Author EVLA Feed & FE PDR 12/13 Feb, 2002 1 EVLA Receivers PDR (4m, P,) L, S, C BAND RECEIVERS Daniel (Mert) Mertely.

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Presentation transcript:

Author EVLA Feed & FE PDR 12/13 Feb, EVLA Receivers PDR (4m, P,) L, S, C BAND RECEIVERS Daniel (Mert) Mertely

Author EVLA Feed & FE PDR 12/13 Feb, Trx Projections Dhawan/ Hayward/Mert EVLA RX FREQ RANGES AND OP TEMPS: REQUIRED vs. PROJECTED BNDFRQ REQCURNTCURNTCALCIDR RANGE Tsys (2) Tsys (3) Trx (4) Trx (5) (GHz)(K)(K)(K)(K)(dB) ========================================================== L1 – 2 (1) TBD S2 – TBD C4 – TBD ========================================================== (1) MHz nominal, response fall-off from MHz. (2)From VLA Expansion Project, Phase I, The Ultra Sensitive Array, Table 3.1 (3)From VLBA pointing gains table “/home/jansky/POINTING/gains.table” (4)Average of “SOIDA” test data of a sample of receivers, 3 pts/band, equal weighting. (5)From R. Hayward noise budget analysis—See this presentation for details.

Author EVLA Feed & FE PDR 12/13 Feb, Estimated Receiver IF Output Power Rx BW (GHz) T(Sky) (  K) IF Power (dBm) L S C Hayward

Author EVLA Feed & FE PDR 12/13 Feb, Gain/Phase Stability Improvement Calibration Noise Sources: Constant Current Circuits Temperature Stabilization Post Amps: Temperature Stabilization IF/LO Cabling: Improved rigidity & support of heliax cables Hayward

Author EVLA Feed & FE PDR 12/13 Feb, Feedhorn Overview Szpindor/Mert Notes: (1)Optimized over GHz (2)Designed and used in current VLA configuration

Author EVLA Feed & FE PDR 12/13 Feb, Polarizer Overview Szpindor Notes: (1)Optimized over GHz (2)Designed and used in current VLA configuration (3)Turnstile Junction OMT (Boifot, Wallack) (4)Four Component Combination (Circ to Sq. Transition, 90 deg Phase Shifter, 45 Twist, OMT)

Author EVLA Feed & FE PDR 12/13 Feb, band Jackson/Mert MHz, 2 channel VLA 4-band Receiver (existing) Custom cross-dipole, NRL design, near prime focus—At 290 K. Commercial wide-band hybrid, quadrature phase shifter—At 290 K. Cal coupler—At 290 K Cal source, NoiseCom/MC63147– At 290 K. LNA, NRL design—At 290 K, Te=TBD K, G=TBD dB 2 outputs at MHz, -TBD dBm Cryogenics: None. Receiver FE NF est=TBD K

Author EVLA Feed & FE PDR 12/13 Feb, P-band Jackson/Mert MHz, 2 channel VLA P-band Receiver (existing) Custom cross-dipole, NRAO design, near prime focus—At 290 K. Commercial wide-band hybrid, quadrature phase shifter—At 290 K. Cal coupler—At 290 K Cal source, NoiseCom/MC63147– At 290 K. LNA, NRAO design—At 290 K, Te=28 K, G=33 dB 2 outputs at MHz, -35 dBm Cryogenics: None. Receiver FE NF est=55 K

Author EVLA Feed & FE PDR 12/13 Feb, LSC Top Level NRAO profiled, corrugated feeds. NRAO e-formed, quad-ridged, OMT. Each polarization output spilt into 2 independently tunable channels. 1, NRAO, 4-channel up-converter module. Jackson/Mert

