&$ 800Mhz_receiver

800 MHz receiver

sep08

The 800 MHz is a dual polarization (linear pols) cooled receiver (tsys about 120K) covering 700 to 800 Mhz. There is a low loss cavity filter in front of the dewar to cut out adjacent tv stations(below 700 Mhz) as well as the cell band (above 800 Mhz).

History
Recent system performance measurements
Calibration measurements
All in time order

History

14mar11: updated pointing model to correct for az,za offsets in 800 mhz rcvr.
11mar11: 2 screws mounting feed to under the floor were loose. This caused the pointing error vs za variation.

fixed 11mar11 afternoon.

24sep10: 800 Mhz re installed after ao40 lowered from dome.. byu antenna version 1.0 installed.
antenna versions (from ganesh)

version 1: twin 50 ohm dipoles with a passive combiner adding to the insertion loss
version 2: dipoles of 100 ohm impedance, simply connected with a T junction eliminating combiner loss. Supposedly V2 also did a better job with the coupling between the dipoles.

14apr10:byu feed with both pols installed. (ant version 1) cold 23apr10.
22dec09: penn state feed replaced with byu single pol feed for testing.
06oct09: dana wiggled cables input to dewar, caused Tsys polB to now be lower than Tsys PolA (see tsys plots)
12aug09: tv chan 67 789.25 turns off.
29jun09: installed cooled receiver.
15jun09: replaced cables to dewar with good cables, installed filter after dewar, retuned dipoles. Switched to 1-2 ghz as default IF
12jun09: installed new feed, filters before dewar. dewar is room temp still.
30mar09: update az offsets in model for turret position at 188.5. After updating model az offset i did a single cross (2strips) and used the az,za offsets to update the constant terms in the model.
18dec08: first spectra scan with interim correlator and 25 MHz filter.
05sep08: az strips at different turret positions to find correct turret center.
15aug08: installed helix antenna.

Calibrations

26sep10: calib run byu antenna after reinstallation.
11jan10: BYU antenna. compare the Penn state.
29jun-02jul09: calibration runs old cal coupler (.ps) (.pdf) processing: x101/090630/calib.pro

Miscellaneous:

14mar11: updated pointing model to correct for az,za offsets
11mar11: added results of stokes calibration (jan,mar11).
08mar11: Dual pol bandpass shape, rms/mean, and sefd vs freq.
08mar11: alfa motor controller, dome cameras rfi at 750 Mhz.
29nov10: azimuth dependence of 800 rcvr rfi.
29nov10: az swing looking at 734.7-739.3 Mhz rfi
24nov10: 734.7-739.3 Mhz rfi in band
30sep10: a2524 dps shows larger ripple in polA.
26sep10: calib run byu antenna after reinstallation.
11jan10: BYU antenna. compare the Penn state.
12oct09: 800 Mhz receiver band pass:
17sep09: PolB/PolA ratios for Tsys,Gain,SEFD jul09->14sep09.
25aug09: azswing looking for chn 67 peak after chn turnoff.
14aug09: new 800 Mhz receiver cals measured 13aug09
12aug09: tv channel 67 turns off
10aug09: beam squint in 800 Mhz rcvr
10aug09: double position switching shows rms polB > rms PolA.
29jun-02jul09: calibration runs old cal coupler (.ps) (.pdf) processing: x101/090630/calib.pro
18jun09: freq hop 750/753.7 . Source of rfi in 700-800 Mhz.
14jun09: az swing looking at 700-800 Mhz.
17jun09: ripple appears in 800 Mhz rcvr polB
16jun09: calibration run 800 MHz rcvr with room temperature dewar.
13jun09: first look at 800MHz feed with tv stations off.
13apr09: 2 azswings near 820 MHz.
11apr09: chan 63/67: lower tv power stations seen in the 700-800 MHz band
08apr08: 2 azswings looking for chan62/50 peak values.
02apr09: planned usage of the 700 MHz band by emergency services
18dec08: spectral scan 620-890 MHz.
30oct08: look at hilltop monitoring data for oct08
05sep08: az strips at different turret positions to find correct turret center.

08mar11: dual pol bandpass. rms, and sefd vs freq

60 second on off position switching was done using the 800 Mhz rcvr on 08mar11.
The setup was:

source B0540+187 (3.32 Jy @ 750 Mhz)
60 sec on,off position switching with 10sec cal on ,off.
za=14.
mock spectrometer 172 Mhz with 8192 channels, 1 second integrations.

the data used was limited to the 100 Mhz bandpass of the 800 Mhz rcvr.

