Digital control board documentation

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This documentation covers the most important things to know while testing the digital control board, including component pinouts, nets, and other information.

Power Requirements

Required Voltages

All components on the digital board except the DAC can be tested using only a +5V source. The DAC requires +5V, -5V, and a high voltage corresponding to 10V higher than the maximum desired DAC output voltage (see Setting the Output Range). Digital and analog grounds must be connected as well before any testing takes place.

Power Pins

Power shall be connected to the board as follows:

Voltage Eurocard Pin
DGND A6
AGND A5
+5V A4
-5V A3
High voltage
(DAC max out +10)
A2

Power Supply Sequencing

The control board is designed such that voltages may be supplied in any order so long as AGND and DGND are connected properly. However, for initial testing, the preferred order for powering up the board is as follows:

  1. Ensure AGND/DGND are connected/grounded
  2. +5V
  3. -5V
  4. High voltage

FPGA

The control board uses a Xilinx XC3S50A VQ100 FPGA. It has a 100 pin footprint and is located in the center of the control board.

Power Details

The FPGA is powered by the 3.3V power plane, which is regulated by VR1. The FPGA also obtains 1.2V for its internal logic from a 1.2V power island, regulated by VR3.

Logic Standard

The Xilinx XC3S50A supports several different digital logic standards. The control board is hard wired such that the FPGA will use a 3.3V CMOS logic standard.

Pinout Table

Pin # Net Name Signal Name Description
P1 FPGA/TMS [JTAG] JTAG
P2 FPGA/TDI [JTAG] JTAG
P3 AD7928/CS SPI_A_iCS SPI chip select for ADC
P4 SPI SPI_SDI Corrected
P5 CLK_5MHZ SPI_SCLK 5 MHz clock output for SPI bus (ADC and temp. sensor)
P6 No connection
P7 No connection
P8 DGND
P9 No connection
P10 No connection
P11 +3.3V
P12 No connection
P13 No connection
P14 DGND
P15 No connection
P16 No connection
P17 +1.2V
P18 DGND
P19 dBinfo_Start
P20 dBinfo_Stream
P21 No connection
P22 +3.3V
P23 DGND [M1: JTAG prog. config.]
P24 DGND [M2: JTAG prog. config.]
P25 DGND [M0: JTAG prog. config.]
P26 +3.3V
P27 FPGA/CLK_IN fClk 20 MHz clock input from crystal oscillator
P28 No connection
P29 No connection (db) state_Q(0)
P30 No connection
P31 No connection (db) state_Q(1)
P32 No connection
P33 No connection (db) state_Q(2)
P34 No connection
P35 CP2201/INT Eth_iINT Ethernet controller interrupt
P36 MASTER_RESET Rst Connects to RESET jumper in upper left of board (active-low, externally pulled up)
P37 (manually wired) fClk_out
P38 +1.2V
P39 No connection
P40 CP2201/CS iCS Chip select for ethernet controller
P41 CP2201/WR iWR Write enable for ethernet controller
P42 DGND
P43 CP2201/RD iRD Read enable for ethernet controller
P44 CP2201/ALE ALE Address line enable for ethernet controller
P45 +3.3V
P46 CP2201/RESET Eth_iRst Reset pin for ethernet controller
P47 DGND
P48 FPGA/INIT_B [JTAG] Used during FPGA configuration - see Xilinx documentation
P49 CP2201/AD0 AD(0) Ethernet controller address/data bus, bit 0
P50 CP2201/AD1 AD(1) Ethernet controller address/data bus, bit 1
P51 FPGA/DIN [JTAG] Serial data input from EEPROM for configuration
P52 CP2201/AD2 AD(2) Ethernet controller address/data bus, bit 2
P53 FPGA/CCLK [JTAG] Configuration clock (signal generated by FPGA at
power on to clock the configuration process)
See Xilinx documentation
P54 FPGA/DONE [JTAG] Gives configuration status - see Xilinx documentation
P55 +3.3V
P56 CP2201/AD3 AD(3) Ethernet controller address/data bus, bit 3
P57 CP2201/AD4 AD(4) Ethernet controller address/data bus, bit 4
P58 DGND
P59 CP2201/AD5 AD(5) Ethernet controller address/data bus, bit 5
P60 CP2201/AD6 AD(6) Ethernet controller address/date bus, bit 6
P61 CP2201/AD7 AD(7) Ethernet controller address/date bus, bit 7
P62 No connection
P63 DGND
P64 No connection
P65 No connection
P66 +1.2V
P67 +3.3V
P68 +3.3V
P69 DGND
P70 ID3 LocStamp(3) Backplane location identifier jumper, pins 3 & 4
Active-low, FPGA should pull high
P71 ID2 LocStamp(2) Backplane location identifier jumper, pins 5 & 6
Active-low, FPGA should pull high
P72 ID1 LocStamp(1) Backplane location identifier jumper, pins 7 & 8
Active-low, FPGA should pull high
P73 ID0 LocStamp(0) Backplane location identifier jumper, pins 9 & 10
Active-low, FPGA should pull high
P74 DGND
P75 FPGA/TDO [JTAG] JTAG
P76 FPGA/TCK [JTAG] JTAG
P77 ID4 LocStamp(4) Backplane location identifier jumper, pins 1 & 2
Active-low, FPGA should pull high
P78 No connection
P79 +3.3V
P80 DGND
P81 +1.2V
P82 No connection (db) dbShort Shorts out the waiting timer in FPGA for Ethernet controller initialization (pulled low)
P83 CLK_5MHZ_2 DAC_Clk 5 MHz clock output for DAC
P84 No connection
P85 AD5535/DIN DAC_serData DAC serial data input (FPGA out -> DAC in)
P86 No connection
P87 DGND
P88 AD5535/SYNC DAC_setISync
P89 No connection
P90 No connection
P91 DGND
P92 +3.3V
P93 AD7314/CE SPI_TCE Chip enable for temperature sensor
P94 No connection
P95 DGND
P96 +3.3V
P97 SPI_SDI Corrected
P98 AD5535/RESET DAC_iRst Reset pin for DAC
P99 DGND PUDC_B pin - enables pullup resistors on user IO and input-only pins during FPGA config.
P100 FPGA/PROG_B [JTAG] Used during FPGA configuration - see Xilinx documentation

