Custom-Calibrations Photonic Repair represented in Japan at the FOE conference!

 

Custom-Cal?would like to thank?Kenji Yano?and?Joe D’Agostino?of?Amplitude Technical Sales,??for introducing?us?to Japan! Thank you also to?Nanese Katayama, Management Assistant at?X-one Technologies.

Recently, Custom-Cal was represented in Japan at the Photonix 2012 Expo and Conference. This is an international event representing the business hub of Asia?s optics and laser industries, held in Tokyo in April of 2012.

Nanese Katayama shares Custom-Cal information at the Photonics Expo!

Here are some links to exhibits that placed Best in Show that we found the most interesting!

?PD-LD ?(one of our local customers)

Smart Eye Glasses

Specialized lighting products

Camping light?(sold at Walmart)

Solar Cogen


Thriving In A Down Economy – Selling Used Agilent, HP, Tektronix Equipment

Custom-Cal adds value and helps clients stay upright in a market downturn. We take the mystery and frustration out of finding the right buyer for your test equipment. No more blind bids, lot bids, auctions, mystery buyers or unwanted solicitation.

used agilent tektronix hp test equipment

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Custom-Calibration Assist Nistica To Meet ISO Requirements

In order to meet?Nistica immediate needs Custom-Calibrations established a Custom Response Team involving Randy Yousey, Tom Gadosky, Bill Pazik,?Peter Kostoulas, Irina Sakhartchouk and Bob Adamson.

Examples of the team?s accomplishments include:

  • Creating quotes for sixty-five items on site and identifying equipment requiring calibration.
  • Custom-Cal was able to accommodate and meet Nistica?s three day expedited calibration needs with our on-site services supplemented with pickup and delivery services.
  • The team calibrated complex optical gear such as: SWS 15107, SWS15101, and SWS20006 systems?on-site within the specified time constraints. Custom-Cal personalized responses to support Nistica?s work status requirements via email?and telephone communication.
  • ?Custom-Cal?also provided the customer with an online “My Data System” which allows calibration certificates to be viewed online, as well as assistance in recalling equipment?for sequent calibration.

Custom-Cal Gains ISO 9000 Certification in RF & Optical Repair

Custom-Cal has successfully completed ISO 9000 registration. ISO 9000?consists of a family of standards?that apply to quality management systems. In order to be certified, there are requirements and standards that have been met by the company. ?Some of the requirements include: monitoring processes to ensure they are effective, having a?set of procedures that covers all key processes in the company and?facilitating continual improvement. ?For Custom-Cal, the ISO 9000 certification specifically applies to calibration and repair of Test and Measurement equipment (primarily RF and optical units), on-site calibration services and new & used equipment sales.

Agilent: HP Spectrum Analyzer 8566/7/8

The HP8566 is the workhorse of the RF industry. This product has been around for some time proving its reliability, yet its age makes maintenance necessary. Custom-Cal has access to OEM Operation Verification software and manuals, which ensures economical performance testing. This allows the interns to officially conduct tesing and provides for ample time to make adjustments. Notably beyond performing routine performance tests and adjustmets, Custom-Cal is staffed with senior repair technicians comfortable in component level troubleshooting and repair. The combination of young willing talent and depth of expertise of senior members is of value to customers. These service and calibration skills can be applied to the following models: 8566A, 8566B, 8567A, 8567B, 8588A?and?8588B, as well as the EMI Option 462?for the 8566B and?8568B, which?is?compatible with the?85650A Quasi-Peak Adapter, the 85685A RF Preselector, the 85869A EMI measurement software and the?85867A EMI receiver functions program.

Master List of Equipment Needed

Standards:

  • HP 3335A Frequency Synthesizer
  • HP 3455A or HP 3456A System DVM
  • HP 83640A Synthesized Sweeper
  • HP 8902A Measuring Reciever or HP 436A or HP 438A Power Meter
  • HP 8485A or HP 8481A Power Sensor
  • HP 8112A or HP 8116A Pulse Generator
  • HP 909A Option 012 50 Ohm Termination
  • HP 8721A Coaxial Directional Bridge
  • HP 11667B or HP 11667A Power Splitter
  • HP 5061A Frequency Standard
  • HP 5316A Universal Counter
  • HP 3456 Voltmeter
  • HP 8566A/B Spectrum Analyzer
  • HP 8672A Synthesized Signal Generator
  • HP 3312 Function Generator
  • HP 8340A Signal Generator
  • HP 5345A Electronic Counter

Accessories:

  • HP part number 0955-0306 50 MHz Low Pass Filter (2 needed)
  • HP part number 8120-4921 APC 3.5 Low-Loss Microwave Test
  • Omni-Spectra 2090-6202-00 Reactive Power Divider
  • HP 8493B, Option 020 20 dB Attenuator (2 required)
  • HP 8493B, Option 003 3 dB Attenuator
  • K&L 5L380-250-B/B Low Pass Filter (250 MHz)
  • K&L 6L250-8000-NP/N Low Pass Filter (8 GHz)
  • HP 360B Low Pass Filter (1200 MHz)

Software Automated Performance Testing
These testing procedures are applicable to the following models: 8566, 8567 and 8588.