Pointing runs show a za offset of up to 25 asecs. This should not affect the gain much (beamwidth=390 asecs at 750Mhz).

The plots show the bandpass, stability, and sefd vs frequency (.ps) (.pdf):

Top: The 60 second average bandpass for the off source position.

red is pola, green is polB
The Y scale in degrees K.

I used the cals to scale the bandpass to kelvins.
I didn't divide by the band pass shape (since that's what i'm showing) so the frequency structure is coming from the filters, etc.
The True Tsys will be the average over the entire band.

The ripples at the left side of the bandpass are coming from the cavity filter in front of the dewar (to keep out the tv station at 692 Mhz).
PolA has more frequency structure than polB.

This was also seen in the A2524 double position switching data back in 30sep10.

In this case the 1 Mhz standing wave from bowl to rcvr was much larger for polA.

Middle: This plots the rms/mean along each channel for the 60 1 second records. The black dotted line is the expected rms/mean (from the radiometer equation). The ratty bandpass looks to be stable in time.
Bottom: The SEFD vs frequency using 3.32 Jy for the source flux (at 750 hz).

This was computed as posOff/(posOn-posOff) * srcFluxJy (or TsysDeflection/ (srcDeflection/srcFlux))
The ripple on the left of the sefd remains from the cavity filter

The off position Power is mainly coming from the dewar (it does not pass thru the cavity filter).
The on position has much more power going through the cavity filter.
Because of this, the off/(on-off) does not cancell out the cavity filter ripple.

processing: 110308/800calib.pro

26sep10: calib run with byu antenna

On 24sep10 the 800 Mhz rcvr was reinstalled with the byu version 1.0 antenna. A calibration run was done on 26sep10.
the plots show the calibration run results (.ps) (.pdf):

the cal values may have changed slightly since a cal cable was replaced on installation.
Page 1: gain,tsys,sefd, bmwidth
page 2: coma,sidelobe, eta mainbeam, eta main beam plus first sidelobe.
page 3: pointing error

za has a -22.5 arc second offsets.

This could be from the feed mounting
It could also be from the platform tilt from the platform reinforcement. In this case we would expect a 1 az variation in za an az. We don't see this.. the two az sections: -80, and +80 differ by 160 degs so a 1 az term amplitude show just about change sign between these two points.. but the don't so it's probably a mounting problem.

processing: x101/100926/800calib.pro

11jan10 single pol BYU antenna gain,tsys,sefd,beam testing (top)

The penn state dual pol antenna was replaced with a single pol byu antenna on 22dec09. On 11jan10 calibration scans were done on the source B0618+145 to check it's performance.
The plots show the antenna performance (.ps) (.pdf):

Page 1: the az,za track across the dish for BYU feed
Page 2: gain,Tsys,sefd,BeamWidth for the BYU feed

The cal values used were the same as the old antenna (measurements by ganesh 13aug09)

Page 3: gain,Tsys,sefd,beamWidth for the Penn state feed for 06oct09->20dec09 data.

This was limited to the same freq ranges as the BYU data.
The Tsys vs Freq for the Penn State feed differs from the BYU feed

BYU : 780,755,710,730 (min to max Tsys)
PennSt: 730,710,780,755
The order is just about reversed. The spillover vs frequency may be different.

(this assumes that the cal values remained the same when the antennas were changed).

Page 4: coma,1st sidelobe,beam efficiencies for the BYU feed.
Page 5: pointing error for the BYU feed.

There is a large az offset. This may come from only having 1 source. The pointing error looks a little different from the penn state feed pointing errors.

Page 6: Compare beamwidths for BYU and PennState feeds.

Each frame is a different frequency (710,730,755,780).
Black is the BYU feed, red is the penn State feed.
The BYU feed beamwidths are smaller than the penn state beam width by about 4%. The BYU must illuminate more of the dish (or it's taper must be different).

SUMMARY:

The BYU feed has narrower bandwidths than the Penn State feed (by about 4%).
the Tsys vs freq increases in the opposite direction for the penn state (low to HiFreq) vs the BYU feed (hi to low freq).