EEPROM

To facilitate power-on configuration of the FPGA, the control board includes a Xilinx XCF01S EEPROM. The EEPROM is located to the left of the FPGA, above the JTAG header, and has a 20 pin footprint. The EEPROM is labelled U5.

Power Details

The EEPROM uses +3.3V exclusively, which it receives from the +3.3V power plane, regulated by VR1.

Flashing/Burning/Writing

Whatever you call it, this refers to storing data in the EEPROM so that it can configure the FPGA at power-on. The EEPROM is programmed using a JTAG interface and the Xilinx Platform USB II cable. It is important to note that in digital board's JTAG chain, the EEPROM is the first device in the chain, unlike in the Xilinx documentation where it is shown as the second device. This should not affect the operation of the board, but should be reflected in the Xilinx software when writing the EEPROM via JTAG.

FPGA Configuration

The EEPROM and FPGA are hardwired to use a master serial protocol to transfer the program from the EEPROM to the FPGA. This is the protocol recommended in the Xilinx documentation because it minimizes the number of traces necessary to run between the EEPROM and FPGA. All configuration data is sent over a single trace, FPGA/DIN (pin 1 on EEPROM), controlled by the configuration clock signal (FPGA/CCLK) which is automatically generated by the FPGA at power-on. When configuration is complete, FPGA/DONE (pin 10) is pulled high by the FPGA, and the EEPROM and configuration clock are deactivated.

