Agilent 8566B Data Sheet

Agilent 8566B Spectrum Analyzer 100 Hz to 22 Ghz
Technical Overview
Outstanding Precision and Capability
2
Designed for bench and system use, the 8566B offers superior measurement speed, microwave frequency accuracy, and sensitivity. Measure low-level signals up to 22 GHz with narrow resolution bandwidths. Synthesizer stability virtually elimi­nates long-term drift and residual FM.
Frequency range is 100 Hz to 22 GHz with a dc-coupled input. Preselected external mixers extend this coverage from 26.5 to 75 GHz. Other external mixers allow measurement to 325 GHz.
An internal bus and microcomputer control make possible many powerful operating and data processing features, as well as flexibility under computer control. Sixteen Kbytes of user RAM are available for storing trace data, instrument states, and custom down­loadable programs (DLPs). All displayed information can be sent directly to a plotter when sweeptime is greater than or equal to 20 ms.
Accurate measurements
Amplitude measurement range extends from +30 to -135 dBm with a 90 dB calibrated display.
Less than 1 x 10
-9
/day frequency reference error and the spectrum analyzer selectivity allow high frequency accuracy even when you are measuring small signals in the presence of large ones.
Turbo speed option
Already a world leader in measurement speed, the 8566B can be made even faster with Option 002, which nearly doubles the internal processing speed of the analyzer. Some measurements can be made up to 50% faster, and overall throughput is typically improved by 5 to 25%. (Sweep speed is not affected by Option 002.)
The turbo option is compatible with all 8566B accessories, and it can be added to any 8566B without affecting specifications. (An 8566A must first be upgraded to a 8566B.)
Accessories and options
By adding measurement accessories and options, the 8566B spectrum analyzer fits into many applications, including electromagnetic compatibility (EMC) testing, broadband signal surveillance, and component stimulus response testing.
• EMI measurement accessories and software create systems for testing to commercial and military standards.
• Microwave tracking sources add scalar measurement capability.
• Preselected external mixers simplify millimeter-wave measurements from 26.5 to 75 GHz.
• Interactive test generator (ITG) soft-front-panel-based drivers speed software development.
• MIL-STD 45662A calibrations are available.
Custom Soft key programming
You can create complex measurement routines on an external controller, store the programs in user RAM, and execute them using a single custom soft key.
Simple measurement routines can be entered from the intrument front panel, stored in user RAM, and executed using a single custom soft key.
Turbo speed improvements
Operation Standard 8566B Turbo 8566B Speed improvement
Trace dump 1083 ms 532 ms 51% MKR AMPL 8.4 ms 3.7 ms 56% Harmonics test 1007 ms 782 ms 22% FFT 473 ms 243 ms 49%
The Agilent 8566B Spectrum Analyzer…
…the Spectrum Analyzer that keeps getting better
3
Test systems tailored to your needs
For EMI troubleshooting and pre-qualification testing, use your 8566B spectrum analyzer with components and accessories from Agilent Technology’s complete line of EMI products. The many offerings include current probes, line impedance stabilization networks (LISNs), antennas, positioning equipment, EMI measurement software, an RF preselector, and a quasi-peak adapter.
Commercial and MIL EMI receivers
The 8566B spectrum analyzer forms the heart of two powerful and flexible EM1 receivers. These receivers are ideal for commercial and military EMI compliance testing from 20 Hz to 40 GHz.
The 8571A receiver is optimized for military EMI testing, making both peak and average detection measurements using impulse bandwidths. The 8572A includes all the features and capabilities of the 8571A, but adds quasi-peak detection and specialized IF bandwidths for commercial compliance measurements.
Both receivers offer ±2 dB absolute amplitude accuracy over their full 20 Hz to 22 GHz frequency range, as required by MIL-STD 461 and CISPR Publication 16. For higher frequency measurements, a 22 to 40 GHz block downconverter can be added. The receivers include a built-in, 1 to 26.5 GHz amplifier and a 20 Hz to 50 MHz input port with a built-in limiter and rugged attenuator. They are also compatible with EMI measurement software and complete line of test accessories.
