photo of sky at
start of az=90 observation (.jpeg)
plots:
normalized
caldeflection vs elevation (.ps) (
.pdf)
tsys
vs elevation, the fits (using Tatm=270K) , and the fit
residuals (.ps) (
.pdf)
the fits using Tatm=290K (.ps) (
.pdf)
a
closer looks at the Tatm contribution to Tsys as well as the
bump around el=60 deg (.ps) (
.pdf)
Tsys
fit values vs frequency (.ps) (
.pdf)
fitting
different elevation ranges to the tsys vs el atm contribution
(.ps) (
.pdf)
Intro
Tsys vs elevation was measured on 20sep22.
The measurements consisted of:
- The telescope was driven between 7 and 87 degrees
elevation at .5 deg/sec
- az=0 drive up and then drive down
- az=90 drive up and then drive down.
- datataking started at 14:30 and ended around 15:00
- While driving the telescope the mock spectrometers took
data:
- 7 172 MHz bands were taken. cfr: 8219.00 8363.00 8505.00
8647.00 8789.00 8931.00 9073.00 MHz,
- 512 channel across each 172 MHz band was used.
- the hardware cal was run during the experiment.
- spectra were sampled at 2 milliseconds.
Processing the data:
- the idl routine masgetscanhwc()
was used to input the data.
- The total power in degK is computed for the calon,caloff
data for each 40 millisecond cal cycle.
- the TsysCalOff is then used for the rest of the
processing.
- the idl routine p12mfittsys()
was used to fit to tsys vs elevation. The fit was:
- Tsys=Tconst + Tatm*(1-exp(-tau*secza)) +
Tcmb*exp(-tau*secza)
- Fit for Tconst and tau
- set Tatm =270 K, Tcmb=2.725k
Plotting the results:
The calcycle is 20ms calOn, 20ms caloff.
Since the telescope was moving at .5 deg/sec , TsysCalOn
will differ slightly from TsysCalOff. The
cal difference will then include this small change.
The first plots looked at whether the cal deflection was
biased by the elevation motion.
The plots show the normalized caldeflection vs elevation
(.ps) (.pdf)
- The 8219 Mhz band was used for the plots.
- The up and down scans at az= 0 were used.
- Page 1:
- Top: Normalized Tsys vs elevation:
- Each curve was normalized by their median value.
- black: PolA 0 to 90 degrees moving up
- green:PolB 0 to 90 degrees moving up
- red :PolA 90 to 0 degrees
moving down
- blue :PolB 90 to 0 degrees moving
down.
- middle: Tsys rate of change while moving.
- green and black are moving up in el (so tsys is
decreasing)
- red and blue are moving down in el (so tsys in
increasing).
- there is very little change in tsys above about 30 deg
el
- Bottom: CalDeflection vs elevation (normalized to median
value)
- let eps be the change in Tsys during the 40ms
cal cycle.
- CalDeflectionM= (calDeflection +tsys) - (tsys + eps) =
calDeflection - eps
- When moving up eps is < 0 .
- When moving down eps is >0.
- The blue,red moving down shows a constant ramp in
CalDeflection over the entire el range
- But eps was > 0 only for el < 30 deg. So
the slope we see is not from the motion of the
telescope.
- Page 2: the cal deflection change repeats for the motion
at az=0 and az=90
- the change in cal deflection could just be and
electronic gain variation... but
- Top: PolA cal Deflection for up,down at the two azimuth
positions
- Bottom: PolB cal deflection for up,down at the two
azimuth positions.
- The change in cal deflection:
- repeats for scans going up in elevation at different
azimuths.
- repeats for scan going down in elevation at different
azimuths.
- So the change in cal deflection is not an electronic
gain change (unless the electronic gain depends on the
direction of el motion).
- The change in value is 1% of the cal value.
- if it is a level change rather than a gain change then
it is about 32K*.01=.3K
- I'm not sure what could be causing this?
The 2nd set of plots shows tsys vs elevation, the fits
(using Tatm=270K) , and the fit residuals (.ps) (.pdf)
- Each page shows a different freq band.
- All 4 scan (az=0 up,down, az=90 up,down) are over
plotted in different colors.