The illumination vs frequency (spillover) may be different.

the SEFD for BYU is smaller than the penn state SEFD:

The smallest SEFD for BYU is 10.5 Jy (755 Mhz).
The smallest SEFD for penn state is 11.5 to 12 Jy.

processing: x101/100111/800.pro

12oct09 800 Mhz receiver band pass: (top)

An average bandpass for the 800 MHz receiver was measured on 12oct09. The setup was:

300 seconds of data averaged
tracking blank sky at za=15 degrees
mock spectrometer with 172 MHz bandwidth and 8k channels used

The plots show the averages bandpass for the 800 MHz receiver (.ps) (.pdf):

PolA is black, polB is red.
Top: the band passes normalized to unity (Tsys).

A baseline was fit to each spectra (linear + 22nd order sin/cos). It is shown in green

Bottom: Bandpass/Fit.

Some of the spikes are coming from:

750 MHz: This is the dc component of the complex mixers.
766.25,769.75: low power channel 63.
789.25/792.83/793.75: channel 67 ..the station at west end of island is off the air.

processing: x101/091019/800bp.pro

17sep09: 800 Mhz rcvr PolA, polB ratios jul-sep09 (top)

The x102 calibration data was used to measure the performance of polA versus polb for the 800 Mhz rcvr. Data from 2jul09 thru 14sep09 was used. The polA, polB data was extracted from the stokes I,Q measurements.

The plots show the 800Mhz rcvr performance and polB/polA ratios (.ps) (.pdf):

I only used sources with < 1% polarization (at 1400 MHz) so the polA,B ratios were not skewed too much by polarized sources.
Color is used to differentiate between sources.
Symbols are used to differentiate between sources.
Page1: Tsys,Gain, and SEFD for stokes I (all frequencies).

Some of the spread is caused by the variation with frequency.

Page2: PolB/PolA Tsys,Gain,SEFD (all frequencies).

The Tsys and gain ratio will be affected if the cal values are incorrect. The SEFD is not affected by the cal values.
02-06jul09 the sefd ratio is close to 1.
10aug-> 14sep09 the sefd polB/polA is greater than one.
some of the variation is caused by the variation in frequency.

Page 3: PolB/polA Tsys,Gain,SEFD 730 MHz.

the 730 Frequency was used for the entire stretch of time (some of the other frequencies were switched when the low power tv station 289.25 turned off).
From 10aug09->14aug09 SEFDB/SEFDA is greater than 1.2.

Conclusions:

02-06jul09 sefdB/sefdA is close to 1.

The new cal coupler was supposedly installed 03jul09 so this is probably not the problem (unless the date on the receiver log page i wrong).
The cal values were changed on 03jul09. This caused the Tsys,Gain jump 02jul to > 02jul09 (purple) this had no affect on the sefd since the sefd is independant of the cals.

10aug09->14sep09 sefdB/sefdA is greater the 1.2

There was a dual beam 430 run from 17jul-26jul09.

processing: x101/090917/chkpols800.pro

25aug09: azswing looking for chn 67 peak after chn turnoff. (top)

Chn 67 (789.25 video carrier) turned off on 12aug09. We continued to see a residual signal at the video and audio carriers. It was not coming from the old chn 67 because the people at the station told us that the transmitter had been dismantled.
On 25aug09 an azswing was done to find the azimuth of the peak value of this signal. The setup was:

az spin at .38 deg/sec and za=18.
mock spectrmeter sampling at 172Mhz bw, 8192 channels and .1 seconds.

The plot shows the azimuth dependence of chn67 video and audio carrier (.ps) (.pdf):

the plots are power in a single channel (21khz) vs azimuth
black: 289.25 video carrier
red: 793.75 audio carrier.
green: baseline taken as a range of freq below the video carrier.

The video peaks at az=-46 (or 314) degrees. There is also some power around 40 and 60 degrees. These directions given the maximum power scattered into the dome. They are not necessarily the directions toward the transmitter.
processing:x101/090825/azswing.pro

10aug09: beam squint in the 800 Mhz rcvr (top)

The calibration data from 28jun09-02jul09 was used to measure the beam squint in the 800 Mhz rcvr. The plot shows the beam squint amplitude vs the amplitude of the beam squint (.ps) (.pdf):

The beam squint amplitude in asecs is the maximum value of the beam squint when the azimuth is pointing in the beam squint position angle direction. The beam squint for a given azimuth is:

beamSquintAz=beamSquintAmp*cos(az - beamSquintposAngle)

The different colors are taken at various frequencies.
It looks like the major beam squint pointint error is in za (along the azimuth arm).
The low freq beam squint 710 Mhz is large.

processing: x101/090810/bmsquint.pro

23jun09: rfi in the 800 Mhz rcvr (top)

To measure rfi in the 800 Mhz rcvr to tests were done:

14jun09: an az swing 270->630 degrees was done to see which direction the rfi peaked in.