  • Input Attenuator Switching Check

This is included as an aid to verify operation only and to assist in
troubleshooting. A signal source of known amplitude is connected to the
spectrum analyzer and the analyzer is adjusted for a reference. The input
attenuator is stepped down from 10 dB to 70 dB, while the reference
level and the signal source are stepped up. This maintains the signal
peak at the same approximate location on the display. The amplitude
of the signal is measured at each step using the marker function on
the spectrum analyzer.
Equipment needed:
– HP 3335A Frequency Synthesizer

  • IF Gain Uncertainty

A signal source of known amplitude is connected to the spectrum
analyzer and the analyzer is adjusted for a reference level. The
amplitude of the signal peak is measured in 0.1 dB steps from -0.1 dB
to -1.9 dB, in 2 dB steps from -1.9 dB to -9.9 dB, and in 10 steps
from -10 dB to -120 dB.
Equipment needed:
– HP 3335A Frequency Synthesizer

  • Scale Fidelity (Log)

The specification listed is for cumulative error. Only cumulative error
is measured in this procedure.
A signal source of known amplitude is connected to the spectrum
analyzer and the analyzer is adjusted for a reference. The signal
source is stepped down in 1 dB steps and the displayed signal
amplitude on the spectrum analyzer is measured at each step. This
measurement is performed in both the 3 kHz and 300 kHz bandwidths.
Equipment needed:
– HP 3335A Frequency Synthesizer

  • Scale Fidelity (Linear)

A signal source of known amplitude is connected to the spectrum
analyzer and the analyzer is adjusted for a reference. The signal
source is stepped down from -10 dB to -30 dB in 10 dB steps, and
the amplitude of the displayed signal is measured using the marker
function. This measured value is used to calculate the percent error
from the established reference level.
Equipment needed:
– HP 3335A Frequency Synthesizer

  • Log Scale Switching Uncertainty

A signal source of known amplitude is connected to the spectrum
analyzer and the analyzer is adjusted for a reference in the 1 dB per
division log scale. The spectrum analyzer is then switched to each of
the other LOG scales (2 dB, 5 dB, and 10 dB) and the LINEAR scale.
The amplitude of the signal peak is measured at each setting.
Equipment needed:
– HP 3335A Frequency Synthesizer

  • Resolution Bandwidths (for instruments without Option 462)

A signal source is connected to the spectrum analyzer input. The
analyzer steps through the bandwidths from 3 MHz to 10 Hz, centers
the signal, sets signal peak near the reference level, and measures
the frequency of the 3 dB points for each bandwidth. The 3 dB
bandwidth is then calculated by determining the difference in
frequency between the 3 dB points.
Next the spectrum analyzer steps through the bandwidths and
measures the frequency of the 60 dB points of each bandwidth. The
60 dB bandwidth is then calculated by determining the frequency
difference between the 60 dB points.
The shape factors are calculated by dividing the 60 dB bandwidths by
the 3 dB bandwidths.

  • Impulse and Resolution Bandwidths (Option 462 Impulse Bandwidth)

A source outputting pulsed RF signals is connected to the spectrum
analyzer input. The analyzer steps through the bandwidths from
3 MHz to 1 kHz, and the controller measures the frequency of the
impulse response for each bandwidth. Next, a CW signal is connected
to the spectrum analyzer input. The analyzer steps through all
bandwidths from 3 MHz to 10 Hz, centers the signal, sets the signal
peak near the reference level, and measures the frequency of the 6
dB points for each bandwidth. The 6 dB bandwidth is then calculated
by determining the difference in frequency between the 6 dB points.
Last, the analyzer steps through the bandwidths and measures the
60 dB points for each bandwidth. The 60 dB bandwidth is calculated
for each bandwidth. The selectivity of each bandwidth is then
calculated by dividing the 60 dB bandwidth by the 6 dB bandwidth
for each filter.
Equipment needed:
– HP 3335A Frequency Synthesizer
– HP 8112A or HP 8116A Pulse Generator

  • Line-Related Sidebands

A signal source is connected to the spectrum analyzer input and the
necessary front-panel control settings made for the test. The test
calculates line frequency harmonics, sets the front-panel controls in
order to view the frequencies, and measures the amplitude of the
signal at each of the frequencies.