Pinout Table

Pin # Net Name Description
1 FPGA/DIN Serial data line
Carries data from the EEPROM to the FPGA
2 No connection
3 FPGA/CCLK Configuration clock
Auto generated by FPGA at power-on, disabled at end of configuration
4 EEPROM/TDI This is the EEPROM's TDI
This is the entry point for the onboard JTAG chain
5 FPGA/TMS JTAG TMS
Connects to both FPGA and EEPROM
6 FPGA/TCK JTAG TCK
Connects to both FPGA and EEPROM
7 FPGA/PROG_B Used during configuration
See Xilinx documentation
8 FPGA/INIT_B Used during configuration - can be used to intiate reconfiguration of FPGA
See Xilinx documentation
9 No connection
10 FPGA/DONE Indicates completion of FPGA configuration
High when complete
11 DGND
12-16 No connection
17 FPGA/TDI This is the EEPROM's TDO/FPGA's TDI
18-20 +3.3V

JTAG Header

To write the FPGA's program to the EEPROM, the board employs a JTAG based programming system consistent with Xilinx's recommendations. The system is designed to operate with Xilnx's Platform USB II cable and the flying lead adapter.

Header Location and Size

The header consists of 14 pins, 100 mil pitch, just below the EEPROM (U5). The header is labelled P1. The pitch of the pins in the header was erroneously selected to be 100 mil, which is not compatible with Xilinx's JTAG ribbon cable. Therefore, the Xilinx flying lead adapter must be used.

Power Details

The JTAG interface is powered by the +3.3V power plane, not by the computer's USB port. Power is supplied through pin 2 of the JTAG header.

Pinout Table

Note that the header is positioned on the board rotated 180 degrees from the position in which it is shown in the Xilinx documentation. Care must be taken when connecting the flying leads to ensure they are connected to the right pins. Improper wiring will certainly cause undesired operation, and may cause damage as well. Damage is most likely to occur if one of the flying leads is improperly connected to an odd numbered pin, since it will short to the PCB's ground plane.

Pin # Net Name Flying Lead Description
1, 3, 5, 7, 9, 11, 13 (odd pins) DGND Black (connect to any odd numbered pin) Ground pins for signal integrity
Never connect a flying lead other than the black lead to an odd numbered pin
Doing so will short to ground and may cause permanent damage if the Platform USB II cable does not have protection against this.
2 +3.3V Red/VREF Power source for all JTAG logic
4 FPGA/TMS Green/TMS JTAG TMS - connects to EEPROM and FPGA
6 FPGA/TCK Yellow/TCK JTAG TCK - connects to EEPROM and FPGA
8 FPGA/TDO Purple/TDO JTAG boundary scan chain endpoint
10 EEPROM/TDI White/TDI JTAG boundary scan chain start point
12 No connection Pin is floating
14 No connection Pin is floating

The gray HALT flying lead is not connected.

JTAG Overview

The JTAG interface is clocked by the TCK signal. TCK is generated by the Platform USB II cable, and connects directly from the JTAG header to both the EEPROM and FPGA.

The TMS signal is directly connected to both the EEPROM and FPGA, and is the data line over which JTAG test results (in this case programming results) are sent. TMS is used by only one component at a time.

The TDI/TDO lines form a chain that connects to each JTAG component in series. On the control board, the first point in the chain is the EEPROM's TDI. Next is the EEPROM's TDO, which is the same as the FPGA's TDI. The FPGA's TDO then returns to the JTAG header and the Platform USB II cable.

DAC

The control board uses the Analog Devices AD5535, 32-channel, 200V max, digital to analog converter. This chip has a modified BC-124 BGA footprint and is located above the Eurocard connector at the bottom of the board. It is labelled U3.

Power Details

The DAC is primarily powered by the +5V power island, regulated by an off-board power supply and extensively decoupled in the area of the DAC. The DAC also requires -5V, and a high voltage as discussed in Power Requirements. Both of these voltages are supplied by an off-board supply and decoupled near the DAC. In addition to these voltage levels, the DAC requires a precise +2.5V reference, created by the shunt-type voltage reference VR4.

