SCIENCE Alpha250 Programmable Board
User Guide

Alpha250 Programmable Board

Alpha250 User Guide
PDF version (https://s3-eu- west-1.amazonaws.com/koheronalpha250-public/koheron_alpha250_user_guide.pdf)
Koheron Alpha250 250 MSPS acquisition board (/fpga/alpha250-signal- acquisition-generation)

Getting started

Warnings
The Alpha250 power supply must be turned off before connecting or disconnecting:

• the micro-SD card
• peripherals on the expansion connector

Turn on the board
First, insert the micro-SD card into the micro-SD slot. Then connect the 12V jack of the power supply. The power good green LED (PWGD) and the FPGA done orange LED (DONE) indicate the system has correctly started.

Communicating with the board

LAN
The ethernet port is the main communication interface with the Alpha250. It can be connected to a local network via a router (/support/tutorials/nd- dynamic-ip) or directly to a computer (/support/tutorials/setup-direct- ethernet-static-ip). The last 8 bits of the IP address are displayed on the 8 user LEDs. Serial interface The serial UART debugging interface can be accessed by the micro USB connector. The required steps are described here (/support/tutorials/setup-usb-serial-connection).

Connectors

12 V external power supply
The external supply connector is a jack with 1.95 mm center pin and 6 mm outer diameter. Only 12 V must be supplied on this connector. Running the Alpha250 requires at least 1 A. More current may be required depending on the load on the expansion connector. Maximum current is 3 A (protected by an electronic fuse).
USB 2.0
This is a USB 2.0 host connector. It provides up to 1 A current at 5 V (shared with the 5 V supply of the expansion connector). The power and data pins are ESD protected.
Micro USB 2.0
Connects to the UART0 PS core via a FTDI device. It is used as a debugging serial interface. The power and data pins are ESD protected.
Gigabit ethernet
The Alpha250 is capable of 10/100/1000 Mbit Ethernet.
MicroSD card
The micro SD card is connected to the SD0 PS core via a level-shifter. The SD card I/Os are ESD protected.
Expansion connector
It contains:

• Power supplies. 12 V from external supply. 5 V up to 1 A (shared with USB 2.0 connector). + 3.3 V up to 800 mA, sequenced with I/Os supply. – 3.3 V up to 500 mA.

• A dedicated I2C bus I2C1 with interrupt.

• 16 single ended or 8 differential I/Os EXP_IOx . They are connected to the FPGA Bank 35. Voltage level is 3.3 V. All I/Os are ESD protected.
  Warning: These pins are connected directly to the Zynq SoC and must be driven from VCCIO_3V3 both for voltage compliance and power sequencing. Applying non compliant voltages on these pins may result in SoC failure.

• Two LVDS clocks from the clocking subsystem EXP_CLK0 and EXP_CLK1 .

• 4 user IOs from the GPIO expander USER_IOx . Voltage level is 3.3 V. They can be con gured as inputs or outputs, open-drain or pull-up. These I/Os have 22 series protection resistors. They are ESD protected.

• A 2.5 V voltage reference. This reference acts as a ratiometric tracking with the reference used for all the data converters (RF ADC, RF DAC, precision ADC, precision DAC). It delivers up to 150 mA (Care must be taken with the voltage drop in track resistance at large currents).

• 4 precision ADC inputs. Differential inputs to the precision 24-bit ADC.

• 4 precision DAC outputs. Outputs from the 16-bit precision DAC.

