Standards/HEI 'VME' Backplane Bus

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(2 Row - 64Pin functionality (HVME16))
 
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| style="background:#7ac1ff" | D05
 
| style="background:#7ac1ff" | D05
 
| style="background:#c6efce" | A13
 
| style="background:#c6efce" | A13
| style="background:#7ac1ff" | D14
+
| style="background:#7ac1ff" | D13
 
|-
 
|-
 
! 07
 
! 07
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|-
 
|-
 
! 10
 
! 10
| style="background:#ff3a3f" | <span style="color:#FFFFFF">MCLK</span>
+
| style="background:#ff3a3f" | <span style="color:#FFFFFF">MCLK<sup>1</sup></span>
 
| style="background:#7ac1ff" | D17
 
| style="background:#7ac1ff" | D17
 
| style="background:#ff3a3f" | <span style="color:#FFFFFF">RST</span>
 
| style="background:#ff3a3f" | <span style="color:#FFFFFF">RST</span>
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|-
 
|-
 
! 12
 
! 12
| style="background:#ffaaff" | MFREEZE
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| style="background:#ffaaff" | MFREEZE<sup>1</sup>
 
| style="background:#7ac1ff" | D19
 
| style="background:#7ac1ff" | D19
 
| style="background:#ffaaff" | EN
 
| style="background:#ffaaff" | EN
 
|-
 
|-
 
! 13
 
! 13
| style="background:#ffaaff" | SREADY
+
| style="background:#ffaaff" | SREADY<sup>1</sup>
 
| style="background:#7ac1ff" | D20
 
| style="background:#7ac1ff" | D20
 
| style="background:#DA9694" | UART_RXD
 
| style="background:#DA9694" | UART_RXD
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! 16
 
! 16
 
| style="background:#7fff7a" | <span style="color:#000000">WCLK0</span>
 
| style="background:#7fff7a" | <span style="color:#000000">WCLK0</span>
| style="background:#7ac1ff" | D23
+
| style="background:#7ac1ff" | D23<sup>1</sup>
 
| style="background:#ffcc77" | IRQ10 / ECC00
 
| style="background:#ffcc77" | IRQ10 / ECC00
 
|-
 
|-
 
! 17
 
! 17
 
| style="background:#3f3f3f" | <span style="color:#FFFFFF">'''GND_N'''</span>
 
| style="background:#3f3f3f" | <span style="color:#FFFFFF">'''GND_N'''</span>
| style="background:#7ac1ff" | D24
+
| style="background:#7ac1ff" | D24<sup>1</sup>
 
| style="background:#ffcc77" | IRQ9 / ECC01
 
| style="background:#ffcc77" | IRQ9 / ECC01
 
|-
 
|-
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| style="background:#b1a0c7" | SPI_CLK
 
| style="background:#b1a0c7" | SPI_CLK
 
| style="background:#cccccc" | <span style="color:#000000">'''GND_F'''</span>
 
| style="background:#cccccc" | <span style="color:#000000">'''GND_F'''</span>
| style="background:#ffcc77" | IRQ8 / ECC02
+
| style="background:#ffcc77" | IRQ8 / ECC02<sup>1</sup>
 
|-
 
|-
 
! 19
 
! 19
 
| style="background:#3f3f3f" | <span style="color:#FFFFFF">'''GND_N'''</span>
 
| style="background:#3f3f3f" | <span style="color:#FFFFFF">'''GND_N'''</span>
 
| style="background:#7fff7a" | <span style="color:#000000">WCLK1</span>
 
| style="background:#7fff7a" | <span style="color:#000000">WCLK1</span>
| style="background:#cccccc" | <span style="color:#000000">'''GND_F'''</span>
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| style="background:#cccccc" | <span style="color:#000000">'''GND_F'''<sup>1</sup></span>
 
|-
 
|-
 
! 20
 
! 20
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! 21
 
! 21
 
| style="background:#b1a0c7" | SPI_MOSI
 
| style="background:#b1a0c7" | SPI_MOSI
| style="background:#ffcc77" | ECC06
+
| style="background:#ffcc77" | ECC06<sup>1</sup>
 
