UniBoard achievements in Q3
In spite of the vacation period in July and August, the UniBoard
project progressed well during Q3. Two schematic review meetings were
held, one internal at JIVE/ASTRON, with a number of local experts,
followed by a review via videocon with all the partners. The layouting
of the board is in full swing and firmware is being developed for
testing purposes and to function as building blocks of the various
applications. Design of a correlator control system has started and a
project-wide SVN firmware repository has been created to enable the
sharing of design among the partners. An MoU was agreed upon in which an extra payment, as subsidy towards the development of the UniBoard, will be made by all partners, prior to the actual production of the board. Finally, a board manufacturer has
been selected. In all, the project is right on track, and we expect the
first prototype at the end of 2009.
Documents:
Erlang Part II: OTP mnsesia and the outside world, Des Small and Harro Verkouter, 01-07-2009
PPT for Schematic Review Gijs Schoonderbeek, Sjouke Zwier, 07-07-2009
UniBoard Schematic Gijs Schoonderbeek, Sjouke Zwier, 18-08-2009
Evaluation of different options for the spectral domain data re-sampling for the VLBI application of the Uniboard, Sergei Pogrebenko, 19-08-2009
Erlang demo: developing a realtime monitoring utility, Des Small and Harro Verkouter, 27-08-2009
UniBoard PCB (preplacement) Sjouke Zwier / Gijs Schoonderbeek. 15-09-2009
General activities in Q3:
Internal JIVE/ASTRON schematic review, 02-07-2009
General schematic review per video conference, 10-07-2009
2-weekly general telecons
Activities by institute in Q3:
ASTRON:
2-weekly internal technical meetings
schematic design finished
board layout and routing started and ongoing production company selected
with JIVE: firmware written to check all pinning
in addition to listed documents, several documents produced on APERTIF beamformer and correlator system
BORD:
continuing work on mathematical model to evaluate effects of filter weights and output signals from each module (polyphase filter and FFT)
modification, simulation and validation of initial VHDL code produced by Arcetri for the polyphase filter block in the input FPGA
T/H chips (65 nano technology) required for fast ADCs have been received from the foundry, test PCB has been designed
INAF
refined conceptual design of the digital receiver filterbank, including input from modelling and board design
draft computer interface model
start of VHDL coding
draft VHDL code for second stage digital filter
resource estimate using simplified conceptual VHDL coding
obtaining experience in the use of SOPC tools
JIVE:
with ASTRON: completed set of designs to check schematic pinning designs to drive interfaces between FPGA and board: DDR3 memory, backplane, ADC, external and internal GX transceivers, 1 GbE control port I2C port
with ASTRON: outline design for network control using the 1 GbE port and Nios embedded processor
correlator control high level design started
investigation into data formats
UMAN:
engineer has been identified to work on pulsar aspects of development. This will focus on the development of the algorithm for coherent dedispersion and creating a model to convert this for use with the UniBoard
discussions with UORL group has started regarding the interfaces between coherent dedispersion and interference rejection software
video conference with UORL, July 10
UORL:
KASI:
Problems / Issues
Issues - organisational, administrative or other problems foreseen
1) at this point, the full 40 Gbps interfaces of the front FPGAs can
only be used with “soft cores” using up to 20% of all available
logic. Hard cores are limited to 3 times 10 Gbps. From discussions with
Altera representatives we understand that this problem will most likely
be solved in the near future.
2) The “route space” between in and output FPGAs is limited, which may
cause the speed between them to turn out lower than planned. This will
have to be checked carefully once the first prototype has been
produced.
3) the lead time of electronic components is longer than previously due
to the economic situation. This is hopefully offset by the timely
selection of a manufacturer.
Red flags - major problems
Forward Look (Q4-Q7)
ASTRON:
completion of PCB layout (Q4)
production of first board (Q4-Q5)
7-board production run (Q6)
BORD:
adaptation of various truncations used in system design based on model results (Q4-Q5)
continuing simulation/validation of code produced at INAF
adaption and addition to existing VHDL based on better definitions of interfaces and monitor points
definition of ADC interface (Q4-Q5)
INAF:
JIVE:
detailed design of control interface (with ASTRON) (Q4)
FPGA designs to test first board and control interface verification correlator mapped out (with ASTRON) (Q4)
board testing (with ASTRON) (Q5)
writing of main components of correlator design, including packet receiver/sorter, delay module, filter bank/FFT, correlation engine and processed data output (Q5-Q6)
reformatting exising dataformats to single-channel, single-data-thread VDIF format (Q4)
design main database scheme for the correlator control system: all components read setting/write status|statistics in this. Will be initialized from VEX files (Q5)
correlate existing data (from file) with the JIVE software correlator, controlled from/by the correlator control software (Q6-Q7)
UMAN:
Algorithm modeling
Algorithm Implementation & Test
Hardware Test
UORL:
face-to-face meeting with UORL group in Manchester (Q4)
continuing matlab simulations on real data from Nancay telescope
definition of RFI mitigation algorithm architecture with UMAN (Q5)
matlab model of this architecture (Q6)
test of gold model on synthetic and real data (Q6)
VHDL coding (Q7)
KASI:
Expected milestones/ deliverables