Subsystems

RF ADC
The RF Analog-to-Digital Converter has 2 acquisition channels with 14-bit resolution and 250 Msps maximum sampling rate (Linear Technologies LTC2157-14 (https://cds.linear.com/docs/en/datasheet/21576514fb.pdf)). It has two inputs labeled IN0 and IN1 on the SMA connectors. The inputs are DC coupled and 50 terminated. The optimum DC offset is reached when the input is driven from a 50 output impedance source. The peak-peak input range is 1 Vpp (between -500 and 500 mV). The inputs are protected by a transient voltage suppressor clamping over-voltages beyond ± 8 V.
The encoding clock of the ADC is provided by the RF_ADC_CLK of the clocking system. The output data are interfaced to the I/O Bank 34 of the FPGA. It consists of 14 LVDS pairs operating in double data rate. The maximum transfer rate per LVDS pair is thus 500 Msps. The transfer protocol is described in the LTC2157-14 datasheet (https://cds.linear.com/docs/en/datasheet/21576514fb.pdf).
A clock synchronous with the data ADC_CLKOUT is also connecting the Bank 34. The RF ADC is con gured by the con guration SPI bus. The source code of the corresponding C++ driver is on GitHub (https://github.com/Koheron/koheron- sdk/blob/master/boards/alpha250/drivers/ltc2157.hpp).
RF DAC
The RF Digital-to-Analog Converter has 2 outputs with 16-bit resolution and 250 Msps maximum sampling rate
(Analog Devices AD9747 (http://www.analog.com/media/en/technical- documentation/data-sheets/AD9743_9745_9746_9747.pdf)).
The outputs are labeled OUT0 and OUT1 on the SMA connectors. Output impedance is 50 . The outputs are protected by a transient voltage suppressor clamping over-voltages beyond ± 8 V. The output range is 1.5 Vpp maximum in a 50 load. It can be adjusted using the DAC gain on the con guration SPI bus. In the default con guration, the DAC outputs 1 Vpp in a 50 load.
The sampling clock of the DAC is provided by the RF_DAC_CLK of the clocking system. The input data lines are interfaced to the I/O Bank 35 of the FPGA. It consists of 32 single-ended lines at 3.3 V. The RF DAC is con gured by the con guration SPI bus. The source code of the corresponding C++ driver is on GitHub (https://github.com/Koheron/koheron- sdk/blob/master/boards/alpha250/drivers/ad9747.hpp).

Clocking

The clocking system is organized around the ultra-low phase noise clock generator (Texas Instruments LMK04906 (http://www.ti.com/lit/ds/snas589f/snas589f.pdf)). A dual PLL setup is used. The rst loop locks an ultra-low phase noise VCXO (ABLNO-V-100.000MHz) onto a reference clock. It serves as a phase-noise cleaner for the reference clock. The second loop locks the LMK04906 internal VCO (2.37 to 2.6 GHz) onto the VCXO. A set of clock dividers allows to produce up to six clocks at desired frequencies.
The clock generator is designed to accept 10 MHz reference clocks.
The reference clock sources are:

• The CLKI SMA input on the board. It is a 50 impedance input that accepts an AC voltage of up to 2.5 Vpp (10 dBm). It also supports up to 5 VDC. An onboard precision high-speed comparator (890 Mbps) provides effective clock recovery. It is ESD protected.
• The FPGA_CLK_OUT signal to discipline the system on a clock provided by the FPGA.
• The onboard 10 MHz temperature compensated voltage controlled crystal oscillator (TCVCXO). It has a tight stability (± 280 ppb over the industrial temperature range -40 to +85 °C). Its aging is ± 1 ppm per year maximum. A DAC controlled from the I2C0 bus can be used to precisely tune its frequency.

The clock generator produces the following clocks:

• An LVCMOS clock available on the board CLKO SMA output. This output is ESD protected.
• RF ADC sampling clock RF_ADC_CLK distributed as an LVDS signal.
• RF DAC sampling clock RF_DAC_CLK distributed as an LVDS signal.
• FPGA_CLK_IN is an LVDS input clock on the FPGA.
• EXP_CLK0 and EXP_CLK1 are LVDS clocks available on the expansion connector.
• The clock generator is con gured by the con guration SPI bus via the Clock Generator driver
  (https://github.com/Koheron/koheronsdk/blob/master/boards/alpha250/drivers /clock-generator.hpp).