EMC Measurement Solutions
4
Easy-to-read, annotated
display shows instrument
settings and multiple traces
Coupled functions
SAVE and RECALL
store instrument settings
One keystroke sends all CRT information directly to a plotter
1
Measurement aids include four tunable markers for direct and relative signal measurements
Smart enough to make its own decisions…
1. Instrument sweeptimes greater than or equal to 20 ms.
5
The 8566B offers
• Exceptional microwave performance
• Decision-making capability
• Enhanced processing speed
• Preselected millimeter coverage
• Advanced functions
• Downloadable programming capability
• Distributed processing with a computer
• Proven reliability, performance, and support
Dedicated keys make basic operations easy
Interactive function and data controls simplify operation
Powerful signal and trace-processing functions perform complex data analysis
…with precision and speed
6
Millimeter mixers
Preselected mixers
The 11974 Series preselected mixers eliminate the need for time-consuming signal identification routines at millimeter frequencies. With preselection, no images or multiples are generated to confuse measurements. These external mixers allow you to quickly locate true signals, and they simplify software development for automated measurements. The 11974 Series mixers are available in four bands covering 26.5 to 75 GHz.
Harmonic mixers
The 11970 Series waveguide mixers are general-purpose external harmonic mixers. They offer flat frequency response and low conversion loss without requiring external dc bias or tuning adjustment. The 11970 Series mixers are offered in six bands covering 18 to 110 GHz.
Accessories That Enhance Performance
Harmonic mixing extends frequency range.
Preselected mixers eliminate images and multiples.
7
Add high dynamic range scalar measurement capability to the 8566B. The 85644A and 85645A portable tracking sources allow you to use your spectrum analyzer for measuring transmission and reflection characteristics of devices. You can also characterize harmonic distortion, intermodulation distortion, spurious products, and more.
The tracking sources give the 8566B dynamic range greater than 125 dB up to 12.5 GHz and greater than 105 dB through 22 GHz.
Other features include:
• Swept offset tracking for mixer testing and swept TOI measurements
• Up to +10 dBm leveled output power
• Standalone CW source capability
Tracking Sources
High dynamic range scalar measurement
8
Boost the sensitivity of the 8566B spectrum analyzer with the 8449B microwave preamplifier. This low noise, high gain preamplifier has a frequency range of 1 to 26.5 GHz. Sensitivity improvements of up to 25 dB allow you to detect and analyze very low level signals in dramatically reduced time, using wider handwidths. Low return loss on the input and output ports of the preamplifier minimizes mismatch uncertainty.
Displayed average noise level
0 dB attenuation, 10 Hz RBW (characteristic)
1.0 to 2.5 GHz -155 dBm
2.0 to 5.8 GHz -154 dBm
5.8 to 12.5 GHz -150 dBm
12.5 to 18.6 GH -144 dBm
18.6 to 22 GHz -140 dBm
The 8566B spectrum analyzer works with computers that support BASIC.
Microwave preamplifier
Computers and plotters
Specifications
Specifications describe the instrument's warranted performance over the 0 ° to 55 °C temperature range (unless otherwise noted), with autocoupled function operation and preselector tracking optimized.
Characteristics provide information about non-warranted instrument performance.