Rfi with the same az peaks are probably coming from the same source.
This was done before the filter was installed after the 1st amp.

18jun09: freq hopping.

Data was taken with the band centered at 750 and 753.7 Mhz.
If the rfi was being created by a mixer harmonic, then changing the lo by 3.7 Mhz should move the rfi by a multiple of this.

az swing on 14jun09:

The setup was:

az 270 -> 630 degrees. az velocity about .38 degrees/sec.
za=18 degrees and fixed
172 Mhz band centered at 750 Mhz.
Sample data at .1 seconds.

Dynamic spectra for clockwise azimuth swing (.gif):

The vertical scale is -90 to + 270 degrees of azimuth.
polA and polB have been averaged.
the large triple rfis are video, color, audio carries for tv stations:

765.25 : chan 63
789.25 : chan 67

The azimuth dependence of the various birdies in the band (.ps) (.pdf):

17jun09: ripple appears in polB (top)

A ripple appeared in polB of the 800 Mhz Receiver. The timeline was:

15jun09: ganesh, stephen tune dipole
16jun09: 16:46 no ripple in Polb
17jun09: afternoon stephen tightens some cables in 800 Mhz system.
17jun09: 16:05 ripple seen in polB
18jun089 -> the ripple remains in polB.

The plots show the appearance of the ripple in polB (.ps) (.pdf):

red is pola, green is polb.
Page 1:

top. 16jun09 600 second average spectra (16:38 ast)
bottom 17jun09 90 second average spectra (16:04 ast)

Page 2: blowup of 17jun09 average spectra.

the spacing is .5 to 1 mhz (1-2 usecs). This would be a long distance if it was a reflection.

Date taken on 18jun09 at various times and configurations continued with the ripple in polB.

processing: x101/090617/polB_bad_800.pro

16jun09: calibration run 800 MHz receiver. (top)

A calibration run was done using the 800 MHz receiver on 15,16, and 17 jun09.The status of the feed/receiver was:

updated pointing model in az by 10asecs to remove final az error offset
turret at 187.05
dipoles were retuned 15jun09 afternoon, cables replaced.
Switched from 260 IF to 1-2 ghz IF.
Still using the room temperature receiver.

The plots show the system performance for the 800 MHz rcvr (.ps) (.pdf):

On 16jun09 evening i switched the 4th band from 790 to 775 to see if the rfi was less... (it wasn't)
On 17jun09 evening i switched the 4th band to 792 with 3 mhz bw..

Page 1: average spectra from first pattern.

710 and 730 are 25 MHz bandwidths
740 and 790 are 12.5 MHz bandwidths
790 had a tv stations () in the band causing interferences

Page 2: average spectra from first pattern.

710 and 730 are 25 MHz bandwidths
740 and 790 are 12.5 MHz bandwidths
775 had a tv stations (765/769) in the band causing interferences

Page 3: gain,Tsys,sefd, beamwidth.

The blue 790/775 results jumps around from the rfi.

Page 4: coma, sidelobe height, main beam efficiency, main beam + first sidelobe efficiency
Page 5: pointint errors.

I've ignored band 4 (790/775 MHz)
still have a small offset in az.

Page 6: az,za coverage of these strips.

processing: x101/090616/calib800.pro

13jun09: tv station turn off date, rfi, and calib. (top)

    The new crossed dipole feed was installed in the dome on 12jun09 with the cavity filters in front of the dewar. The dewar was still room temperature, and the filters after the dewar are not yet installed.

    Data was taken for 60 seconds with the mock spectrometer. The setup was:

az,za fixed at 285/10.
172 MHz centered at 750 MHz was taken with the 260 MHz IF (the band was centered at 325).
.1 Seconds integrations were made.

The plots show the bandpass and rfi in the band (.ps) (.pdf):

Page 1: bandpass

Top: avg 60 seconds. red=polA,green=polB. This is a linear scale where the largest birdies go offscale.