Precis ion ADC

The precision ADC is a 8-channel, 24-bit sigma-delta ADC with programmable gain ampli er (Analog Devices AD7124-8
(http://www.analog.com/media/en/technical-documentation/data- sheets/AD7124-8.pdf)). The inputs differential pairs can be used to sense either oating or ground referenced signal. They also facilitate Kelvin sense connections. Differential input voltage range is ± 1.25 V.
The rst four channels are available on the expansion connector. The next four channels monitor the offsets of the RF ADC and RF DAC.
Communication with the precision ADC is done through a dedicated SPI bus. The precision ADC data can be retrieved using the PrecisionAdc driver (https://github.com/Koheron/koheron-sdk/blob/master/boards/alpha250/drivers /precision-adc.hpp).

Precision DAC
The precision DAC is a 4-channel, 16-bit DAC (Analog Devices AD5686 (http://www.analog.com/media/en/technicaldocumentation/data- sheets/AD5686_5684.pdf)).
The output voltage ranges from 0 to 2.5 V. It includes an output buffer that can deliver up to 20 mA per channel. The outputs are ESD protected.
The four output channels are available on the expansion connector. Communication with the precision DAC is done through a dedicated SPI bus via the PrecisionDac driver (https://github.com/Koheron/koheronsdk/blob/master/boards/alpha250/drivers /precision-dac.hpp).

Temperature sensors

The Alpha250 has two high-accuracy temperature sensors (TMP116 (http://www.ti.com/lit/ds/symlink/tmp116.pdf)) with an accuracy of ± 0.2 °C over -10 °C to +85 °C. One sensor is placed near the voltage reference (T0 highlighted in blue) to allow temperature compensation in high precision measurements. The other one is placed between the clock generator and the RF ADC which is close to the hottest point on the board (T1 highlighted in red).
The Zynq temperature T2 is also monitored using the XADC on the FPGA. The TemperatureSensor driver
(https://github.com/Koheron/koheron-sdk/blob/master/boards/alpha250/drivers /temperature-sensor.hpp) allows to retrieve the 3 above temperatures. For reliable operation, make sure that T1 < 70 °C and T2 < 85 °C.

Power monitors

The Alpha250 includes two power monitors (Texas Instruments INA230 (http://www.ti.com/lit/ds/symlink/ina230.pdf)). Two rails are monitored: the external 12 V power supply and the clocking subsystem supply. In both cases, the current shunt resistor is 10 m. Both power monitors are accessible on the I2C0 bus via the PowerMonitor driver (https://github.com/Koheron/koheronsdk/blob/master/boards/alpha250/drivers /power-monitor.hpp).
EEPROM
The Alpha250 has a 64-kbit EEPROM (Microchip 24AA64T-I/MC (http://ww1.microchip.com/downloads/en/DeviceDoc/21189K.pdf)).
It is accessible on the I2C0 bus via the Eeprom driver (https://github.com/Koheron/koheron- sdk/blob/master/boards/alpha250/drivers/eeprom.hpp).
The EEPROM is divided into two parts. The lower addresses are used by Koheron to store identi cation and calibration data. The higher addresses (above 0x1000) are for user applications. The EEPROM map addressing is given in the table below.

Zynq I/Os

The Zynq XC7Z020-2CLG400I has 2 I/O banks for the programmable logic (Banks 34 and 35) with 48 IOs each. One bank (Bank 0) is dedicated to the processing system with a multiplexed I/O (MIO) interface. The set of peripherals and interface buses is depicted below.
Zynq peripherals and communication buses.
I/O constraints are de ned in the ports.xdc le (https://github.com/Koheron/koheronsdk/blob/master/boards/alpha250/config/ports.xdc).

RF ADC parallel bus

The RF ADC is interfaced to the Bank 34 by a LVDS parallel bus. The data for each ADC channel are transferred in double data rate on a 7 line sub-bus. The RF ADC also provides a clock synchronous with the output data ADC_CLKOUT . The con guration is performed via the con guration SPI bus.

