MICRONETICS RFN55C2

FULLBAND HIGH ENR MICROWAVE NOISE SOURCES
S, C AND X BANDS
6.2008
D ESCRIPTION
Micronetics line of fullband noise
sources are specially designed for builtin test and calibration where there is
significant path loss between the noise
source and the device.
This family of high output fullband noise
sources with their compact size are specially designed for ease of integration
into microwave systems.
FU L L B A N D O UTPUT C HARACTERISTICS
FO R U S E IN S Y S T E M S
MODEL
RFN55L
RFN55S
RFN55C
RFN55C1
RFN55C2
RFN55X
FREQUENCY
RF OUTPUT
EXCESS NOISE
RATIO (dB)
FLATNESS
1.0 to 2.0 GHz
2.0 to 4.0 GHz
4.0 to 8.0 GHz
3.95 to 5.85 GHz
5.85 to 8.20 GHz
8.0 to 12.4 GHz
55(MIN)
55(MIN)
55(MIN)
55(MIN)
55(MIN)
55(MIN)
2.0 dB P-P
2.0 dB P-P
2.0 dB P-P
2.0 dB P-P
2.0 dB P-P
4.0 dB P-P
WAVEGUIDE C HART
MODEL
RFN55C1
RFN55C2
RFN55X
FREQUENCY
3.95 to 5.85GHz
5.85 to 8.20GHz
8.20 to 12.4GHz
WAVEGUIDE
WR-187
WR-137
WR-90
With their rugged and stable design, the
heart of these noise sources is a small
chip and wire hermetic noise module.
This is embedded in the housing with a
precision launch to the coaxial jack.
This design gives is much more stable
and rugged than traditional coaxial
noise sources which rely on pill packaged diodes and beryllium copper bellow assemblies which are not only are
less reliable, but use hazardous materials.
C O N F I G U R A B L E TO Y O U R
REQUIREMENTS
Micronetics fullband noise sources are
based on a coaxial design as the base
part. As standard options, noise
sources can be ordered with either
• Coaxial Isolator
• Waveguide Output
• Waveguide Isolator
S PECIFICATIONS
C O M M O N A PPLICATIONS
Radar Built-in Test/Calibration; where there is significant path loss between the noise
source and the receiver. For example, a 30dB coupler can be used to feed the test
noise signal into the receiver which minimized noise figure while still allowing 25 dB
ENR.
-Operating Temp: -40 to +85oC
-Storage Temp:
-65 to +125oC
-Supply Voltage: +15V +/- 1.5V
-Current Draw: @ 200 mA (Max)
-Output Impedance: 50 ohm
-Peak Factor:
5:1
Jamming Systems; these high output devices, when used in conjunction with power
amplifiers, offer an efficient means to jam RF/microwave signals.
Antennal Calibration; high output noise can be used for antenna calibration to counter
the effects of over-the-air transmission loss.
MICRONETICS / 26 HAMPSHIRE DRIVE / HUDSON, NH 03051 / TEL: 603-883-2900 / FAX: 603-882-8987
WEB: WWW.MICRONETICS.COM
FULLBAND HIGH ENR MICROWAVE NOISE SOURCES
S, C AND X BANDS
There are several primary uses for employing a noise signal for built-intest.
HO
1. Using Noise for Built in Test:: These high output moduels are ideal
for buidl-in-test wehrer there is a significant path loss between the noise
source and the point at which the noise signal is used. For an example
an 8-way splitter in an array antenna receiver will allow enough power at
the receiver plane at each of the eight receive paths. Another example
allows a high directivity coupler to be used (i.e., 30 dB) allowing better
receiver noise figure.
R F N 5 5 X -X
2. Noise Temperature (noise figure) or Sensitivity Testing: This test
uses the noise source to supply a known excess noise ratio (ENR) to a
device under test for a Y-factor measurement. By taking two receiver
readings, one with the noise on and one with it off, Y-factor can be determined. By knowing the ENR and Y-factor, one can calculate noise temperature (figure) or sensitivity.
3. Frequency Response: The noise source being broadband can be
used as a replacement of a swept source to calculate frequency
response of a receiver or other device. By putting in a known spectral
signal at the input and taking a reading at the output, one can determine
the gain or loss over frequency of the entire system. Noise sources are
inherently extremely stable devices. In addition, the circuitry is much
simpler than a swept source which increases reliability and lowers cost.
4. Amplitude Reference Source: The noise source can be used as a
known reference signal. By switching in the noise source from the live
signal, a quick test can be performed to check the health of the chain or
calibrate the gain/loss. For this test, noise can be injected into the IF
system as well as the RF to test/calibrate the path.
For more information on using noise for built-in-test, read the Feb 2004
Microwave Journal article authored by Patrick Robbins of Micronetics.
http://www.micronetics.com/articles/microwave_journal_02-04.pdf
U S E F U L N OISE E Q U ATIONS
Calculating Y-Factor:
YFact = N2 / N1 Where N2 is measured power output with noise
source on and N1 is the measured power output with noise source off.
Calculating Noise figure from ENR and Y-factor:
NF(dB) = ENR (dB) - 10 log10 (YFact -1)
Converting ENR to Noise spectral density (N0):
0 dB ENR = -174 dBm/Hz
Calculating noise power in a given bandwidth (BW) from noise
spectral density:
Power (dBm) = N0 + 10log(BW)
W TO
O RDER
Model
L = L band *
S = S band *
C = C band
C1 = C band
C2 = C band
X = X band
Option
0 = Plain
1 = Coax Isolator
2 = Waveguide
3 = Waveguide Isolator
* waveguide not
available on S
and L models