  • Average Noise Level

The RF INPUT of the spectrum analyzer is terminated with a 50 ohm
load or the synthesizer. The necessary front-panel control settings are
made and the average noise level measured at four non-preselected
and four preselected frequencies.
Equipment needed:
– HP 909A Option 012 50 Ohm Termination

  • Residual Responses

The RF INPUT of the spectrum analyzer is terminated with a 50 ohm
load or the synthesizer. The peak amplitude of the noise or responses
is measured at various frequencies associated with residual responses
caused by harmonics and mixing products of the first, second, and
third local oscillator; the internal reference; and the HP-IB and digital
storage clocks.
Equipment needed:
– HP 909A Option 012 50 Ohm Termination

  • Sweep + Tune Out Accuracy

A digital voltmeter is used to monitor the rear-panel SWEEP + TUNE
OUT voltage while the spectrum analyzer center frequency is set to
nine arbitrary values. The output voltage for each center frequency
setting is checked against the specification.
Equipment needed:
– HP 3455A or HP 3456A System DVM

  • Second Harmonic Distortion

A 40 MHz signal is applied to the analyzer RF INPUT through a 50
MHz low pass filter. The spectrum analyzer is adjusted to measure the
second harmonic at 80 MHz.
Equipment needed:
– HP 3335A Frequency Synthesizer
– HP part number 0955-0306 50 MHz Low Pass Filter (2 needed)

  • Frequency Span Accuracy

A stable signal source is connected to the spectrum analyzer. The
center frequency and span are set to measure spans from 100 kHz to
10 GHz in a 1, 2, 5 sequence.
Equipment needed:
– HP part number 8120-4921 APC 3.5 Low-Loss Microwave Test Cable
– HP 83640A Synthesized Sweeper

  • Gain Compression

Gain compression is measured by changing the power level at the
input mixer from -15 dBm to -5 dBm and measuring the change in
display level using the spectrum analyzer marker function. This is
done at two frequencies: 100 MHz and 2.2 GHz to check both the first
mixer and YIG-tuned mixer, respectively.
Equipment needed:
– HP part number 8120-4921 APC 3.5 Low-Loss Microwave Test Cable
– HP 83640A Synthesized Sweeper
– HP 8485A or HP 8481A Power Sensor
– HP 8902A Measuring Receiver or HP 436A or HP 438A Power Meter
– HP 11667B or HP 11667A Power Splitter

  • Frequency Response

If this test is individually selected, a menu of the testable bands is
displayed. For all bands, the test consists of 100 data points taken
across the selected band. For the 200 Hz to 22 GHz test, six bands are
tested (600 data points). First the sweeper is used to test from 20 MHz
to 22 GHz, and then the synthesizer is used to test from 200 Hz to 20
MHz. The levels at 20 MHz are matched to guarantee continuity. If
the Frequency Response test is entered from the ALL TESTS Mode,
then the 200 Hz to 22 GHz is selected automatically.
– HP 11667B or HP 11667A Power Splitter
– HP 3335A Frequency Synthesizer
– HP 83640A Synthesized Sweeper
– HP 8902A Measuring Receiver or HP 436A or HP 438A Power Meter
– HP 8485A or HP 8481A Power Sensor
– HP part number 8120-4921 APC 3.5 Low-Loss Microwave Test Cable

  • Third Order Intermodulation

Two signals with 1 MHz separation are applied to the first mixer. The
frequencies of third order intermodulation products are calculated
and the spectrum analyzer is set to measure the amplitude of
these responses. The third order intercept is calculated from the
Measurements.
Equipment needed:
– HP 83640A Synthesized Sweeper
– HP 3335A Frequency Synthesizer
– HP 8721A Coaxial Directional Bridge
– HP part number 0955-0306 50 MHz Low Pass Filter (2 needed)
– HP part number 8120-4921 APC 3.5 Low-Loss Microwave Test Cable

  • Cal Output Amplitude Accuracy

The power sensor is connected to the spectrum analyzer CAL
OUTPUT and the power is measured.
Equipment needed:
– HP 8902A Measuring Receiver or HP 436A or HP 438A Power Meter
– HP 8485A or HP 8481A Power Sensor

  • First LO Output Power

The power sensor is connected to the spectrum analyzer 1ST LO
OUTPUT and the output power is measured as the LO is stepped from
2.3 GHz to 6.2 GHz in 100 MHz steps.
Equipment needed:
– HP 8902A Measuring Receiver or HP 436A or HP 438A Power Meter
– HP 8485A or HP 8481A Power Sensor