The low power tv channels 65 and 67 are flagged at the bottom of the plot (video and audio carriers).

Looks like they are transmitting but there isn't much modulation.

The birdie at 750 is DC.
The birdies at 730,734 and 711 are probably mixer images of the tv stations.
The band is supposed to fall off below 700 MHz and above 800.

On the spectrum analyzer it falls off above 800 but is pretty flat down to 600 MHz.
The fall off seen in the plot is probably from the baseband fitlers of the pdev spectrometer.
The low freq junk is probably from the other sideband of the mixer.

the 720 bump coming from the other side band is: 750 + 325 + 325 + (750-720)= 1430MHz.
If the filter was letting these freq thru, then it would explain the increase in system noise.

Middle: A db plot of the bandpass. The tv stations are about 35 db above the noise floor (rbw=172./8192=21 khz).
Bottom: rms/mean be channel for the 60 seconds of data. The measured rms : .023 is close to th expected value: .022.

Page 2: blowup in frequency of the bandpass (db scale).

The second plots are from a short calibration run (.ps) (.pdf) on B0758+143 (4.7 Jy @ 740 MHz).

The setup was:

25 MHz bandwidth centered at 740 MHz was used.
The turret was at 188.5 degrees.
40 K was used for the calvalue

Page 1:

gain=6.1
Tsys=186
Sefd: 31
BeamWidth: 378 asecs

Page 2: coma,1st sidelobe, beam efficiencies. The sidelobe is low probably because the source was not strong enough for it to be seen.
Page 3: pointing errors:

az=-142 Asecs

.. this is because the attenna was mounted in a different spot from the helix that had been there.

za=142 asecs.

The model used the position from the old helix. The model offset had been +72 asecs. All the other feeds have an offset of -70 -120 asecs.. So this error puts the antenna closer to the other feeds.

SUMMARY:

low power tv channels 65 and 67 have not turned off.
the power in the low part of the band extends down to 600 MHz.
the za pointing error brings the model offset closer to the other feeds.
The azimuth error is because the turret position has changed.
TO do: track a strong source at different turret positions and match the sidelobes on each side of the main beam to find the correct turret position. I did this on 13jun09 but the source was not strong enough ..

processing: x101/090613/calib800.pro, mock800.pro

13apr09: 2 az swings looking at 820MHz band (top)

Two azswings were done the with 800 MHz test rcvr on 13apr09 with the dome at 19 degrees. The filter was set to 820 MHz to see how strong the interference in the high side of the 700-800 MHz band is. This will determine how fast the filter in front of the dewar will have to fall off on the high side.
The setup was:

azswings 270-630 and back at .38 deg/sec
za=19 degrees
800 MHz test receiver (not cooled) in dome was used.
The tunable 30 MHz filter after the preamp was set to 820 MHz.
172 MHz Spectra and 8192 channels (rbw=21 KHz) were dumped at a 1 second rate with the pdev spectrometer.
Data outside the 798-842 MHz range were ignored.

Dynamic spectra for the two azimuth swings (.gif):

The images show dynamic spectra in a az vs frequency plane.
The top image is the clockwise swing.
The bottom image is the counter clockwise swing.
The dtv station at 800-806 MHz is channel 69. It will move to channel 12 after 12jun09.
The 824 to 849 band is the cellular phone uplink (phone to tower).

828-835 has shows the 200 KHz gsm channels that are used.
It looks like many channels are being used at once. This is probably the frequency hopping in gsm that is going on.

Peak and mean spectra for az swings (.ps) (.pdf):

Page 1:

Top: peak hold spectra for the two az swings.

Black is the CW spin, red is the ccw spin.
The y Axis is db above the median spectral value. The rbw was 21 KHz.
The digital tx channel gets to about 40 db above the average Tsys.

Bottom: the mean spectrum for each az swing.

Page 2: Power versus azimuth:

Top The azimuth dependence for the median tv station power.

The y axis is the median dtv value/ median spectral value.
The main peak is at az=22 deg.
Smaller peaks occur at az= -59,-9, and 52.

Middle: 818.81 Peak strength for 818.81 vs az (rbw=21KHz)
Bottom: 819.14 Peak strenght for 8190.14 vs az (rbw=21khz)

Summary:

800-806: Tv station 69 will move out of the band after 12jun09
810-824 MHz

These had time variable bursts. The strongest was 818-820 at 45 db above Tsys.
I don't know whether this is representive of this band because of the time variability.