- Top: Tsys vs elevation and fits for polA and polB
- middle: fit residuals (data-fit) for polA
- bottom: fit residual (data - fit ) for polB
- Looking at the residuals there is a small bump around
el=60 deg for all bands.
- The fits are too high at low elevation and a bit low at
high elevation.
- I repeated
the fits using Tatm=290K (.ps) (.pdf)
- this gives the same fit residuals.
- Change Tatm only changes Tconst and tau some
The 3rd plot takes a closer looks at the Tatm
contribution to Tsys as well as the bump around el=60 deg
(.ps) (.pdf)
- Top Atmospheric contribution to Tsys.
- The Tconstant parameter from the fits was removed from
each Tsys data set.
- Az=0 up direction was used. All 7 freq bands polA,B are
over plotted.
- All freq bands and pols overlay one another.
- At el=90 deg the Tsys contributions is about 6.3K ( this
is atmospheric and any scattered radiation).
- Bottom: A blowup of the atmosphere Tsys contribution 50 to
90 deg el.
- The slope changes between elevation of 60 and 70 deg.
The 4th set of plots has Tsys fit values vs frequency
(.ps) (.pdf)
- Top: Tsys vs frequency for elevation = 60 deg.
- the small error bars are the fit sigmas.
- Middle: the Tconst fit value vs frequency
- this includes Trcvr and any other constant temperature
values.
- The 4 scans overlay each other pretty well.
- The + are just to show where the data was measured. The
coef sigmas were much smaller than this
- Bottom: The opacity (tau) from the fits vs frequency
- Black in polA, red is polB
- The value is .015 to .017.
- Not sure what the dip at 8931 means (may be weak
rfi).
processing: x101/220920/tipper.pro
Tsys from atm and scattered radiation
The atmospheric contribution to tsys has a
sec(za) dependence with za. Scattered radiation should
also have an dependence on za (or el)
- You might think that the largest contribution from
scattered radiation occurs at el =90 deg
- The secondary over illuminates the primary and sees the
ground.
- As you move to lower elevation some of this spillover
will start to see the cooler sky.
- This el dependence would be opposite to the atm
contribution (largest at low elevation).
- I tried fitting different elevation ranges to the atm
contribution and then looked to see if the residuals told us
anything about the scattered radiation.
The plots show the results from fitting different elevation ranges
to the tsys vs el atm contribution (.ps) (.pdf)
- I ended up fitting 6 elevation ranges:
-
el range (deg)
|
color
|
notes
|
6 to 88
|
red
|
all the data
|
6 to 33
|
green
|
bottom 1/3
|
6 to 48
|
blue
|
bottom 1/2
|
33 to 60
|
light blue
|
middle 1/3
|
48 to 88
|
light brown
|
upper 1/2
|
60 to 88
|
purple
|
upper 1/3
|
- Top: Tsys vs el fits
- Bottom: fit residuals (data -fit)
- If you don't fit the bottom 33deg, then the fit values
at low el are too large (but up to 8 degk)
- If you include the bottom 33deg in the fit then
the maximum residual is about 1degK.
- This may not be saying much, since the strongest
curvature is at the lower elevations.
- It doesn't look like you can separate out the Tatm from
the scattered radiation by playing with the elevation
ranges.l
processing:220920/chkfit.pro
SUMMARY
- elevation strips 7 to 87 degrees and back were done at
az=0 and 90 degrees.
- Tsys was fit to elevation using
Tsys=Tconst+Tatm*(1-exp(-tau*secza)) + Tcmb*exp(-tau*secza)
- Tcmb=2.725
- Tatm was set to 270K (290K was also tried)
- there was good agreement in the fits at different
azimuths.
- If the cloud conditions had changed, then it wouldn't
have been constant.
- Tconst and tau(opacity) were fit for.
- tau was about .015.
- If we changed Tatm then Tconst and tau would vary.
- At el=90deg there was about 6.3K from the atmospheric fit.
- the slope of tsys vs el changed around el = 60 to 70 deg.
- The cal deflection varied over a strip
- this variation differed going up and down in elevation
- but it repeated at different azimuths (so it probably
wasn't a gain variation with temperature).
- We looked at whether you could separate out the Tsys from
the atmosphere and from scattered radiation by playing
with the elevation range using in the fitting.
- nothing obvious popped up.