Additional Manual Performance Testing

  • Center Frequency Readout Accuracy Test

A synthesized signal source that is phase-locked to a known frequency
standard is used to input a signal to the analyzer. The frequency
readout of the analyzer is compared to the actual input frequency
for several different frequency settings over the analyzer?s range.
The signal source is phase-locked to a standard known to be as
accurate as the analyzer?s internal frequency reference to minimize
the ?frequency reference error X center frequency? term of the
Specifications.
Equipment needed:
– HP 83640A Synthesized Sweeper
– HP 5061A Frequency Standard

  • Sweep Time Accuracy Test

A universal counter is connected to the PENLIFT RECORDER
OUTPUT (on the rear panel) of the 8566B. The counter is used in
time interval mode to determine the “pen down” interval of the
PENLIFT RECORDER OUTPUT. The penlift output voltage level
corresponds directly to the sweeping of the analyzer (pen down = 0V)
and not-sweeping of the analyzer (pen up = 15V). A DVM is used to
set the appropriate trigger level of the counter.
Equipment needed:
– HP 5316A Universal Counter
– HP 3456A Voltmeter

(This test is for sweep times ?20 ms. For faster sweep times, refer to Fast Sweep Time Accuracy Test.)

  • Noise Sidebands Test

A 5.7 GHz signal with low phase noise is input to the spectrum
analyzer. The signal and noise sidebands are displayed on the analyzer
and the trace is video-averaged. The displayed noise sideband level
at various frequency offsets is measured and the measured values are
corrected for log amplification and detection errors, then normalized
to a 1 Hz bandwidth. A second HP 8566A/B Spectrum Analyzer is
used as the signal source for this test. Therefore, if the measured
values are not within specification limits, either analyzer may be at
Fault.
Equipment needed:
– HP 8566A/B Spectrum Analyzer

  • Harmonic and Intermodulation Distortion Test

Second harmonic distortion in the non-preselected and preselected
bands is checked with a signal source and low-pass filter. The
low-pass filter ensures that the harmonics measured are due to the
analyzer and not the source. Third-order intermodulation distortion
is measured in the non-preselected and preselected bands with two
signal sources. To prevent source interaction, the synthesizer outputs
are padded and combined in a reactive power divider.
Equipment needed:
– HP 8902A Measuring Receiver or HP 436A or HP 438A Power Meter
– HP 8485A or HP 8481A Power Sensor
– HP 8340A Synthesized Sweeper
– HP 8672A Synthesized Signal Generator
– Omni-Spectra 2090-6202-00 Reactive Power Divider
– HP 8493B, Option 020 20 dB Attenuator (2 required)
– HP 8493B, Option 003 3 dB Attenuator
– K&L 5L380-250-B/B Low Pass Filter (250 MHz)
– K&L 6L250-8000-NP/N Low Pass Filter (8 GHz)
– HP 360B Low Pass Filter (1200 Mhz)

  • Image, Multiple, and Out-of-Band Responses Test

Image and out-of-band responses are checked by setting the analyzer
center frequency to several frequencies across the analyzer range and
tuning a leveled signal source to the frequencies determined by the
tuning equation, Fsig = nFLo ? FIF. Input signals at these frequencies
will excite all possible image and out-of-band responses for a given
1st LO frequency and all positive integer values of n. In this test,
only values of n corresponding to the analyzer mixing modes are
used. Multiple responses are checked by applying an input signal
and measuring the response at those center frequencies for which a
harmonic of the 1st LO mixes with the input signal.
Equipment needed:
– HP 8340A Synthesized Sweeper

  • Fast Sweep Time Accuracy Test (~20 ms)

The triangular wave output of a function generator is used to
modulate a 500 MHz signal which is applied to the spectrum analyzer
RF INPUT. The signal is demodulated in the zero span mode to display
the triangular waveform. Sweep time accuracy for sweep times
~20 ms is tested by checking the spacing of the signal peaks on the
displayed waveform.
Equipment needed:
– HP 8340A Synthesized Sweeper
– HP 5316A Universal Counter
– HP 3312A Function Generator

  • Frequency Reference Error Test

The frequency of the spectrum analyzer time base oscillator is
measured directly using a frequency counter locked to a frequency
reference which has an aging rate less than one-tenth that of the
time base specification. After a 30-day warm-up period, a frequency
measurement is made. The analyzer is left undisturbed for a 24-hour
period and a second reading is taken. The frequency change over this
24-hour period must be less than one part in log.
Equipment needed:
– HP 5061A Frequency Standard
-HP 5345A Electronic Counter