Setting the Output Range

The output range of the DAC is set by the 2.5V reference voltage supplied by VR4. The high voltage power supply must supply at a minimum 50 times this voltage, plus 10. Thus, the high voltage power supply should be at least 135V for DAC to operate properly, even though the SiPMs are expected to need only 40V. If it is convenient to use a lower high voltage, VR4 must be replaced to provide lower reference voltage. The high voltage may then be decreased appropriately. To summarize:

  • Max output voltage = VREF*50
  • Minimum high voltage supply = VREF*50 + 10
  • Acceptable range for VREF
    • Min: 1V
    • Max: 3.75V (AD5535 datasheet specifies 4V max, but this would require AVCC of 5.25V for the DAC, which is not possible in the current board design)

If relevant, R13 is a 100K resistor.

Thermal Diode

The DAC has a built in thermal diode. The diode drop from anode to cathode is typically 0.65V at 25°C. It changes at a rate of -2.20mV/°C. The anode of this diode is connected to the +5V power island, and the cathode is connected to a 270K resistor to ground. The voltage between the cathode and the resistor is connected to VIN1 (pin 15) on the ADC.

Pinout Table

See documentation from Analog Devices.

Channel Mapping

Due to the layout of the balls on the footprint of the DAC, the DAC's internal channel numbers (which must be referenced by the FPGA) have no correlation to the channel numbers on the amplifier board. This table summarizes the mapping between various pins that belong to each channel.

DAC Channel # DAC Pin # Digital Board Eurocard Pin # Amplifier Board Eurocard Pin # Amplifier Channel #
0 B1 B3 B6 6
1 A2 C4 B7 7
2 D1 B2 B4 4
3 C2 C3 B5 5
4 B3 B4 B8 8
5 E2 C2 B3 3
6 F3 B1 B2 2
7 A4 B5 B10 10
8 E4 C5 B9 9
9 B5 C6 B11 11
10 F5 C1 B1 1
11 A6 C7 B13 13
12 E6 B6 B12 12
13 B7 B7 B14 14
14 F7 C10 B19 19
15 E8 C8 B15 15
16 A8 B8 B16 16
17 B9 C9 B17 17
18 F9 C16 B31 GAINMODE
19 E10 B11 B22 22
20 A10 B9 B18 18
21 B11 B10 B20 20
22 C12 B12 B24 24
23 D13 B13 B26 26
24 E12 B14 B28 28
25 A12 C11 B21 21
26 B13 C12 B23 23
27 H13 B16 B30 30
28 G14 B15 B27 27
29 C14 C13 B25 25
30 F13 C15 B29 29
31 E14 C14 Not connected No amplifier connection
DACHEALTH
See ADC Channel Descriptions.

ADC

The board includes an Analog Devices AD7928 analog to digital converter. The ADC is located just to the right and slightly below the FPGA. It is labelled U4.

Power Details

The ADC is powered by the +5V power island, which is regulated by an off-board power supply and decoupled near the ADC. It also requires a precise (±1%) 2.5V reference to which it compares voltages when converting from analog to digital. Since the +5V power source is not used for comparison, it is flexible and may vary by ±0.25V without affecting ADC precision.

Setting the Measuring Range

The measuring range is set programmatically by the FPGA over the SPI bus. The way the ADC is connected on the digital board requires that its measuring range be set to 5V, so the RANGE bit should be set to 1 by the FPGA (see Analog Devices documentation).

Data Interfacing

The ADC uses an SPI bus to communicate with the FPGA. This bus is shared with the temperature sensor. SPI related pins include SCLK, CS, DIN, and DOUT. See the Pinout Table below.

Channel Descriptions

This table shows what signals are monitored by the ADC.