Frequency
Measurement range 100 Hz to 22 GHz, dc-coupled input; up to 325 GHz with external mixers Frequency reference error
Aging rate < 1 x 10
-9
/day and < 2.5 x 10-7/year
Temperature stability < 7 x 10
9
over 0 ° to 55 °C range
Center frequency 0 Hz to 22 GHz Center frequency readout accuracy
Spans n x 5 MHz ± (2% of frequency span + frequency reference error x
center frequency +10 Hz)
Spans > n x 5 MHz ± (2% of frequency span + n x 100 kHz + frequency
reference error x center frequency) where n is the harmonic mixing number, depending on center frequency:
n center frequency
1 100 Hz to 5.8 GHz 2 5.8 to 12.5 GHz 3 12.5 to 18.6 GHz
4 > 18.6 GHz (After adjusting freq zero, add 30% of RES BW setting if error correction is not used.) Zero span ± (frequency reference error x center frequency)
9
Frequency span
0 Hz, 100 Hz to 22 GHz over 10 division CRT horizontal axis; variable in approximately 1% increments. Two FULL SPAN keys select spans from 0 to 2.5 GHz and from 2 to 22 GHz.
Frequency span readout accuracy
Spans n x 5 MHz ± 1 % of indicated frequency separation Spans > n x 5 MHz ± 3% of indicated frequency separation Start or Stop Frequency Same as center frequency
Resolution
Resolution bandwidth 3 dB bandwidths of 10 Hz to 3 MHz in a 1. 3, 10 sequence.
Bandwidth may be selected manually or coupled to frequency span (AUTO mode).
3 dB bandwidth accuracy
3 MHz ±20% 3 kHz to 1 MHz ±10% 10 Hz to 1 kHz ±20% (30 kHz and 100 kHz bandwidth accuracy figures apply only with 90% relative humidity, 40 °C.)
60 dB/3 dB bandwidth selectivity ratio
100 kHz to 3 MHz < 15:1 3 kHz to 30 kHz < 13:1 30 Hz to 1 kHz < 12:1 (60 dB points on 10 Hz bandwidth are separated by < 100 Hz.)
Bandwidth shape
Synchronously tuned, approximately Gaussian
Stability
Residual FM (typical) For fundamental mixing (n = 1) < 50 kHz peak-to-peak,
freq. span > 5 MHz. Drift Because analyzer is phase-locked at beginning of each sweep, drift occurs only during time of one sweep.
Frequency span Center frequency drift
1
< 100 kHz < Iø Hz/min of sweeptime 100 kHz to 5 MHz < 500 Hz/min of sweeptime 5 MHz < 5 KHz/min of sweeptime
Spectral purity
Noise sidebands (for frequency span < 25 kHz – except 100 kHz offset – and center
frequency from 100 Hz to 5.8 GHz)
Offset from carrier sideband level
320 Hz -80 dBc/Hz 1 kHz -85 dBc/Hz 10 kHz -90 dBc/Hz 100 kHz -105 dBc/Hz
Specifications (continued)
Figure 1. Typical spectrum analyzer resolution
1. Typical, after 1 hr warmup at stabilized temp COUPLED FUNCTION not required.
10
Typical noise sideband performance
Power-line-related sidebands
(for line conditions specfied in Power Requirements section)
SIDEBANDS
Center frequency Offset from 100 MHz > 100 MHz 6.8 to 12.6 to 18.6 to carrier to 5.8 Ghz 12.6 GHz 18.6 Ghz 22 GHz < 360 Hz -70 dBc -60 dBc -64 dBc -60 dBc
1
-58 dBc
1
360 kHz to 2 kHz -75 dBc -75 dBc
1
-69 dBc -65 dBc
1
-63 dBc
1
>2 kHz -80 dBc -80 dBc
1
-74 dBc
1
-70 dBc
1
-63 dBc
1
Amplitude
Measurement range
Measurement range is the total amplitude range over which the analyzer can measure signal responses. The low value is determined by sensitivity (10 Hz RBW and 0 dB RF input attenuation) and the high value by damage level.
Tuned frequency Range
Non-preselected 100 Hz to 50 kHz -95 to +30 dBm 50 kHz to 1 MHz -112 to +30 dBm 1 MHz to 2.5 GHz -134 to +30 dBm
Preselected
2.0 to 5.8 GHz -132 to +30 dBm 5 8 to 12 5 GHz -125 to +30 dBm 12 5 to 18 6 GHz -119 to +30 dBm
18.6 to 22 GHz -114 to +30 dBrn
Displayed values
Scale (over a 10 division CRT vertical axis with 0 dB reference level at top graticule line)
Calibration
Log 10 dB/div for 90 dB display from reference level.