Author EVLA Feed & FE PDR 12/13 Feb, L-band 1 – 2 GHz, 2 x 1 GHz channel EVLA L-band Receiver Development 300 K, NRAO,3.474 K Vacuum 300 K, NRAO,0.069 K Quadridge OMT, 300 K, NRAO,1.165 K Wide-band hybrid, 90 deg phase 15 K, TRM,0.848 K Cal 15 K, Narda, K Cal 290 K, NoiseCom, S-Cal 290 K, NoiseCom, 15 K, (Opt),(.500 K) 15 K, Te=2 K, G=25 * 2 dB, NRAO (planned)2.300 K 300 K, K&L, Post-amp, various 300 K, NF 20 dB0.007 K 2 outputs at 2–4 GHz, -44 dBm Cryogenics: CTI-350 refrigerator. Receiver FE NF est=8.78/11.27 K Hqyward/Jackson/Mert

Author EVLA Feed & FE PDR 12/13 Feb, ComponentTemp (K)L/G (dB)  T Rx (K) Feed Vacuum Window OMT Hybrid Cal Coupler LNA – 1 st G-BlockTn = Cooled Filter LNA – 2 nd G-BlockTn = Coax150 & 3002 & Post AmpNF=2 dB Splitter Mixer Total T Rx 8.78 L-Band Noise Budget Cooled Isolator (0.5 dB) add 2.49  K Hayward

Author EVLA Feed & FE PDR 12/13 Feb, L-band Reuse? Retain: –Noise diode, CTI 350 frig, Cal coupler & splitter? (New for solar?), Vacuum sensor, Dewar? (with extensions), Misc con & attn. Scrap: –LNAs, Post-amps, OMT, FH, Filters, M&C. Mert

Author EVLA Feed & FE PDR 12/13 Feb, – 4 GHz, 2 x 2 GHz channel EVLA S-band Receiver Development 300 K, NRAO,3.474 K Vacuum 300 K, NRAO,0.069 K Quadridge OMT, 300 K, NRAO,1.165 K Wide-band hybrid, 90 deg phase 15 K, TRM,0.848 K Cal 15 K, Narda, K Cal 290 K, NoiseCom, S-Cal 290 K, NoiseCom, 15 K, (Opt),(.500 K) 15 K, Te=4 K, G=40 NRAO (planned)4.541 K 300 K, K&L, 300 K, NF 25 dB, various OEMs,0.035 K 2 outputs at 2–4 GHz, -44 dBm Cryogenics: CTI-350 refrigerator. Receiver FE NF est=11.01/13.76 K S-band Hqyward/Jackson/Mert

Author EVLA Feed & FE PDR 12/13 Feb, ComponentTemp (K)L/G (dB)  T Rx (K) Feed Vacuum Window OMT Hybrid Cal Coupler LNATn = Cold SS Coax Warm Coax Post AmpNF=2 dB Splitter Mixer IF Cable Total T Rx S-Band Noise Budget Cooled Isolator (0.5 dB) add 2.75  K Hayward

Author EVLA Feed & FE PDR 12/13 Feb, C-band 4 – 8 GHz, 2 x 4 GHz channel EVLA C-band Receiver Development 300 K, NRAO,3.474 K Vacuum 300 K, NRAO,0.069 K Quadridge OMT, 300 K, NRAO,1.165 K Wide-band hybrid, 90 deg phase 15 K, TRM,0.848 K Cal 15 K, Narda, K Cal 290 K, NoiseCom, S-Cal 290 K, NoiseCom, 15 K, (Opt),(.500 K) 15 K, Te=2 K, G=25 * 2 dB, NRAO K 300 K, K&L, Post-amp, various 300 K, NF 20 dB0.035 K 2 outputs at 2–4 GHz, -44 dBm Cryogenics: CTI-350 refrigerator. Receiver FE NF est=11.01/14.32 K Hqyward/Jackson/Mert

Author EVLA Feed & FE PDR 12/13 Feb, ComponentTemp (K)L/G (dB)  T Rx (K) Feed Vacuum Window OMT Hybrid Cal Coupler LNATn = Cold SS Coax Warm Coax Post AmpNF=2 dB Splitter Mixer IF Cable Total T Rx C-Band Noise Budget Cooled Isolator (0.5 dB) add 3.31  K Hayward

Author EVLA Feed & FE PDR 12/13 Feb, C-band Reuse? Retain: –Noise diode?, Misc con & attn. Scrap: –LNAs, Post-amps, OMT, FH, Filters, M&C, CTI 1020 frig, Entire dewar box. Mert