Loren Data's SAM Daily™

SAMDAILY.US - ISSUE OF JULY 29, 2020 SAM #6817
AWARD

66 -- Quantum Networking and Computing Electronics Control System and Software

Notice Date

7/27/2020 4:17:50 AM
 

Notice Type

Award Notice
 

NAICS

334516 — Analytical Laboratory Instrument Manufacturing
 

Contracting Office

FA8751 AFRL RIKO ROME NY 13441-4514 USA
 

ZIP Code

13441-4514
 

Solicitation Number

FA875120Q0048
 

Archive Date

08/11/2020
 

Point of Contact

Richard Childres
 

E-Mail Address

Richard.Childres@us.af.mil
(Richard.Childres@us.af.mil)
 

Award Number

FA875120P0034
 

Award Date

07/27/2020
 

Awardee

M-LABS LIMITED Sheung Wan HKG
 

Award Amount

35390.00
 

Description

The Government required�a trapped ion quantum networking and computing electronics control system and software with: Kasli FPGA carrier (QTY = 2) 3 SFP connectors for Ethernet (if Kasli is the master) and DRTIO (one upstream, two downstream). Each with a LED. SFP1: Ethernet in stand-alone (if Kasli is master), DRTIO upstream otherwise SFP2: DRTIO downstream SFP3: DRTIO downstream or special purpose. 1 micro USB for JTAG, serial console, I2C 1 SMA to the clock recovery and clock distribution chip used as RTIO reference clock input in master/stand-alone mode (10 dBm sine/square) FBarrel connector for +12V power, used for Kasli and passed through to the EEM IDCs. Compatible with locking barrel connectors for increased ruggedness.Eight EEM (0-7) available as 30 pin IDC connectors on Kasli Four EEM (8-11) available on the 96 pin DIN 41612 connector DIN 41612 96 position connector to backplane. Hosts 8 EEMs using standard EEM headers Up to 4 EEMs via backplane 1 SATA (wired as master/host) connected to a transciever SATA1 (""host"" pinout, not ""disk""/""reversed""): DRTIO downstream or special purpose 4 MMCX outputs with the RTIO reference frequency Port 4 of the FT4232H available on an optional pin header FPGA JTAG 3 USER_LEDs XC7A100T-2FGG484I FPGA, DDR3 RAM, SPI flash a clock recovery and distribution network USB connectivity with four virtual ports four high speed 6 GB/s transcievers for Ethernet and DRTIO, and up to 12 EEM ports for Eurocard Extension modules 8 channel SMA TTL card (QTY = 10) Extension module (EEM) supplying 8 digital IOs via front-panel BNCs. Occupies one EEM port Two banks of four channels each Each bank with individual ground isolation Per-bank switchable direction via on-board switches or I2C Per-channel switchable 50 Ohm termination with LED indicators Output channels can supply >2V into 50 Ohm loads Output channel impedance: 50 Ohm Short circuit tolerance: infinite Minimum pulse width: 3ns Max 150 MHz toggle rate with 50% duty cycle IO direction switched in groups of 4 channels Panel width: 8HP Urukul 4-channel DDS card AD9910 (QTY = 4) DDS Two variants of Urukul are available with different DDS chips: AD9912 and AD9910 Output frequency (-3 dB): 400 MHz Frequency resolution: AD9912: ~8 �Hz (47 bit) -- see AD note AD9910: ~0.25 Hz (32 bit); see also #210 for an extension of the frequency resolution using the DRG) Frequency update rate using the single-width SPI bus: > 500 kHz burst aggregate, TBC Phase offset resolution: 14 bit (AD9912), 16 bit (AD9910) Digital amplitude (ASF) resolution: 14 bit (AD9910 only) DAC full scale current resolution: 10 bit (AD9912), 8 bit (AD9910) DAC full scale current slew rate: ~6 mA/20 �s, 100 ns/LSB (AD9912) #205 Temporal resolution, FTW/POW/ASF updates: 4 ns (IO_UPDATE on a SERDES TTLOut) (TBC) OSK: not supported DRG control pins: not supported Profile (using the AD9910 PROFILE pins): ganged and exposed in the shift register RF signal chain Anti-Aliasing: The lowpass can be replaced by a custom discrete filter. This allows usage of the second or third Nyquist zones. Digital step attenuator resolution: 0.5 dB Digital step attenuator range: 0 to -31.5 dB Digital step attenuator glitch duration: 100 ns Nominal max output power (1dB compression from expected attenuator/ASF/FSC setting due to pre-amplifier): 10 dBm Temporal resolution RF switch: 1 ns (limited by FPGA OSERDES/ARTIQ TTLOut resolution) RF switch speed: 100 ns rise to 90 % RF switch isolation: 70 dB Jitter RF switch: 50cm/s (from thermal simulation, #321), TBD Power consumption: 7 W (AD9910)/6.5 W (AD9912) with 1 GHz PLL, 4x400 MHz, 10.5 dBm, 52 C DDS temperature sitting on bench Front panel Each channel: SMA RF output Green LED indicating RF output