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Joe Britton edited this page Oct 17, 2017 · 60 revisions

Eurocard Extension Modules

Eurocard Extension Module (EEM) is a Sinara standard for low-cost, low-bandwidth peripherals that are controlled by ARTIQ DRTIO.

EEM peripherals are supplied with power and a digital interface (ARTIQ DRTIO) from an EEM Carrier, such as Kasli, via ribbon cables using the EEM Connector interface.

Small system example

EEM-DIO-crate EEM-DIO-crate

EEM Mechanical

EEM peripheral PCBs are

  • 100 mm tall
  • up to 160 mm long

EEM Carriers

EEM Carriers provide EEM Connectors to supply EEM peripherals with power and digital IO. Presently, Sinara includes two EEM Carriers:

  • Kasli Carrier can serve as a stand-alone ARTIQ Master that generates DRTIO signals
  • VHDCI Carrier interfaces with Sayma or Metlino boards that generate DRTIO signals

EEM Connectors

EEM connectors provide a standardised means of connecting EEM peripherals to a carrier, such as Kasli, which provides power and real-time digital IO (DRTIO).

Connectors are 2x15 100mil pitch male pin-header (pinout below). Wiring between boards is typically done using ribbon cable (50mil wire pitch).

Connector pinout:

Function Comment Pin(s) pin designation if used for SPI RJ45 SPI
GND 1, 4, 7, 10, 13, 16, 19, 22, 25
+12V 2A max (5A max for all EEM+Kasli/VHDCI together) 28, 29
+3V3 20mA max, managmenet power for EEPROMs etc 30
I2C 3V3 LVCMOS 26 (SDA), 27 (SCL)
LDVS_1 LVDS, bi-directional 2 (P), 3 (N) SCLK0, clock-capable SCLK0, clock-capable
LDVS_2 LVDS, bi-directional 5 (P), 6 (N) MOSI MOSI0
LDVS_3 LVDS, bi-directional 8 (P), 9 (N) MISO MISO0
LDVS_4 LVDS, bi-directional 11 (P), 12 (N) CS0 CS0
LDVS_5 LVDS, bi-directional 14 (P), 15 (N) CS1 SCLK1
LDVS_6 LVDS, bi-directional 17 (P), 18 (N) MOSI1
LDVS_7 LVDS, bi-directional 20 (P), 21 (N) MISO1
LDVS_8 LVDS, bi-directional 23 (P), 24 (N) CS1
odd even
1 GND 0P 2
3 0N GND 4
5 1P 1N 6
7 GND 2P 8
9 2N GND 10
11 3P 3N 12
13 GND 4P 14
15 4N GND 16
17 5P 5N 18
19 GND 6P 20
21 6N GND 22
23 7P 7N 24
25 GND SDA 26
27 SCL 12V 28
29 12V MP 30

LVDS is compatible with 1.8V, 2.5 and 3.3V bank supply. Metlino utilises 1.8V FPGA bank supply, while Kasli utilises 2.5V supply.

Each EEM peripheral has an EEPROM on its I2C bus for identification.

EEM Connector Protocol

Multiple digital IO protocols are supported for the LVDS lines on each EEM Connector. Protocol choice is baked-in when the ARTIQ Master FPGA's bitstream is compiled.

  • TTLs, input, output, bidirectional
  • SPI
    • SPI Phys have the pin assignment: SCLK, MOSI, MISO, CS in that order.
  • NU-Servo fast ADC/DDS/PID
  • CameraLink

See ARTIQ #823 for the bitstream and device_db building infrastructure requirements.

The old idea of having a restricted set of pprotocols that could be chosen at runtime (see issue #164 for discussion) has been abandoned.

EEM Chassis/Enclosures

EEM PCBs are designed to mount either in a stand-alone enclosure, or in a 19'' rack. If in a rack,

  • pitch is 12 HP ("wide") or 4 HP ("narrow").

Suitable enclosures:

Suitable racks:

Backplane

Following is a summary of a proposed backplane. Note that presently there is no officially supported EEM backplane (only the EEM Connectors).

The 96 position DIN 41612 connector from Kasli should be used to supply backplane-compatible EEMs or a breakout board for more EEM connectors. Supporting the backplane from an EEM is optional. Depending on electrical simplicity an EEM could opt to support an EEM Connector interface and backplane signaling as a runtime alternative, or as a fixed design choice.

The equivalent of four EEMs is supplied from Kasli through the backplane. Whether these four backplane EEMs are in addition to the eight EEM Connectors s or mutually exclusive with them remains TBD. The backplane is passive.

  • 1 pin: 3.3 V management power
  • 2 pins: 12 V
  • 3 pins: GND
  • 4x2 (1 pair per EEM): provide a reference clock signal to EEMs
  • 4x2 (2 per EEM): I2C
  • 4x2x8 (8 LVDS pairs per EEM)
  • 10 pins remaining for more power/GND

The signals are star-routed to several EEM DIN 41612 connectors in a barrel-shifted way so that a single EEM can claim up to four EEM links. The EEM connector pinout should be the same as Kasli. The four CLK/I2C/LVDS groups should be assigned in two different ways.

If the unused LVDS and clock stubs are not a problem, the backplane layout could be a very flexible routing (where 4-link EEMs can be plugged into any slot) or a more fixed routing (but with no stub problems).

Fixed backplane links

  • 0: 0, 1, 2, 3 (Kasli)
  • 1: 0, 1, 2, 3 (up to quad-link EEM)
  • 2: 1, 2, 3 (up to triple-link EEM)
  • 3: 2, 3 (up to double-link EEM)
  • 4: 3 (single-link EEM)

The EEM pitch should such that a 19 inch subrack can be filled. Then if e.g. a single-link EEM is pliugged into slot 1, it will claim only link 1 and all slots to the right (2-4) can be used. A double-link EEM plugged into slot 3 would claim links 2 and 3 and slot 4 can not be used. An N-link EEM requires that the N-1 slots to the right of it are empty.

Flexible backplane link routing

  • 0: 0, 1, 2, 3
  • 1: 1, 2, 3, 0
  • 2: 2, 3, 0, 1
  • 3: 3, 0, 1, 2
  • 4: 0, 1, 2, 3
  • 5: 1, 2, 3, 0
  • 6: 2, 3, 0, 1
  • etc.

The pitch between connectors on the backplane can e.g. be 4 HP. If e.g. Kasli is plugged into slot 0, it drives all four groups from there. Then if e.g. a single-link EEM is pliugged into slot 1, it will claim only link 1. A double-link EEM plugged into slot 6 would claim links 2 and 3. An N-link EEM requires that the N-1 slots to the right of it are empty.

EEM Connector-to-DIN mezzanine

To clean up the wiring in the rack, one could design a simple mezzanine for Kasli (or the VHDCI carrier) that plugs into its EEM Connectors (four or 8) and then routes them through another (or two) DIN connectors to the backplane. The backplane would then do all the wiring for EEMs significantly reducing the ribbon rats nest.

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