| style="background:#ffcc77" | IRQ7 / ECC03
 
| style="background:#ffcc77" | IRQ7 / ECC03
 
|-
 
|-
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| style="background:#3f3f3f" | <span style="color:#FFFFFF">'''+5V_F'''</span>
 
| style="background:#3f3f3f" | <span style="color:#FFFFFF">'''+5V_F'''</span>
 
|}
 
|}
 +
 +
<sup>1</sup> These pins connect to a GCLK pin on the FPGA
  
 
== Timing diagrams ==
 
== Timing diagrams ==

Latest revision as of 15:32, 5 April 2017

Contents

Based on the VMEbus and inspired by the ARM AMBA3 AHB-Lite, this backplane bus is synchronous and master-slave oriented.

Bus Specifications

The table below presents its signals, which can be divided into three groups:

  • The main parallel bus
  • Some serial buses (UART, SPI, I2C)
  • The power supply

The main parallel bus is like a CPU bus, with address and data. All operations are synchronous relatively to the main clock MCLK. The master can write or read on slaves, via the usage of the signals Axx (address), Dxx (data), WR (write/read operation flag), and EN (enable operation). Please note that the data bus is bidirectional.

For applications with less data bandwidth but higher data integrity specifications, a Hamming error correction code can be used for manage small errors (2-bit error detection, 1-bit error correction). The extra signals managing the ECC functionality (bidirectional) and the MFREEZE / SREADY flags (asynchronous).

Signal Width Driver Description
Axx 8/16 bit Master Address bus
Dxx 16/32 bit Master/Slave Data bus
ECCxx 6/8 bit Master/Slave ECC bits (7 Hamming Bits + 1 Parity Bit)
MCLK 1 bit Master Main bus clock
RST 1 bit Master ReSeT. Allow the master to reset all slaves racks.
EN 1 bit Master Enables bus transaction.
WR 1 bit Master WRite operation when set, else read operation.
SREADY 1 bit Slave Slave READY. Pulled low by slave when not ready or when ECC error occurs.
MFREEZE 1 bit Master Master FREEZE. Set by the master for freeze the bus when ECC error occurs.
MODE 1 bit Master '1' is 64k*32bit slave card and '0' 256*16bit slave card. Used as MSB bit of address.
WCLKx 2 bit Undef. Additionnal clock lines.
IRQxx 8 bit Undef. User-defined interrupt bits.
UART_TXD 1 bit Master UART-Bus transmission line
UART_RXD 1 bit Slave UART-Bus receiving line
SPI_CLK 1 bit Master SPI-Bus clock signal
SPI_MISO 1 bit Slave SPI-Bus Master In Slave Out
SPI_MOSI 1 bit Master SPI-Bus Master Out Slave In
SPI_CS0 1 bit Master SPI-Bus Chip-Select 0
SPI_CS1 1 bit Master SPI-Bus Chip-Select 1
I2C_SCL 1 bit Master I2C-Bus clock line
I2C_SDA 1 bit Bi-Directionel I2C-Bus data line
+12V - Backplane +12V as defined by the VME Standart
-12V - Backplane -12V as defined by the VME Standart
USER_VDD - Backplane Free definable user voltage
+5V_F - Backplane Filtered +5V for all "Clean" consumers
+5V_N - Backplane +5V for all "Noisy" consumers
+3.3V - Backplane Filtered +3.3V voltage for all "clean" consumers
GND_N - Backplane Gnd for all "Noisy" Voltages. That means -12V / +12V / User_VDD / +5V_N
GND_F - Backplane Ground for all "Clean" Voltages e.g. +5V_F / +3.3V

Signal Mapping

The bus can be shared by boards with full bus width (HVME32) and halved bus width (HVME16). If the master is HVME32, slaves HVME32 and HVME16 can co-exist, with or without ECC individually. However, if the master is HVME16, all slaves cards must be implicitly HVME16.

