Regarding point 5, below, there is an existing Quad ADC card for the ROACH, a pair of which would allow a ROACH to capture eight 125 MHz inputs. Unfortunately, the analog bandwidth is not great, so digitizing at RF is not practical with these ADCs. I haven't looked at ADC options in a while, but perhaps there is a more suitable quad ADC that could digitize ~250 MHz at RF.<br>
<br>Glenn<br><br><div class="gmail_quote"><blockquote class="gmail_quote" style="border-left: 1px solid rgb(204, 204, 204); margin: 0pt 0pt 0pt 0.8ex; padding-left: 1ex;">5. The long-range plans are to locate the beamformer electronics in<br>
the Jansky laboratory. This offers the greatest room for growth and<br>
minimizes the problems of space, weight, and EMI in the GBT receiver<br>
room. However, the first beamformer with modest bandwidth will be<br>
located in the GBT receiver room so that its implementation is not<br>
dependent on transmitting its input signals to the Jansky lab. [Can<br>
fewer ROACH boards accommodate 38 lower speed ADCs?]<br>
<br>
6. A 250-MHz bandwidth beamformer that uses 20 ROACH boards and 20 iADC<br>
boards plus ethernet switch and associated electronics and power<br>
supplies is too big and noisy for the GBT receiver room. This should<br>
be planned for installation in the Jansky lab.<br>
<br>
7. We'll vigorously develop digitizers and digital fiber links that<br>
allow signals from the array elements to be transmitted to the Jansky<br>
lab on digital fiber links, but we don't want this to be on the critical<br>
path to implementing a wider bandwidth beamformer. An alternative<br>
solution will be to install commercial 0.9-2.2 GHz analog fiber modems<br>
to transmit RF signals directly to the lab. The feasibility of such a<br>
solution depends on it being stable enough to be tracked with the<br>
phase and amplitude monitoring system. Two modem pairs are in hand,<br>
and tests of them on fibers between the GBT and the lab will begin<br>
soon. Each modem pair costs about $2K, and a set to handle 38 signal<br>
paths will cost about $80K so we need to be certain that it will offer<br>
significant scientific pay-off before taking this option. Note that<br>
the modems in hand do not work below 900 MHz so they would not transmit<br>
low-frequency IF signals from the BYU receiver modules currently under<br>
construction. Analog modems that work at lower frequencies are<br>
available, but they may be more expensive.<br>
<br>
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</blockquote></div><br>