ADC Channel # ADC Pin # Net Name Description
VIN0 16 AD7928/VHEALTH This net helps to monitor to overall health of power on the board, but is specifically intended to monitor -5V. It's voltage is the output of a resistor divider between the +5 and -5V power supplies, with resistor values of 33.2K, and 100K. Assuming +5V and -5V are both correct, the output of the divider will be +2.51V. A reading of other than 2.51V indicates a problem with one of the power supplies. Problems with the +5V power supply can be ruled out by reading VIN3. Based on the reading from VIN3, the voltage of the -5V supply can be calculated.
VIN1 15 AD5535/CATHODE This is the thermal diode output from the DAC. Should read 4.35V (typical) at 25°C. Drops -2.20mV/°C.
VIN2 14 +3.3V This is the +3.3V power plane. A reading of other than +3.3V indicates a problem with VR1.
VIN3 13 +5V This is the +5V power island. A reading of other than +5V indicates a problem with the +5V power supply.
VIN4 12 ADC_EXT1 This trace routes to the backplane via Eurocard pin A8. It is intended to measure one of the transistor base voltages on the amplifier board.
VIN5 11 +1.2V This is the +1.2V power island. This island powers the internal logic of the FPGA. A reading of other than 1.2V indicates a problem with VR3.
VIN6 10 ADC_EXT2 This trace routes to the backplane via Eurocard pin A7. It is intended to measure the output of thermistor on the amplifier board.
VIN7 9 DACHEALTH This channel monitors the output of a resistor divider connected to channel 31 of the DAC. The divider consists of three resistors of 200K, 200K, and 10.2K (in order). The ADC reads out the voltage level between the second 200K and then 10.2K resistor. These resistors were selected so that at 200V, the readout voltage will be 4.973V. Since the divider should be linear, the expected voltage at 20V is 0.4973V. Three resistors were used rather than two to avoid exceeding the resistors' power ratings when the DAC is set to its maximum voltage. Note that since this divider will consume up to 484uA of current at 200V, this DAC channel should not be used for anything that might require more than ~200uA of current (the DAC can source 700uA max). The channel is routed to the backplane nonetheless.

Pinout Table

Pin # Net Name Description
1 CLK_5MHZ SPI clock (SCLK), from FPGA
Shared with temperature sensor
2 DIN SPI data in, from FPGA
Shared with temperature sensor
Currently wired wrong
3 CS SPI chip select
4 AGND
5 +5V Power pin
6 +5V Power pin
7 AD7928/REF_IN +2.5V reference, set by VR2
8 AGND
9-16 VIN[7:0] See ADC Channel Descriptions
17 AGND
18 DOUT SPI data out
Currently wired incorrectly
19 +3.3V VDRIVE, powers the SPI logic
20 AGND

Ethernet Controller

The board uses a Silicon Laboratories CP2201, 28-pin, ethernet controller. The CP2201 is located just above the FPGA, and is labelled U2.

Power Details

The CP2201 uses only +3.3V, which is supplied by the +3.3V power plane and regulated by VR1. Appropriate decoupling capacitors can be found near the CP2201.

Ethernet Jack

To the right of the CP2201 is a Pulse J0011D21NL ethernet jack, labelled J1. This jack has a built-in 1:1 inductive coupling. For best results, connect this jack to a nearby ethernet switch. The jack may also be connected directly to a computer using a crossover cable. Though auto-crossover is not supported by the CP2201, if the computer's NIC supports it, a crossover cable is not necessary to connect directly to a computer.

Ethernet Jack Pins

These are visible only on the back side of the board. Pin 1 is indicated by a square pad. Pin 8 is the farthest pin from pin 1. Pins are numbered such that the 4 pins closer to the plastic thru-hole connectors are odd (1, 3, 5, 7), and the four pins closer to the CP2201 are are even (2, 4, 6, 8).

  • Pin 1: TX+
  • Pin 2: AC coupled to DGND
  • Pin 3: TX-
  • Pin 4: RX+
  • Pin 5: AC coupled to DGND
  • Pin 6: RX-
  • Pin 7: No connection
  • Pin 8: DGND (direct)

The two large thru-hole pins (not numbered) connect to the metal shielding on the outside of the jack. These are directly connected to DGND to shield against electrical noise inside the jack.

The two plastic thru-hole pins are not conductive and have no electrical connection. They are present only for structural purposes, presumably to prevent stress on the solder points when an ethernet wire is inserted or removed from the jack.

Crystal Oscillator

The CP2201 is responsible for driving the 20MHz crystal oscillator. This oscillator clocks both the CP2201 and the FPGA. The crystal oscillator can be found above the right corner of the FPGA. It can be identified by its four surface mount pads and roughly .3" length. It is labelled Y1, though this label is not visible after the oscillator is soldered on. The CP2201 uses an inverting driver to excite the crystal. The output of the crystal is then sent to the CP2201 and the FPGA.