3 Row - 96Pin functionality (HVME32)

10 IRQ bits are available and freely usable for the target application. However, some pins have shared functions. E.g. ECC and IRQ uses the same pin. Therefore its functionality need to be choosen during development, and can minimize the number of IRQ Pins available.

The table below represents the signal mapping on the DIN41612 3x32pin.

Some well-known serial protocols (UART, SPI, I2C) have been added to the mapping for allow simple communications with and between cards which are only equipped with µC because of their incapacity to interface the main parallel bus.

For the power supply, grounds and voltages have been placed to grant compatibility with VME backplanes. A +3.3V pin has been added and a distinction between clean (*_F) voltages for voltage sensitive operations like ADC, DAC and noisy (*_N) voltages for voltage insensitive usage has been added, this functionality can be bypassed if necessary.

2 Row - 64Pin functionality (HVME16)

For physical reasons (notably routing 2 layer “HES-SO” PCB with small FPGA/µC), there is the possibility to use the A and C row only – therefore, the data (Dxx) and the address (Axx) bus are both divided by two. The bus can host both 3 rows (A15..0/D31..0) and 2 rows (A7..0/D15..0) slave boards, respectively named 32bit and 16bit slaves. Addressing of each type of slave is done with the MODE bit, acting like an “Axx’high+1” address bit. Note that ECC is supported for both modes (16bit mode use less ECCxx bits – 5 instead of 7). The last ECC bit (ECC07 or ECC05) is de facto not used, but reserved for further better ECC coding.

Row A Row B Row C
01 D00 A08 D08
02 D01 A09 D09
03 D02 A10 D10
04 D03 A11 D11
05 D04 A12 D12
06 D05 A13 D13
07 D06 A14 D14
08 D07 A15 D15
09 GND_N D16 GND_N
10 MCLK1 D17 RST
11 GND_N D18 WR
12 MFREEZE1 D19 EN
13 SREADY1 D20 UART_RXD
14 MODE D21 UART_TXD
15 GND_N D22 SPI_CS1
16 WCLK0 D231 IRQ10 / ECC00
17 GND_N D241 IRQ9 / ECC01
18 SPI_CLK GND_F IRQ8 / ECC021
19 GND_N WCLK1 GND_F1
20 SPI_MISO GND_N I2C_SCL
21 SPI_MOSI ECC061 IRQ7 / ECC03
22 SPI_CS0 ECC07 I2C_SDA
23 A07 GND_N IRQ6 / ECC04
24 A06 D25 IRQ5 / ECC05
25 A05 D26 IRQ4
26 A04 D27 IRQ3
27 A03 D28 IRQ2
28 A02 D29 IRQ1
29 A01 D30 IRQ0
30 A00 D31 +3.3V_F
31 -12V USER_VDD +12V
32 +5V_N +5V_N +5V_F

1 These pins connect to a GCLK pin on the FPGA

Timing diagrams

HEI VME Timing Diagram

The upper graph presents a write operation, where the master set the address (with corresponding ECC code) and the EN / WR flags. Next cycle, the data are placed on bus. The slave can pull-down the SReady line until the ECC code verifies correct data integrity on the bus.

The lower graph shows a read operation in which the master set the address and the EN / WR flags. Next cycle, the slave takes control of the data line and places the corresponding data. In case of integrity failure, the master set high the MFreeze until data is considered as valid by verifying the ECC.

All operation can be pipelined, including interleaved read/writes.

The slave could hold down the SReady line until the read/write operation is done, but this case has not been considered yet.

  • NB #1 The used Hamming ECC code can only detect errors on 2 bits and correct only errors on 1 bit. In case of wider data corruption (> 2 bits), corrupted data can be interpreted as valid by the master as well as the slave controller.
  • NB #2 When ECC is active, a big asynchronous loop is present between Dxx/ECCxx and SReady/MFreeze lines (Master\circlearrowleftSlave for write operations and Slave\circlearrowrightMaster for read operation). This reduces considerably the max bus speed. Furthermore it has a great negative impact on the line quality and distance between master/slaves.
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