Cellular phones: 824-849

These did not get above 15 db above tsys in a 21 KHz band.
Since this is the mobile to tower, a cell phone closer to the observatory will be stronger.
i don't know how far away the cell phones in the data were from ao.

From the data we saw, you probably want the filter to be 30-40 db down at 820 MHz.

processing: x101/090413/azswing.pro

11apr09: chan 63,67:low power tv stations in the 700-800 MHz band (top)

The following low power stations have been seen in the 700-800 MHz band using the test rcvr. As of 23jun09 they are still broadcasting in the band.

chan	freq	notes
63	764-770	W63BF 42 km west of ao, 1.79 km south. translator station for wccv-tv yiyi avila channel 46 video carrier avg azswing value 44 db above average tsys. Peak value > 50 db above tsys (using 21KHz rbw). This was at an az= -16 deg. Has an fcc license for 35.6kw analog transmitter see chan 63 fcc info (.ps) This station has not filed a statement with the fcc to terminate transmissions on 12jun09. lat/long of xmiter: 18:19:31/67:10:13 fcc contact info/owner (.ps) Seen in detail in azswings 08apr09.
67	788-794	WTPM-LP 43 Km west of AO. 18.5Kw . see fcc info (.ps) seen in 620-890 MHz spectral scan Talking to someone who works at the station, they said they will be moving after12jun09. This is a translator station They have a constrution permit for lp digital channel 45 (.ps) so maybe they will be moving out of the band eventually

08apr09: azSwings for chan62/50:Where to put the 800 MHz filter. (top)

The 800 MHz receiver will cover the 700-800 MHz range after the the Tv stations in this range are transitioned to lower frequencies (on 12jun09).

A bandpass filter in front of the dewar is needed to:

Cut out the tv stations below this band
Cut out the cellular phone band 824-849 MHz (cell phone to tower uplink).

We would like to push this filter as close to 700 MHz as possible to give more suppression for the cell phone band.

The tv stations closest to the bottom of this band after 12jun09 will be:

chan 50 (686-692 MHz).

This channel is currently transmitting in digital as channel 62 (758-764 MHz)

chan 51 (692-698 MHz). We currently see the analog version of this station at chan 52. The spectral scan of 18dec08 saw the video carrier for chan 52 (699.25) 7 db above the noise floor (this may not have been the max since it was a fixed azimuth). The transmitter is about 60 miles east of AO.

On 08apr09 2 azimuth swings were done to see how strong channel 62 is above the current receiver (not cooled) noise floor. When it switches to channel 50, it will most likely stay on the same tower. The setup was:

azswings 270-630 and back at .38 deg/sec
za=19 degrees
800 MHz test receiver (not cooled) in dome was used.
The tunable 30 MHz filter after the preamp was set to 760 MHz.
172 MHz Spectra and 8192 channels (rbw=21 KHz) were dumped at a 1 second rate with the pdev spectrometer.
Data outside the 740-780 MHz range were ignored.

Dynamic spectra for the two azimuth swings (.gif):

The images show dynamic spectra in a az vs frequency plane.
The top image is the clockwise swing.
The bottom image is the counter clockwise swing.
The tv station around 760 is digital channel 62. This will move to channel 50.

It has a broad peak near az=0 degrees.

The tv station near 766 is analog channel 63. It is a low power station from aguada (1.79 km south of ao and 42 km west).

Plotting the spectra vs frequency (.ps) (.pdf):

Page 1: Tsys in Kelvins before the azimuth swings.

The cal was toggled for about 20 seconds. 40 K was used for the cal value.
Black trace: za = 11 degrees. 122 Kelvins
Red trace: za = 19 degrees. 129 kelvins
The za spillover 11 to 19 degrees increased Tsys by about 7 Kelvins.

Page 2:

Top: average spectra for the two azimuth swings.

The y axis is spectral density in db's above the median value. For the analog stations the RBW = 21 KHz.

The average value between the dotted red lines (channel 62) was computed for each second of the two azimuth swings.
analog channel 63 (765.25 Video, 769.75 audio) has the video carrier 44 db above the average Tsys value.

Middle: Average spectral density for Channel 62 vs azimuth position.