enabled Red LED indicating DDS sychronization/PLL error or software-controlled function One SMA for the reference frequency input, up to 1 GHz Red LED: over temperature Green LED: power good Sample 8-channel ADC card (QTY = 2) Width: 8HP Channel count: 8 Resolution: 16-bit Sample rate: up to 1.5 MHz Sustained aggregate data rate in single-EEM mode (8 channel readout): ~700 kHz Sustained per-channel data rate in dual-EEM mode (SU-Servo): ~1 MHz Bandwidth: 200kHz -6dB bandwidth for G={1, 10, 100}, 90kHz for G=1000 Input ranges: +-10V (G=1), +-1V (G=10), +-100mV (G=100), +-10mV (G=1000) DC input impedance: Termination off: 100k from input signal and ground connections to PCB ground Termination on: signal 50Ohm terminated to PCB ground, input ground shorted to PCB ground ADC: LTC2320-16 PGIA: AD8253 EEM connectors: power and digital communication supplied by one or two EEM connectors. Grabber camera interface card (QTY = 2) Supports andor iXon Ultra/Life EMCCD 888/897 and Andor X3 cameras PM 10 clock, four data, four control and two serial communications lines. The clock and data lines carry the frame data. They also carry FVAL/DVAL/LVAL (frame, data, line valid flags to describe the shape of the frame and validity of the data). Base transfers 28 bits (4 control and 24 data) per clock cycle. Maximum clock frequency is 85 MHz, line rate on the data lines is 85 MHz * 7 = 595 MHz. Clock speeds and frame format will target the 40 MHz, M=16 bit grey, Base CameraLink (Andor) use case. Needs 1:7 PLL on the clock input for the 1:7 SERDES. The full frame data would be ~16 Mbit. We don't want to store that on FPGA nor do we want to build the DRAM writer for it. Full frame data is also readily available on the ""standard"" link (USB or Ethernet) through the computer and e.g. Andor SDK, and a good shim layer in Python. For alignment, ion finding and definition of the ROIs use the computer. The gateware will automatically discover the frame dimensions from FVAL/LVAL/DVAL and run/clear row/column coordinate counters accordingly. Frame dimensions will be limited to K=12 bits (4096 rows and columns). To process the data, it is streamed through and N>=16 ""ROI engines"". N=32 if possible. Each ROI engine gates on one rectangular pixel region and accumulates pixel values for each frame. The ROI engines operate independently and can be overlapping. The accumulators need to be 2*K + M = 36 bit wide. After the frame, the accumulated value is pushed as an RTIO input event if the ROI region is enabled. One RTIO input channel for all ROI engines. The ROI engines sensitivity areas are configured through a single RTIO port (or even through slower non-RTIO/out-of-band means). N addresses, each 4x12 bits ROI data. The RTIO input submission is gated (per ROI engine) by a N-bit gate RTIO port, analogous to the TTL input gate. This allows suppression of spurious input events e.g. during alignment or cleaning frames. The kernel CPU can use the values to perform dark frame subtraction, calibration, thresholding, bayesian analysis, calculate moments, and otherwise handle the data. �Zotino 32 channel DAC card (QTY = 2) 32-channel, 16-bit DAC EEM with an update rate of 1MSPS (divided between the channels). Width: 4HP Channel count: 32 Resolution: 16-bit Update rate: 1MSPS, which may be divided arbitrarily between the channels Analogue bandwidth: 3rd-order Butterworth response with 75kHz cut-off; ?V/s slew-rate Output voltage: �10V Output impedance: 470Ohm in parallel with 2.2nF DAC: AD5372BCPZ EEM connectors: power and digital communication supplied by a single EEM connector. Power consumption: 3W without load, 8.7W with max load on all channels. Temperature stability: OpAmp self-heating is about 25C. 0.2ppm/C or� 4ppm. BNC-IDC (QTY = 8) Adapter for routing analog potentials from Zotino IDC headers to BNC. Eurocard chassis Chassis and mounting hardware (QTY = 2) Eurocard rack with 12+1 Eurocard slots Assembly, bitstream generation based on existing ARTIQ features, and testing (QTY = 2) Testing done to ensure workable software and hardware upon delivery for controlling trapped ion quantum information system
 

Web Link

SAM.gov Permalink
(https://beta.sam.gov/opp/8a142fba77d7489e81fb8ee03ef620fe/view)
 

Record

SN05734124-F 20200729/200727230131 (samdaily.us)
 

Source

SAM.gov Link to This Notice
(may not be valid after Archive Date)

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