Bus Format and Multiplexing

The 28-pin CP2201 used on the board only supports multiplexed operation. This means that both address and data information are passed over the same set of 8 traces. Hence, these traces are referred to as the address/data (AD) bus. A separate address line enable (ALE) trace prevents collisions from occuring on these traces. The communication protocol used is the Intel format. See the CP2201's datasheet for more information about this.

Pinout Table

Pin # Net Name Description
1 CP2201/LA Link/activity indicator
Routed to backplane but not implemented
See CP2201 data sheet for information on how to connect to an LED
2 DGND By the data sheet, this pin should be AGND
We deliberately set it to DGND to avoid noise on AGND plane
3 +3.3V AV+ power pin
4 CP2201/RX- Connects to RX- on ethernet jack
5 CP2201/RX+ Connects to RX+ on ethernet jack
6 CP2201/TX+ Connects to TX+ on ethernet jack
7 CP2201/TX- Connects to TX- on ethernet jack
8 +3.3V "VDD" power pin
9 DGND "DGND1" per the data sheet
10 CP2201/RESET "RST" per the data sheet
Connects to FPGA - should be programmatically triggered upon reset of FPGA by RESET jumper
11-18 CP2201/AD[0:7] Bits 0-7 of the address/data bus
Connect to FPGA
19 +3.3V "VDD" power pin
20 DGND "DGND2" per the data sheet
21 CP2201/ALE Address line enable
Connects to FPGA
See CP2201 documentation
22 CP2201/RD Read strobe for AD bus
Connects to FPGA
See CP2201 documentation
23 CP2201/WR Write strobe for AD bus
Connects to FPGA
See CP2201 documentation
24 CP2201/CS Chip select
Connects to FPGA
25 CP2201/INT Interrupt request
Connects to FPGA
26 DGND "MOTEN" (Motorola enable) per the datasheet
Tied low to disable Motorola bus format (enable Intel format)
27 CP2201/XTAL2 Crystal oscillator driver
The CP2201 inverts the 20MHz clock signal and feeds it back to the crystal oscillator to encourage larger oscillations
28 FPGA/CLK_IN "XTAL1" per the data sheet
This is the 20MHz clock input
Also connects to the FPGA's clock input
29* DGND This is not a pin but rather the base of the CP2201 package.
It is connected to the DGND plane for thermal relief

Eurocard Connector

At the bottom of the control board is the Eurocard connector, labelled P2. The Eurocard connector connects the board to the backplane and also connects the board to its power supplies. The Eurocard has 48 pins arranged in three rows of 16 pins each. Rows B and C are exclusively used to pass SiPM bias voltages to the backplane as described in DAC Channel Mapping. Here is a table describing the purpose of pins in row A:

Row A Pinout Table

Note that when viewing the front side of the board with the Eurocard at the bottom, these pins go from right to left. If you look closely at the pins, you will see that pin A1 has a square pad, unlike the round pads of the others.

Pin # Net Name Description
A1 CP2201/LA Ethernet link/activity indicator routed to backplane
A2 High voltage input (+210V max) High voltage input for DAC. See DAC for information about what voltage to input here.
A3 -5V For DAC
A4 +5V Powers most things on the board
A5 AGND
A6 DGND
A7 ADC_EXT1 Connects to ADC to monitor voltages on amplifier board
See ADC
A8 ADC_EXT2 Connects to ADC to monitor voltages on amplifier board
See ADC
A9 No connection
A10 No connection
A11 No conneciton
A12 ID4 Location identifier bit 4
Used to identify which backplane board is connected to
See FPGA
A13 ID3 Location identifier bit 3
Used to identify which backplane board is connected to
See FPGA
A14 ID2 Location identifier bit 2
Used to identify which backplane board is connected to
See FPGA
A15 ID1 Location identifier bit 1
Used to identify which backplane board is connected to
See FPGA
A16 ID0 Location identifier bit 0
Used to identify which backplane board is connected to
See FPGA