Expanded from reference level: 5 dB/div for 50 dB display 2 dB/div for 20 dB display 1 dB/div for 10 dB display
Linear 10% of ref level/div when calibrated voltage
1. Typical
Figure 2. Single sideband noise normalized to1 Hz BW vs offset from carrier
Figure 3. Typical analyzer and SSB noise at 5.0 GHz center frequency. May be limited by average noise level.
Specifications (continued)
11
Reference level
Range
Log +30.0 to -99.9 dBm or equivalent in dBmV, dBµV, volts. Readout expandable
to +60.0 dBm to -119.9 dBm (-139.9 dBrn for < 1 kHz RBW)
1
Linear 7.07 V to 2.2 µV full scale. Readout expandable to 223.6 V to 2.2 µV
(0.22 µV for < 1 kHz RBW)
1
Accuracy
The sum of the following factors determines the accuracy of the reference level readout. Measurement technique used after calibration with CAL signal determines applicability of uncertainty sources. Specifications given with preselector tracking optimized using MARKER PRESELECTOR PEAK.
With corrected readout (SHIFT W and SHIFT X executed just prior to measurement), 20 ° to 30 °C temperature range, and minimum one hour warmup time.
Calibrator uncertainty ±0.3 dB Frequency response (flatness) uncertainty
(10 dB attenuation)
100 Hz to 2.5 GHz ±0.6 dB
2.0 to 12.5 GHz ±1.7 dB
12.5 to 20 GHz ±2.2 dB 20 to 22.0 GHz ±3.0 dB
Cumulative, 100 Hz to 20 GHz ±2.2 dB
Absolute amplitude calibration uncertainty
The uncertainty of setting the frequency response curve absolutely when using the internal CAL signal or other calibration signal in the 100 Hz to 2.5 GHz band (10 dB input attenuation).
±0.6 dB
Resolution bandwidth switching uncertainty
Referenced to 1 MHz RES BW
10 Hz ±1.1 dB 30 Hz ±0.4 dB 100 Hz to 1 MHz ±0.2 dB 3 MHz ±0.2 dB
Log scale switching uncertainty ±0.1 dB
Log fidelity Incremental ±0.1 dB/dB over 0 to 80 dB display Cumulative
10 Hz RBW ±2.1 dB over 0 to 90 dB30 Hz RBW ±1.5 dB over 0 to 90 dB
±1.0 dB over 0 to 80 dB
Linear fidelity < ±3% of reference level over top 9-1/2 divisions of
the display
IF gain uncertainty Reference to -10 dBm; reference level with 10 dB input attenuation.
Reference level
RBW 3 kHz 0 to -59.9 dBm ±0.3 dB
-60 to-100 dBm ±1.O dB
RBW 100 Hz-l kHz 0 to -79.9 dBm ±0.3 dB
-80 to -100 dBm ±1.0 dB
RBW 30 Hz 0 to -79.9 dBm ±0.3 dB
-80 to -100 dBm ≤ ±2.0dB
RBW 10 Hz 0 to -79.9 dBm ±1 .0 dB
-80 to -100 dBm ≤ ±2.0dB
1. Maximum total input power not to exceed +30 dBm damage level
Specifications (continued)
12
Log digitization uncertainty
10 dB/div ±0.2dB 5 dB/div ±O.I dB 2 dB/div ± 0.04 dB 1 dB/div ± 0.02 dB
Linear digitization uncertainty ± 0.2% of ref level
Error correction accuracy ± 0.4 dB (applicable when SHIFT W and SHIFT X are executed)
Reference line accuracy Equals the sum of reference level accuracy plus the scale fidelity between the reference level and the reference line level.