RF ADC (Bank 34)

set_property IOSTANDARD DIFF_HSTL_I_18 [getports adc*] set_property PACKAGE_PIN P19 [get_ports adc_clk_in_clk_n] set_property PACKAGE_PIN N18 [get_ports adc_clk_in_clk_p] # Channel 0
set_property PACKAGE_PIN U17 [get_ports {adc_0_n[0]}] set_property PACKAGE_PIN T16 [get_ports {adc_0_p[0]}] set_property PACKAGE_PIN Y19 [get_ports {adc_0_n[1]}] set_property PACKAGE_PIN Y18 [get_ports {adc_0_p[1]}] set_property PACKAGE_PIN P16 [get_ports {adc_0_n[2]}] set_property PACKAGE_PIN P15 [get_ports {adc_0_p[2]}] set_property PACKAGE_PIN W19 [get_ports {adc_0_n[3]}] set_property PACKAGE_PIN W18 [get_ports {adc_0_p[3]}] set_property PACKAGE_PIN P18 [get_ports {adc_0_n[4]}] set_property PACKAGE_PIN N17 [get_ports {adc_0_p[4]}] set_property PACKAGE_PIN W20 [get_ports {adc_0_n[5]}] set_property PACKAGE_PIN V20 [get_ports {adc_0_p[5]}] set_property PACKAGE_PIN U20 [get_ports {adc_0_n[6]}] set_property PACKAGE_PIN T20 [get_ports {adc_0_p[6]}] # Channel 1
set_property PACKAGE_PIN W13 [get_ports {adc_1_n[0]}] set_property PACKAGE_PIN V12 [get_ports {adc_1_p[0]}] set_property PACKAGE_PIN Y14 [get_ports {adc_1_n[1]}] set_property PACKAGE_PIN W14 [get_ports {adc_1_p[1]}] set_property PACKAGE_PIN P20 [get_ports {adc_1_n[2]}] set_property PACKAGE_PIN N20 [get_ports {adc_1_p[2]}] set_property PACKAGE_PIN R14 [get_ports {adc_1_n[3]}] set_property PACKAGE_PIN P14 [get_ports {adc_1_p[3]}] set_property PACKAGE_PIN W15 [get_ports {adc_1_n[4]}] set_property PACKAGE_PIN V15 [get_ports {adc_1_p[4]}] set_property PACKAGE_PIN T15 [get_ports {adc_1_n[5]}] set_property PACKAGE_PIN T14 [get_ports {adc_1_p[5]}] set_property PACKAGE_PIN Y17 [get_ports {adc_1_n[6]}] set_property PACKAGE_PIN Y16 [get_ports {adc_1_p[6]}] RF DAC parallel bus
The RF DAC is interfaced to the Bank 35 by a LVCMOS 3V3 parallel bus. The data for each channel are transferred on a 16 line subbus. The con guration is performed via the con guration SPI bus.

RF DAC (Bank 35)