The units are db's above the median Tsys.
The black plot is the clockwise spin, the red trace is the counter clockwise spin
The az peaks are at: -60, -1, 26, and 52.2. They repeat for the two swings.
The average spectral power for channel 62 is 35 db above the median Tsys value.

Bottom: Chan 63 Video carrier pk values vs azimuth (rbw=20KHz)

The azimuth peaks are at -16,32.7 and 56 degrees. The two swings show the same values.
The peak value in 21KHz bw is > 50 db above the noise floor (also using 20Khzrbw). It looks like it saturated.

Summary:

chan	freq	Notes:
		lat/long AO: 18:20:39.44/66:45:10
50	686-692	Peaks 35 db above noise floor (from chan 62 measurements)
51	692-698	WRFB 60 miles east of AO. Currently broadcasting analog on channel 52 (see below). Will switch to chan 51 on 12jun09. Has fcc licencse for 256 KW ERP digital transmitter: see chan 51,52 fcc info (.ps)
52	698-70	will move to chan 51 on 12jun09. 18dec08 spectral scan saw video carrier at 7 db above avg Tsys. May be stronger since did not do an azswing. Current license is 275 KW ERP analog transmission. lat/long of xmter: 18:16:44/65:51:12
63	764-770	W63BF 42 km west of ao, 1.79 km south video carrier avg azswing value 44 db above average tsys. Peak value > 50 db above tsys (using 21KHz rbw). This was at an az= -16 deg. Has an fcc license for 35.6kw analog transmitter see chan 63 fcc info (.ps) This station has not filed a statement with the fcc to terminate transmissions on 12jun09. lat/long of xmiter: 18:19:31/67:10:13

chan 62/50--> bandpass filter needs to cut out the 35 db at 692 MHz.
chan 51.

If the power levels remain the same in the switch 52->51 then this should not be a problem. This assumes that chan 52 is currently broadcasting at full power. It certainly doesn't look like a 275 kw erp transmitter... Probably need to check this out some more.

chan 63:

It was mentioned that all low power stations will move out of the 700 MHz band after 12jun09. We need to verify this. There have been no fcc filings stating that they will stop transmissions on 12jun09 (chan 52 has done this).
the -16 deg az does not point at the transmitter. The station headquarters is in camuy. az=-16 degrees does point toward camuy (maybe this is just a coincidence).

processing: x101/090408/pdevazswing.pro

02apr09: Emergency services usage of 700 MHz band (top)

Emergency services have been allocated 24 MHz of bandwidth in the 700 MHz band. They will begin using this bandwidth after the dtv transition (jun09).
The band usage is described here (.ps) (.pdf):

763-775 (12 MHz)
793-805 (12MHz)

The entire report: Federal Strategic Spectrum plan (march 2008) is found on the ntia office of spectrum management page.

18dec08: spectral scan 620-890 MHz. (top)

Data was taken with the low frequency rfi feed (650-900 MHz) on 18dec08 around 16:00 hours. The setup was:

az,za=185,10 degrees. The turret was positioned to 188.5 degrees.
the cal was winked on/off at one hz. during the data taking.
the 25 MHz filter was tuned to a position and then data was taken for a few minutes. It was then moved manually to the next position.
The interim correlator was used with 1024 channels, 25 MHz bandwidth, 9 level sampling, and 1 second dumps.
The antenna is a helix that receives 1 circular pol.

Tsys in cal units:
the first plots show tsys in units of th cal (.ps) (.pdf):

The Top plot is the 832MHz band, the bottom plot is the 839 MHz band.
The processing was:

Try to throw output bad frequency channels by fitting a polynomial,sine wave to The median(calon/calOff) the removes the filter bandpass.
compute the median power over the good channels (also throwing out about 10% on the edges).
compute (calOff)/(calOn-calOff) and take the median over the N samples. Multiply the median cal off spectra by this value to get Tsys in Cal units.

Tsys is about 3 cal units. The cal is about 40K so Tsys is around 120K.

Spectral scan of 620 to 890 MHz.
The second set of plots shows the spectral scan from 620 to 890 MHz (.ps) (.pdf):

There are 12 plots. One for each 25 MHz band integration.
The top plot has a peak hold spectra over the entire integration time (solid line). The dashed line is the median spectrum from the N samples. The vertical units are db above Tsys.