Dynamic range
Spurious responses (signals generated by the analyzer due to input signals) for signals
< -40 dBm at the input mixer, all harmonic and intermodulation distortion > 70 dB below input signal. Second harmonic distortion (for mixer levels < -40 dBm)
100 Hz to 50 MHz < -70 dBc 50 to 700 MHz < -80 dBc 700 MHz to 2.5 GHz < -70 dBc
For mixer levels -10 dBm
2 to 22 GHz <-100 dBc
Third order intermodulation distortion
Third order intercept (TOI)
100 Hz to 5 MHz > +5 dBm 5 MHz to 5.8 GHz > +7 dBm
5.8 GHz to 18.6 GHz > +5 dBm
18.6 to 22 GHz > +5 dBm (typical) 2 to 22 GHz, for > 100 MHz > +50 dBm (typical) signal separation
Image, multiple, and out-of-band responses
Image responses are due to input signals that are two times the IF frequency above or below the tuned frequency. Multiple responses are due to input signals mixing with more than one LO harmonic. Out-of-band responses are due to input signals outside of the selected frequency band.
Figure 4. Typical optimum dynamic range
Specifications (continued)
13
Applied frequency Tuned frequency
(GHz) 0 to 2.5 2.0 to 5.8 5.8 to 12.5 12.5 to 18.6 18.6 to 22.0 0 to 2.5 NA -60 dBc 60 dBc -60 d8c -60 dBc
2.0 to 5.8 -60 dBc -70 dBc -60 dBc -60 dBc -60 dBc
5.8 to 1 2.5 -50 dBc -60 dBc -70 dBc -60 dBc -60 dBc
12.5 to 18.6 - 4 5 dBc -60dBc -60 dBc -70 dBc -60 dBc
18.6 to 22.0 -40 dBc -60 dBc -60 dBc -60dBc -70 dBc
1
Residual responses (signals displayed by the analyzer independent of input signals), 0 dB
input attenuation, no input signal.
100 Hz to 5.8 GHz < -100 dBm
2
5.8 to 12.5 GHz < -95 dBm
12.5 to 18.6 GHz < -85 dBm
18.6 to 22 GHz < -80 dBm
Gain compression < 1 .0 dB, 100 Hz to 22 GHz. with < -5 dBm at input mixer Displayed average noise level (sensitivity)
0 dB input attenuation, 10 Hz RBW
100 Hz to 50 kHz < -95 dBm 50 kHz to 1 .0 MHz < -112 dBm 1 .0 MHz to 2.5 GHz < -134 dBm
2.0 to 5.8 GHz < -132 dBm
5.8 to 12.5 GHz < -125 dBm
12.5 to 18.6 GHz < -119 dBm
18.6 to 22 GHz < -114 dBm
Marker (frequency and amplitude are read out continuously)
Marker type Frequency accuracy
Normal Same as center frequency accuracy Delta Same as frequency span accuracy
Amplitude accuracy
Normal Same as reference level accuracy + scale fidelity between the
reference level and marker position
Delta Same as frequency response uncertainty and scale fidelity
between two markers
Sweep time accuracy (1 µs to 1500s full sweep)
< 200 second sweep time ± 10% > 200 second sweep time ± 30%
1. lmage responses: - 6 0 dBc, 18.6 – 20.0 GHz; – 50 dBc, 20.0 – 22 GHz
2. Limited by the appropriate DANL or -100 dBm, whichever is greater.
Figure 6. Specified average displayed noise level, 2.0 to 22 GHz, preselected tuning range.
Figure 5. Specified average displayed noise level, 100 Hz to 2.5 GHz, non-preselected tuning range.