set_property IOSTANDARD LVCMOS33 [getports dac] s
et_property DRIVE 8 [getports dac] set_property IOSTANDARD LVCMOS33 [getports dac] set_property DRIVE 8 [getports dac] # Channel 0 set_property PACKAGE_PIN D18 [get_ports {dac_0[0]}] set_property PACKAGE_PIN E17 [get_ports {dac_0[1]}] set_property PACKAGE_PIN E19 [get_ports {dac_0[2]}] set_property PACKAGE_PIN E18 [get_ports {dac_0[3]}] set_property PACKAGE_PIN A20 [get_ports {dac_0[4]}] set_property PACKAGE_PIN B19 [get_ports {dac_0[5]}] set_property PACKAGE_PIN F17 [get_ports {dac_0[6]}] set_property PACKAGE_PIN F16 [get_ports {dac_0[7]}] set_property PACKAGE_PIN B20 [get_ports {dac_0[8]}] set_property PACKAGE_PIN C20 [get_ports {dac_0[9]}] set_property PACKAGE_PIN L17 [get_ports {dac_0[10]}] set_property PACKAGE_PIN L16 [get_ports {dac_0[11]}] set_property PACKAGE_PIN D20 [get_ports {dac_0[12]}] set_property PACKAGE_PIN D19 [get_ports {dac_0[13]}] set_property PACKAGE_PIN G18 [get_ports {dac_0[14]}] set_property PACKAGE_PIN G17 [get_ports {dac_0[15]}] # Channel 1
set_property PACKAGE_PIN F20 [get_ports {dac_1[0]}] set_property PACKAGE_PIN F19 [get_ports {dac_1[1]}] set_property PACKAGE_PIN J16 [get_ports {dac_1[2]}] set_property PACKAGE_PIN K16 [get_ports {dac_1[3]}] set_property PACKAGE_PIN G20 [get_ports {dac_1[4]}] set_property PACKAGE_PIN G19 [get_ports {dac_1[5]}] set_property PACKAGE_PIN K18 [get_ports {dac_1[6]}] set_property PACKAGE_PIN K17 [get_ports {dac_1[7]}] set_property PACKAGE_PIN H20 [get_ports {dac_1[8]}] set_property PACKAGE_PIN J20 [get_ports {dac_1[9]}] set_property PACKAGE_PIN M18 [get_ports {dac_1[10]}] set_property PACKAGE_PIN M17 [get_ports {dac_1[11]}] set_property PACKAGE_PIN H18 [get_ports {dac_1[12]}] set_property PACKAGE_PIN J18 [get_ports {dac_1[13]}] set_property PACKAGE_PIN G15 [get_ports {dac_1[14]}] set_property PACKAGE_PIN H15 [get_ports {dac_1[15]}] Con guration SPI bus
A shared SPI bus is dedicated to the con guration of the RF ADC, the RF DAC and the clock generator. In the reference design, a HDL core is used for the communication on this bus. The interface is described below.
Con guration SPI bus.
Constraint le The con guration SPI bus pins are connected to Bank 34 with 1.8 V LVCMOS signals.

Configuration SPI (Bank 34)

set_property IOSTANDARD LVCMOS18 [get_ports spicfg*] set_property PACKAGE_PIN R17 [get_ports spi_cfg_sdo] set_property PACKAGE_PIN R16 [get_ports spi_cfg_sdi] set_property PACKAGE_PIN W16 [get_ports spi_cfg_sck] set_property PACKAGE_PIN V16 [get_ports spi_cfg_cs_rf_adc] set_property PACKAGE_PIN U12 [get_ports spi_cfg_cs_rf_dac] set_property PACKAGE_PIN T12 [get_ports spi_cfg_cs_clk_gen] Transfer core
The core is write only. It does not read back con gurations from the chips. The s_axis_tready signal can be used to determine when the core nishes sending a message and is ready to send a new one.
The core can send 1, 2, 3 or 4 bytes of data. The number of bytes to transfer is speci ed using the bits B2 and B3 of the cmd byte according to the table below.

Configuration SPI byte transfer count.
The chip select address is specified using the bits B0 and B1 of the cmd byte according to the table below.

Confi guration SPI chip select address.
The transferred data must be wired to the s_axis_tdata pin. The transfer is triggered on the s_axis_tvalid pin falling edge. The core is controlled via the SpiConfig driver (https://github.com/Koheron/koheron- sdk/tree/master/boards/alpha250/drivers/spi-config.hpp).

Precision ADC SPI bus
A dedicated SPI is used for the communication with the precision ADC. The bus is connected to PL I/Os on bank 34. Constraint le The precision ADC SPI pins are connected to the Bank 34 with 1.8 V LVCMOS signals.