The db units are probably only valid for the 832 and 839 MHz band where there was not a lot of interference.
The label MedianTsysVal shows the median bandpass value (linear scale) in correlator units. For optimum sampling this number should be +/- 20% from 1. The large rfi was turning the input signal into a sine wave. For some of the bands (say 660 MHz) the median Tsysvalue was only .04. The baseline then used to normalize to Tsys was then way to small.. So look at the large spikes but their absolute intensity is probably not very accurate. We can redo hopefully redo this with the mock spectrometers and do a little better (as long as the fft doesn't overflow).

the bottom plot is a dynamic spectra of the data. The vertical scale is in seconds. The color stretch used a db scale. Most of the rfi is there all the time.

A tour through the stronger rfi:

(also see tvFreq)
635 MHz band

627: channel 40: video carrier (pbs)
635: channel 41: digital station
639: channel 42: video carrier

660 Band

648: channel 43: digital
663: channel 46: video carrier

685 band

683: channel 49: digital
687: channel 50: video carrier

710 band:

703: channel 53: digital (yiyi avila...)
711: channel 54: video (yiyi avila..)

735 band:

723:channel 56:

There is no license for chan 56 in pr.
video carrier should be at 723.25, audio:727.75
This may be intermods created by channel 54 below..

747.25: channel 60: video carrier.

This is the arecibo station.
Moving to chan 14 after 12jun09

735.25/739.75: chan 58 video/audio

moving to chan 48 after 12jun09.

760 band:

751.75: audio carrier for channel 60. moving to chan 14 after 12jun09
761: channel 62 digital. moving to channel 50 after 12jun09
765.25/769.75: channel 63 audio/video carrier.

the audio at 769. is stronger than the video.
low power tv station serving aguada. Office in camuy. see fcc info (.ps)

771.25: chan 64 video carrier. moving to chan 18 after 12jun09

785 band:

775.75:channel 64: This is the audio carrier. moving to chan 18 after 12jun09
789.25/793.75: channel 67 video carrier/audio carrier

This is a lower power tv station 18.5Kw 43 km due west of AO. see fcc info (.ps)

795.25: chan 68 video. moving to chan 49 after 12jun09.

807 band

803: channel 69: digital. moving to chan 12 after 12jun09.

832 band, 839 band:

824-849 cellular phone uplink band (handheld to tower)

850 band:

Not sure what this is unless it's the spill over from the downlink.

875 band:

869-894 is the cell phone down link

Things to check out:

Check the signals 722.75-728. see if they are intemods..
Low power stations to check on:

processing: 081218/rfifeed.pro

05sep08: looking for the turret position. (top)

The source B1607+268 (1") was used to find the correct turret position for the 800 MHz feed. The procedure was:

track the source
Offset the turret by a fixed amount. Offset the azimuth position to compensate for this.
Do an azimuth strip using this turret position.
Look at the sidelobes and see if they are equal.
Repeat this for 7 positions about the turret center.
When the turret is centered on the tertiary the sidelobes should be symmetric.

The setup was:

rf frequency 1050 MHz
interim correlator 1 second sampling with 25 MHz bw.
Do strips at 187.2 + [-3.-2,-1,0,1,2,3] turret degrees. Repeat this twice.\
Do strips at 188.45 + [-1.5,-1,-.5,0,.5,1.,1.5] turret degrees.

The plots show the az strips thru the source for the various turret positions (.ps) (.pdf):

Page 1: az strips thru the source (linear).

There are 7 az strips in each frame. The center is flagged with the green line.
The top two frames have 1 degree steps in turret centered at 187.2

The left sidelobe is larger for 184,185,186 turret degrees.

the bottom frame has .5 degree steps in turret centered at 188.45

Page 2: az strips thru the source (db scale).

These are the same plots as page one but using a db scale.
around 188 turret position the sidelobes start to balance out.

The new turret position was taken to be 188.5. The old position of 182.7 has very uneven sidelobes. We should probably redo this test with a stronger source starting at 188.5 as the center and moving up and down in turret position to verify that this is the real center.

The pointing model has not yet been updated for this change.

Data was taken with the az off=-346.01.
1 turret degree moves the pointing by 45 asecs/deg (need to check the sign..)
moving from 182.7 to 188.5 should move the offset by 261 asecs (which direction ???).

processing: x101/080905/rfifeed.pro

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