Specifications (continued)
14
Inputs
RF input 100 Hz to 22 GHz, precision type-N female connector, dc-coupled Maximum input level
ac Continuous power: +30 dBm from 50 ohm source
Mixer protected by diode limiter, 100 Hz-2.5 GHz Pulse power: 100 W, 10 µs pulse width with 50 dB input attenuation
(0 dBm peak power to input mixer)
dc < 100 mA damage level
Input attenuator 0 to 70 dB in 10 dB steps
SWR (typical) Tune frequency Input attenuation 10O Hz to 2.5 GHz 2.5 GHz to 5.8 GHz 5.8 GHz to 22 GHz
10 dB 1.2 1.5 1.9 0 dB
1
2.3 3.0 3.0
Outputs
Calibrator (front panel)
100 MHz ± (frequency reference error x 100 MHz)
-10 dBm ± 0.3 dB; 50 ohm impedance, nominal
1st LO (front panel)
2.3 to 6.1 GHz; > +5 dBm; 50 ohm impedance, nominal
Sweep and tune output (rear panel)
-1 V/GHz of tuned frequency ± (2% + 10 mV) 10 kohm impedance, nominal
Display outputs (typical parameters)
X, Y, and Z outputs for auxiliary CRT displays. X, Y 1V for full deflection Z 0 to 1 V intensity modulation, -1 V blank BLANK TTL level > 2.4 V for blanking Compatible with most oscilloscopes.
Recorder outputs (typical parameters) Outputs to drive all current X-Y recorders using positive pencoils or TTL pen uplift.
Horizontal sweep output (X-axis) A voltage proportional to the horizontal sweep of the frequency sweep generator. 0 V
for left edge, +10 V for right edge; 1.7 kohm impedance, nominal. Video output (Y-axis) Detected video output (before A-D conversion) proportional to vertical deflection of the
CRT trace 100 mV/div from 0 to 1 V; < 475 ohm impedance, nominal Penlift output (Z-axis) During sweep, pen down 0 V from 10 ohm source
During retrace, pen up +15 V from 10 kohm source
21.4 MHz output (rear panel, typical)
21.4 MHz; 50 ohm impedance, nominal: -20 dBm for a signal at reference level. In log scales, the IF output logarithmically related to RF input signal; in linear, the output is linearly related.
Frequency reference (rear panel, typical)
10.000 MHz, 0 dBm; 50 ohm output impedance 10 MHz output (rear panel, typical) 5 dBm to ohm output impedance
Video output 0 to 2 V, > 10 ohm output impedance
Display
Cathode ray tube Post deflection accelerator, aluminized P31 phosphor, electrostatic
focus and deflection. Viewing area Approximately 9.6 cm vertically by 11.9 cm horizontally (3.8 in x 4.7 in)
1. When tuned to within ±3 MHz of signal
Specifications (continued)
15
Dimensions
Remote operation
The standard 8566B operates on the interface bus (GP-IB). All analyzer control settings (with the exception of VIDEO TRIGGER LEVEL, FOCUS, ALIGN, INTENSITY, FREQ ZERO, AMPTD CAL, and LINE power) are remotely programmable. Function values, marker frequency/amplitude.and A/B traces may be output; CRT labels and graphics may be input.
LCL Returns analyzer to local control, if not locked out by controller. Service request
SHIFT r calls an GP-IB request for service.
GP-IB interface functions
SH1, AH1, T6, L4. SRI, RL1, PPO, DC1, Cl, C2, C3, C28, E2
Options
All specifications for options are identical to standard 85668 except as noted.
400 Hz Power line frequency operation (Option 400)
Power line related sidebands (center frequency from 100 Hz to 5.8 GHz)
Offset from Carrier Sideband Level < 2 kHz -55 dBc 2 kHz to 5.5 kHz -65 dBc
Power requirements
Line frequency 400 Hz ±10% line frequency (50 to 60 Hz operation for servicing only) Line voltage 100 to 120 v (+5%, -10%)
Operating temperature range
400 Hz 0 ° to 55 °C 50 Hz to 60 Hz 0 ° to 40 °C (service only, not for extended periods)
General Specifications
Figure 7. Instrument dimensions with and without handles
Environmental
Temperature
Operation 0 ° to 55 °C Storage -40 ° to 75 °c
Increased internal temperatures may result if the rear panel air filters are not cleaned regularly.