Precision ADC (Bank 34)

set_property IOSTANDARD LVCMOS18 [get_ports spi_precisionadc*] set_property PACKAGE_PIN U13 [get_ports spi_precision_adc_cs] set_property PACKAGE_PIN V13 [get_ports spi_precision_adc_sck] set_property PACKAGE_PIN T11 [get_ports spi_precision_adc_sdi] set_property PACKAGE_PIN T10 [get_ports spi_precision_adc_sdo] Data transfer
In the reference design, the precision ADC SPI bus is connected to the SPI0 PS core.
This is done using the EMIO interface which allows to connect PL signals to the MIO interface of the PS. It can be controlled using the PrecisionAdc driver
(https://github.com/Koheron/koheron-sdk/tree/master/boards/alpha250/drivers /precision-adc.hpp).
Precision DAC SPI bus
Data is transferred to the precision DAC using a SPI bus that can be clocked up to 50 MHz. In addition, a latched pin LDAC pin is used to update the 4 channel outputs synchronously. In the reference design, a dedicated HDL core is used. The interface is shown below.
Constraint file
The precision DAC SPI pins are connected to the Bank 34 with 1.8 V LVCMOS signals.

Precision DAC (Bank 34)

set_property IOSTANDARD LVCMOS18 [get_ports spi_precisiondac*] set_property PACKAGE_PIN V17 [get_ports spi_precision_dac_cs] set_property PACKAGE_PIN V18 [get_ports spi_precision_dac_sck] set_property PACKAGE_PIN T17 [get_ports spi_precision_dac_sdi] set_property PACKAGE_PIN R18 [get_ports spi_precision_dac_ldac] Transfer core
While the valid is high, the core updates the DAC channels with the values on pin data . The 64 bits of the data pin contain the concatenation of the 4 x 16 bits values to be set on the 4 channels. Channel 0 being on the 16 least signi cant bits, followed by channels 1, 2 and 3.
After sending the data for the 4 channels, the core latches ldac . The data will be synchronously updated if cmd = 1. If cmd = 3, the output is updated as new values arrive. The core (https://github.com/Koheron/koheronsdk/tree/master/boards/alpha250/cores/precision_dac_v1_0) is written in Verilog.
It is controlled with the PrecisionDac driver (https://github.com/Koheron /koheron-sdk/tree/master/boards/alpha250/drivers/precision-dac.hpp).
PS cores
The processing system contains hard cores (by opposition with the soft cores that can be deployed on the PL). The PS cores are interfaced with MIO pins on Bank 0. The logic level is LVCMOS 1.8 V. MIO con guration can be found in the board con guration file
(https://github.com/Koheron/koheron- sdk/tree/master/boards/alpha250/config/board_preset.tcl).

The constraints le for the PS is:
set_property CFGBVS GND [current_design] set_property CONFIG_VOLTAGE 1.8 [current_design] I2C0
This bus is used on the Alpha250 internally and is not accessible from the expansion connector. The I2C0 bus addressing is:

• 1100100 / 1011100 : Secure EEPROM
• 1010001 : RTC registers
• 1010100 : User EEPROM
• 0100000 : GPIO expander
• 1000001 : Main power supply monitor
• 1000101 : Clocking subsystem supply monitor
• 1001000 : Voltage reference temperature sensor
• 1001001 : Board temperature sensor
• 0101111 : TCXO control voltage

I2C1
The I2C1 bus is for the expansion connector. A 3.3 V level shifter with 2.2 k pull-ups provides the interface with the Bank 0.
The I2C1 core can be replaced by a CAN core CAN0 with proper PS con guration.
ENET0
The ethernet peripheral is interfaced with the ENET0 MAC core.
USB0
The USB 2 connector is interfaced with the USB0 core.
SD0
The SD card is interfaced with the SD0 core.
UART0
The serial port debugging USB interface connects to the UART0 core.

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References

• koheron-sdk/ad9747.hpp at master · Koheron/koheron-sdk · GitHub
• koheron-sdk/eeprom.hpp at master · Koheron/koheron-sdk · GitHub
• koheron-sdk/ltc2157.hpp at master · Koheron/koheron-sdk · GitHub
• koheron-sdk/precision-adc.hpp at master · Koheron/koheron-sdk · GitHub
• koheron-sdk/temperature-sensor.hpp at master · Koheron/koheron-sdk · GitHub
• koheron-sdk/precision-adc.hpp at master · Koheron/koheron-sdk · GitHub
• koheron-sdk/precision-dac.hpp at master · Koheron/koheron-sdk · GitHub

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