog converter
AD9122
AD9129-EBZ Reference design: Analog Devices

14-bit, 2.8GSPS digital-to-analog converter
AD9129
AD9747-EBZ Reference design: Analog Devices

Dual 16-bit, 250MSPS digital-to-analog converter
AD9747
AD9117-DPG2-EBZ
AD9116-DPG2-EBZ
AD9115-DPG2-EBZ
AD9114-DPG2-EBZ
Reference design: Analog Devices

8/10/12/14-bit, low power digital-to-analog converter (DAC) that provides a sample rate of 125 MSPS.
AD9114
AD9115
AD9116
AD9117
AD9785-DPG2-EBZ
AD9787-DPG2-EBZ
AD9788-DPG2-EBZ
Reference design: Analog Devices

12-bit, 14-bit, and 16-bit, high dynamic range TxDAC® devices, respectively, that provide a sample rate of 800 MSPS, permitting multicarrier generation up to the Nyquist frequency.
AD9785
AD9787
AD9788

AD-ADC-FMC Adapter Board


The AD-ADC-FMC adapter board allows Analog Devices' FIFO-compatible High-Speed ADC Evaluation Boards to be used on a Xilinx® evaluation board with a FMC connector. There are two revisions of the interposer where both use the high pin count (HPC) version of the FMC connector.

More information about this adapter board can be found at the product page.

Evaluation boards which can be used with the Rev A, AD-ADC-FMC Adapter Board:

Part Number Description ADI Parts
AD9279-80KITZ Reference Design: Analog Devices

8 channel LNA, VGA, AAF, I/Q Demodulator with 12Bit, 80MSPS Analog-to-Digital Converter
AD9279
AD9467-250EBZ Reference Design: Analog Devices

16-bit, 250MSPS monolithic, IF sampling analog-to-digital converter (ADC)
AD9467

Evaluation boards which can be used with the Rev B, AD-ADC-FMC Adapter Board (Part Number: CVT-ADC-FMC-INTPZB):

Part Number Description ADI Parts
AD9250-250EBZ Reference Design: Analog Devices

14-Bit, 250 MSPS, Analog-to-Digital Converter
AD9250
AD9250-170EBZ Reference Design: Analog Devices

14 Bit, 170 MSPS, Analog-to-Digital converter
AD9250
AD6673-250EBZ Reference Design: Analog Devices

11 Bit, 250 MSPS, Dual channel IF Receiver
AD6673
AD9649-EBZ Reference Design: Analog Devices

14 Bit, 80 MSPS, Single channel ADC
AD9649
AD9671-EBZ Reference Design: Analog Devices

14 Bit, 40 MSPS, Eight channel Ultrasound AFE with digital demodulator
AD9671
AD9683-250EBZ Reference Design: Analog Devices

14-Bit, 250 MSPS, Analog-to-Digital Converter
AD9683

FMC-SDP Interposer

The FMC-SDP interposer allows any Analog Devices SDP Evaluation Board to be used on a Xilinx® evaluation board with a FMC connector. The interposer uses the Low Pin Count (LPC) version of the FMC connector, so it can be used on either LPC or HPC hosts. The interposer can only be used with FPGA boards that support 3.3VIO for the FMC connection.

Part Number Description ADI Parts
SDP-FMC-IB1Z SDP to FMC Interposer Board

Existing projects which can be used with the FMC-SDP Adapter Board.

Part Number Description ADI Parts
Analog to Digital Converters
EVAL-AD7091SDZ ad7091_kc705.jpg Reference Design: Analog Devices

The AD7091 is a 12-bit successive approximation register analog-to-digital converter (SAR ADC) that offers ultralow power consumption (typically 367 μA at 3 V and 1 MSPS) while achieving fast throughput rates (1 MSPS with a 50 MHz SCLK). The AD7091 operates from a single 2.09 V to 5.25 V power supply. The AD7091 also features an on-chip conversion clock and a high speed serial interface.
AD7091
EVAL-AD7091RSDZ ad7091r_kc705.jpg Reference Design: Analog Devices

The AD7091R is a 12-bit successive approximation analog-to-digital converter (ADC) that offers ultralow power consumption (typically 349 µA at 3 V and 1 MSPS) while achieving fast throughput rates (1 MSPS with a 50 MHz SCLK). Operating from a single 2.7 V to 5.25 V power supply, the part contains a wide bandwidth track-and-hold amplifier that can handle input frequencies in excess of 7 MHz. The AD7091R also features an on-chip conversion clock, accurate reference, and high speed serial interface.
AD7091R
EVAL-AD7175-2SDZ ASCII Reference Design: Analog Devices

The AD7175-2 is a low noise, fast settling, multiplexed, 2-/4- channel (fully/pseudo differential) Σ-Δ analog-to-digital converter (ADC) for low bandwidth inputs. It has a maximum channel scan rate of 50 kSPS (20 μs) for fully settled data. The output data rates range from 5 SPS to 250 kSPS. The AD7175-2 integrates key analog and digital signal condition-ing blocks to allow users to configure an individual setup for each analog input channel in use. Each feature can be user selected on a per channel basis. Integrated true rail-to-rail buffers on the analog inputs and external reference inputs provide easy to drive high impedance inputs. The precision 2.5 V low drift (2 ppm/°C) band gap internal reference (with output reference buffer) adds embedded functionality to reduce external component count. The digital filter allows simultaneous 50 Hz/60 Hz rejection at 27.27 SPS output data rate. The user can switch between different filter options according to the demands of each channel in the application. The ADC automatically switches through each selected channel. Further digital processing functions include offset and gain calibration registers, configurable on a per channel basis.
AD7175-2
EVAL-AD7176-2SDZ ASCII Reference Design: Analog Devices

The AD7176-2 is a fast settling, highly accurate, high resolution, multiplexed S-? analog-to-digital converter (ADC) for low band-width input signals. Its inputs can be configured as two fully differential or four pseudo differential inputs via the integrated crosspoint multiplexer. An integrated precision, 2.5 V, low drift (2 ppm/°C), band gap internal reference (with an output reference buffer) adds functionality and reduces the external component count. The maximum channel scan data rate is 50 kSPS (with a settling time of 20 µs), resulting in fully settled data of 17 noise free bits. User-selectable output data rates range from 5 SPS to 250 kSPS. The resolution increases at lower speeds. The AD7176-2 offers three key digital filters. The fast settling filter maximizes the channel scan rate. The Sinc3 filter maximizes the resolution for single-channel, low speed applications. For 50 Hz and 60 Hz environments, the AD7176-2 specific filter minimizes the settling times or maximizes the rejection of the line frequency. These enhanced filters enable simultaneous 50 Hz and 60 Hz rejec-tion with a 27 SPS output data rate (with a settling time of 36 ms).
AD7176-2
EVAL-AD7291SDZ ad7291.jpg Reference Design: Analog Devices

The AD7291 is a 12-bit, low power, 8-channel, successive approximation analog-to-digital converter (ADC) with an internal temperature sensor.
AD7291
EVAL-AD7298SDZ img_ad7298.jpg Reference Design: Analog Devices

The AD7298 is a 12-bit, high speed, low power, 8-channel, successive approximation ADC with an internal temperature sensor. The part operates from a single 3.3 V power supply and features throughput rates up to 1 MSPS. The device contains a low noise, wide bandwidth track-and-hold amplifier that can handle input frequencies in excess of 30 MHz.
AD7298
EVAL-AD7327SDZ

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