Altitude
Operation 3 4,572 m (15,000 ft) Storage 15,240 m (50,000 ft)
Power requirements 50 to 60 Hz; 100,200,
120,220, or 240 V (+5%, -10%); approximately 650 VA (40 VA in standby). 400 Hz operation with Option 400.
Humidity
Operation Type tested to 95% relative
humidity, 25 ° to 40 °C, except as noted in electrical specifications.
Storage 5% to 90% relative humidity,
0 ° to 40 °C
EMI Conducted and radiated
interference is within the requirements of MIL-STD-461C, Part 7 RE02 and CE03 (Air Force), and CISPR Publication 11; VDE 0871 and FTZ 526/527/79.
Warm-up time
Operation Requires 30 minute warm-up
from cold start, 0 ° to 55 °C. Internal temperature equilibrium is reached after 2-hour warm-up at stable outside temperature.
Frequency reference (typical)
Frequency reference aging rate attained after 24 hour warm-up from cold start at 25 °C. Frequency is within 1 x 10'8 of final stabilized frequency within 30 minutes.
Weight
Total, net 50 kg (112 Ib) RF section, net 29 kg (65 Ib) IF display 21 kg (47 Ib)
section, net RF section, 35 kg (78 Ib)
shipping
IF display 27 kg (60 Ib) section, shipping
*626.4 mm (24.7 in)
598.5 mm (23.56 in)
558.8 mm (22 in)
425.5 mm (16.75 in)
457.2 mm (18 in)
279.2 mm
(11 in)
TOP
SIDEBACK
(Allow 100 mm, 4 inch clearance at rear panel for interconnect cables. Dimensions marked with * denote with handels)
8566B spectrum analyzer – lOO Hz to 22 GHz Option R02 Turbo retrofit kit for any 8566B Option 002 Turbo option for faster measurements Option 010 Rack mount slide kit Option 016 Installed EMI receiver functions Option 031 German operating manual Option 080 Information card in Japanese Option 081 Information card in French Option 1BN MIL-STD 45662A calibration certification Option 1BP MIL -STD 45662A calibration certification with test data Option 400 400 Hz operation Option 462 100 Hz, 1 kHz, and 1 MHz
Impulse bandwidth filters for EMI measurements
Option 908 Rack flange kit without handles Option 910 Extra operating and test and adjustment manuals Option 913 Rack flange kit with handles Option 915 Troubleshooting and repair manual set Option W30 3-year customer return repair Option W32 3-year customer return calibration
8566AB Retrofit kit to convert 8566A to 8566B
Recommended accessories 85644A Tracking source 300 kHz to 6.5 GHz 85645A Tracking source 300 kHz to 26.5 GHz 8449B Preamplifier 1 to 26.5 GHz 11975A Amplifier 2 to 8 GHz
Preselected mixers 11974A 26.5 to 40 GHz preselected mixer 11974Q 33 to 50 GHz preselected mixer 11974U 40 to 60 GHz preselected mixer 11974V 50 to 75 GHz preselected mixer 11974 Option 003 Delete power supply
Harmonic mixers 11970K 18 to 26.5 GHz mixer 11970A 26.5 to 40 GHz mixer 11970Q 33 to 50 GHz mixer 11970T 18 to 40 GHz mixers, hardwood case, cables, tools Option 001 Add 40 to 60 GHz mixer Option 002 Add 33 to 50 GHz mixers 11970U 40 to 60 GHZ mixer 11970V 50 to 75 GHz mixer 11970W 75 to 110 GHz mixer
Option 009 Mixer connection set adds three 1-meter low-loss
SMA cables, wrench, Alien screw driver for any 11970 series mixer.
Part Numbers
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