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Transcript
Justin Wright
October, 17 2002
Local Oscillator/Harmonic Mixer Frequency Measurement System
Introduction
We have constructed a circuit capable of measuring frequencies on the order of 140
Ghz. It was built as a backup to the very expensive EIP counters and requires only a
counter capable of measuring up to 3Ghz (We used an HP Model 5386A). The circuit is
based a local oscillator and a harmonic mixer. The components were purchased from
stock as discrete components
Fig. 1 is a photograph of the assembled system and the circuit can be identified.
The signal from the microwave source to be counted is feed into the harmonic mixer
along with the output of a Dielectric Resonant Oscillator (DRO) running at 17.5 GHz.
The mixer IF output is then run through two amplifiers with a gain of 20 dB each. The
signal from the IF port of the harmonic mixer is the difference between the 8 th harmonic
of the DRO and the reference signal. It is this signal that serves as the input to the
frequency counter. Realize that this system cannot distinguish whether the microwaves
input are below or above 140 Ghz. This can be determined, however, by increasing or
decreasing the frequency of the microwaves (using the mechanical bellows on the EIO)
and observing the effect this has on the measurements.
Operation:
Before turning on the system via the switch be sure the second amplifier output
has been connected to a measurement device as an open load may damage the
amplifiers. The red light indicates that power is on. There is a 250V, 2A fuse on the
power converter.
The DRO puts out a frequency of 17.500 GHz. This signal goes into the LO end
of the Harmonic Mixer. The microwave signal goes into the RF end of the Mixer.
(NOTE: The maximum total power that can be sent into the mixer is 100 mW. And the
power from the LO should always be greater than the RF power. Also note that the
DRO output power is about 50 mW. Many frequency counters will be damaged by that
much power. Be sure to insert an attenuator before measuring the LO frequency
directly.)
As can be seen in Fig. 2, the frequency measured by this system is accurate
from –600 MHz to –150 MHz and from +150 MHz to +2000 MHz (measured relative to
140.00 GHZ.) In the 0 MHz +/- 150 MHz range, the readings increase rapidly due to a
discontinuity at 0 MHz. This discontinuity is recorded in Fig. 2 and is probably caused
by the limitations of the Amplifiers and of the Mixer itself. This is acceptable. The upper
and lower limits are set by the operation range of the EIO. This frequency is changed
by mechanically altering the length of a resonance cavity in the microwave generator.
For a given voltage, though, only a certain range of cavity length (and thus a certain
range of frequency) will work. Figure 3 shows a close view of the discontinuity at zero
frequency. Fig. 4 is a circuit diagram, including the couplers used during testing.
Justin Wright
October, 17 2002
List of Components
Power Supply
Model: Nemic-Lambda ZWS15-15
Input voltage/current: 120 VAC @ ~0.45 A
Output voltage/current: +15 VDC @ ~ 1A, 1.2 A peak
More info: See www.lambdapower.com/products/zws-series.htm
Amplifiers:
Model: Minicircuits ZFL-2000
Input voltage/current: +15 VDC @ 120 mA (0.1 μF cap kills noise)
Input power: +5.00 dBm input power (no damage)
Output power: +16 dBm output max
Frequency range: 10 – 2000 MHz
Gain: 20 dB (min.), +/- 1.50 Max flatness
More info: See www.minicircuits.com – search model number
NOTE: Do NOT power with open load.
Local Oscillator:
Model: Miteq DRO-J-17500-HT-ST
Input voltage/current: +15 VDC@ 230 mA (196 mA measured)
Output frequency: 17.500 GHz
Tuning (mechanical): +/- 10 MHz
Output RF power: +17.0 dBm (+18.0 dBm measured), 50 mW
More info: See -wave parameter sheets & manual (red binder)
Harmonic Mixer:
Model: Hughes (Millitech) 47448H-1002, Serial#: 020
Input frequency: 140 GHz RF, 17.500 GHz LO
Input power: 100mW total between RF and LO (LO > RF)
More info: See -wave parameter sheets & manual (red 3-ring)
See Hughes catalogue (ask Don)
Justin Wright
October, 17 2002
Fig.1
Justin Wright
October, 17 2002
LO/Mixer system accuracy
LO/Mixer beat frequency (MHz)
2500
y = 0.9998x - 6.937
2000
2
R =1
1500
1000
500
0
-500
-1000
-1000
-500
0
500
1000
1500
2000
2500
EIP frequency (MHz + 140 GHz)
Fig. 2
Linear fit excludes points between –150 MHz and +150 MHz due to discontinuity.
Justin Wright
October, 17 2002
Fig. 3
Discontinuity
LO/Mixer beat freq. (MHz)
2000
1500
1000
500
0
-500
-1000
-300
-200
-100
0
100
EIP freq. (MHz +140 GHz)
200
300
Justin Wright
October, 17 2002
Fig. 4