SKAMP Square Kilometre Array Molonglo Prototype Duncan Campbell-Wilson, School of Physics Molonglo Radio Observatory, Bungendore, NSW, Australia
Cylindrical Antenna 18,0000 m2
SKAMP Development Strategy SKAMP1: Gain experience with FPGA technology, but use existing MOST analogue infrastructure. SPARTAN 2-3 Xilinix FPGAs used for signal processing and complex correlation. SKAMP 2: Take the lessons learnt from SKAMP 1 to develop a multi-channel correlator system with spectral line and continuum capability. Based on Virtex 4 technology. SKAMP 3: New feed design with full polarisation and integrated low cost LNAs. Some exploratory work already complete.
SKAMP 3 Development Goals Design a new cost-effective broadband feed system to replace the current mechanically driven beam-steering system. Frequency agile and compatible with the detector system built for SKAMP 2. Change the front end receivers to accept bandwidth of 94 MHz within the range 700-1400 MHz
SNR1987A
SKAMP 2 Design Goals Compatibility with MOST and SKAMP 1. Major change to digital signal transport on optical fibres and digital signal processing using FPGAs. 368 individual antenna systems: 352 for astronomy and 16 for RFI mitigation and testing
Variable Cosmic Radio Sources
SKAMP 2-3 Signal Pathway Antenna to Low Noise Amplifier (LNA) LNA to receiver Receiver fixed 30 MHz BW at 843 MHz; down-converted to baseband (SKAMP 2) Receiver frequency agile with 100 MHz BW; down-converted to baseband in IQ format (SKAMP 3) Digitised to 8 bits Serialised in the Lattice FPGA Sent on 850 nm optical fibre to the control room for digital signal processing
Polyphase Signal Pathway Optical to electrical conversion Delay First level (coarse) FFT performed in the first stage (PFB A) Second level (fine) FFT produces ~14 kHz frequency channels (PFB B) Signals aligned to stop the fringes and adjust signal amplitude Data re-ordered and serialised for transfer to the correlator Some sections working but full integration is incomplete
PFB Output Spectrum (RFI antenna)
Correlator 24 boards, each handling approx 4 MHz of bandwidth 48 independent outputs, feeding into a switch Two computers handle the data reduction, under control of a third computer Readout every 32 seconds for normal observations
SKAMP II correlator board
Loaded PFB and Correlator Racks
Status: Polyphase Filter and Correlator All prototype boards completed and tested 26/27 production correlator boards delivered January 2011 27 Correlator Rear Transition Modules (CRTM) and Optical Rear Transition Modules (ORTM) delivered. Front panel fit-off complete 27 production PFB boards complete January 2011.
Correlator Status Close to full operation Long term accumulator is outstanding but underway System verification is incomplete Input and output interfaces passing correct test data About 2 months left to complete the firmware
Receiver specifications Design capable of accepting 700-1400 MHz, with output bandwidth 100 MHz Analogue input, with digital output in IQ format; fibre optic transmission Environmental monitoring; local gain and offset control
Down-converter Attributes Wideband input 700-2800 MHz Gain compensation vs temperature I/Q outputs Four receivers per down-converter board One local oscillator (low phase-noise margin)
RX Digitiser Board
RX Diagnostics Diagnostic features included as part of the design Diagnostics along the signal path to allow remote fault-finding Diagnostic functions kept independent of each other
RX System Diagnostics Two Tone test Checker Board test Half Scale Pseudo random binary sequence Power supply voltage monitoring Down-converter temperature monitoring Digitiser temperature monitoring
RX Remote Control Programmable down-converter; pseudo-logarithmic gain control Linearly programmable ADC offset control Linearly programmable ADC voltage reference System under test for reliability and debugging
RX Development Status Slow firmware development; correlator firmware has priority Down-converter boards production-ready; assembly underway Digital RX FPGA boards not yet production-ready FPGA placement reliability; need for rework
RX Diagnostic Spectrum
PFB and Correlator Firmware PFB firmware – still to do: time delay, fringe stopping, amplitude adjustment Limited testing Correlator firmware in good shape; long term accumulator incomplete
Software Status Data processing pipeline has been tested Diagnostic software under development SKAMP2 system control still to be extended from single board to full system Telescope control computer interface complete Calibration: no significant work
Astronomical Calibration Selection parameters for calibrators: flux density, spectral index, angular size, variability and declination Molonglo Southern 4 Jy survey (MS4; Burgess & Hunstead 2006, Table 5) is an excellent starting point for SKAMP2 calibration.
Displaying Visibilities
System Calibration Temperature dependent gain calibration Delay calibration Frequency dependent gain and phase Fine channel calibration