• Shows jumps vs decimation 1 to 20.
• The size of the jump decreases with increasing input level. The input level changes with the decimation used (but not by more than a factor of 2 in voltage).
  

• Not doing the first butterfly down shift make a big difference.
  

• Shows jumps for adjpwr:15,20,25,30,80 with various pshifts. Has fftlens 8192,4096,2048,1024,512
  

23apr10: spectral jumps with noise source.

• 8192 channels, 172 Mhz  bandwidth.
  
•  integrate for 60 and 300 seconds.
  
• Take data with adjpwr of 30,45 and 120.
• Use the standard pshift=0x1ff5. Also try pshift=0x0ff5 (where first butterfly down shift is  not done).
• test numbers:
1. pshift=0x1ff5, adjpwr=30, 60 secs
   
2. pshift=0x1ff5, adjpwr=45, 60 secs
   
3. pshift=0x1ff5, adjpwr=120 , 60 secs
4. pshift=0x1ff5, adjpwr=120 , 300 secs
5. pshift=0x1ff5, adjpwr=30   , 300 secs
   
6. pshift=0x1ff5, adjpwr=45   , 300 secs
7. pshift=0x0ff5, adjpwr=45   , 300 secs
8. pshift=0x0ff5, adjpwr=30   , 300 secs
9. pshift=0x0ff5, adjpwr=120 , 300 secs
   

• Page 1: The jumps at channel 2048 for the 9 tests.
• A linear fit was done to channels 2007-2047 (fit1 red) and (2048-2088 fit2) green.
• The jump was: (fit2[2048] - fit1[2048])/mean(data[2007:2088]) - 1.
  
• The vertical scale is Tsys close to Channel 2048.
• Page 2: jumps, power vs  test number:
• Top: The size of the jump vs test number. Black is polA, red is polB
• Bottom: the A/D rms in counts fore each test.
• Page 3: Size of jump vs a/d rms input level
• polA is +, polB is *
• Black has the standard pshift=0x1ff5, red has pshift=0x0ff5
• The size of the jump decreases as the rms input level increases.
• Not doing the first down shift in the butterfly stages makes a large decrease in the jump size.
  

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