Agilent E5515C Data Sheet

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Agilent
8960 Series 10 cdma2000 Mobile Test for the E5515C Mainframe and the E1962B Test Application
Data Sheet
TX measurements
• Channel power
• Average power
• Access probe power
• Code Domain Power
RX measurements
• Sensitivity
• Dynamic range
• Demodulation of FCH with AWGN
• Service Option 002, 009, and 055 loop back support
IS-2000 Functionality
Call processing:
Registration One-button page Auto answer MS origination Hard Handoff (Band & Channel)
RF generator:
Pilot, Sync, Paging, Quick Paging, FCH Channel, OCNS, and AWGN Channels
Radio configuration support:
1 through 5 supported
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Technical specifications
These specifications apply to an E5515C mainframe with se­rial prefix US41070101 or higher when used with an E1962B test application of firmware revision B.01.15. Specifications describe the test set’s warranted performance and are valid over the entire operation and environmental ranges unless otherwise noted. All specifications are valid after a 30­minute warm-up period of continuous operation.
Supplemental characteristics are intended to provide addi­tional information useful in applying the instrument by giving typical, but non-warranted performance parameters. These characteristics are shown in Italics and labeled as “typical”, or “supplemental”. All units shipped from the factory meet these typical numbers at 25 °C ambi­ent temperature without including measurement uncertainty.
CW RF generator
Frequency
Available frequency range: 292 MHz to 2700 MHz Specified frequency ranges: 800 MHz to 960 MHz, and 1700
MHz to 2000 MHz
Accuracy and stability: Same as timebase reference
Amplitude
Available output level range: –127 to –10 dBm Specified output level range: –116 to –15 dBm Absolute output level accuracy: <±1.0 dB, typically <±0.5 dB
(Level accuracy at RF generator output levels >-30 dBm may be degrad-
ed by simultaneous reception and transmission when applied TX power
is >32 dBm.)
Audio generator
Frequency
Operating range: 100 Hz to 20 kHz, typically 1 Hz to 20 kHz Accuracy: Same as timebase reference Frequency resolution: typically 0.1 Hz
Output level (from AUDIO OUTPUT connector)
Ranges: 0 to 1 V peak, 1 to 9 V peak (into >600 ohms) Accuracy: <±(1.5% of setting +resolution) when output is DC
coupled
Distortion: <0.1% for 0.2 to 9 V peak into >600 ohms Coupling mode: User-selectable as DC or AC (5 uF in series
with output) Typical maximum output current: 100 mA peak into 8 ohms Typical output impedance: <1.5 ohms at 1 kHz when output is DC coupled
Typical DC offset (when output is DC coupled):
<1 mV peak for 0 to 1 V peak <10 mV peak for 1 to 9 V peak Output level resolution: typically <0.5 mV for 0 to 1 V peak output, <5.0 mV for 1 to 9 V peak output
CW RF analyzer
Frequency stability measurement
Types of signals measured: Analog signals without
modulation Frequency capture range: Signal must be within ±200 kHz of test set ’s expected frequency Minimum input level: Signal at test set ’s RF in/out must have analog TX power > –30 dBm
Frequency and frequency error measurement
Accuracy: <±(1 Hz + timebase accuracy), 800 to 960 MHz
Measurement trigger source: Immediate Available results: RF frequency and RF frequency error Multi-measurement capabilities: 1 to 999 measurements,
minimum, maximum, average and standard deviation in Hz for all results and worst case RF frequency error in ppm result. Concurrency capabilities: Frequency stability measurements can be made concurrently with all analog and audio measurements.
Measurement resolution for frequency and frequency error measurement results in Hz: typically 1 Hz. Measurement resolution for frequency error measurement result in ppm: typically 0.01 ppm.
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IS-2000 active cell call processing functionality
Resident formats: IS-2000 SR1
Call processing timing tolerance: mobile transmissions
must be typically within ±6 usec of test set’s transmitted pilot channel clock timing for proper reverse channel acquisition.
Overhead channels: F-pilot - with user settable PN offset F-sync - with real-time long code and system time update
and updates for user entered parameters such as SID, NID, PRAT, CDMA_FREQ, and PN OFFSET
F-paging - with real-time overhead messages F-QPCH - indicates if active page will be in the next paging
channel slot
Protocol stack: IS-2000 revision 0 with addendum (PREV = 6)
Base station parameters: NID, SID, country code (MCC), network code (MNC), paging rate, max slot cycle index, CDG esc mode, F-QPCH state, F-QPCH relative level, and reverse link traffic pilot gain
Call control ("one button commands"):
Register BS call originate BS call disconnect MS call originate (auto answer) MS call disconnect
Access parameters: Nom_pwr, nom_pwr_ext, init_pwr, pwr_step, num_step, max_req_seq, max_rsp_seq and pam_size
Registration support: User initiated (zone based), power up, timer based, implicit registration (mobile originated call), or direct user entry of mobile IMSI
Registration reported mobile information: ESN, MCC, MNC, MSIN, slot class, slot cycle index, protocol revision, band class, operating mode, max EIRP, registration type, QPCH support, enhanced RC support, minimum power control step size, MS called party number
Query mobile capabilities function: Uses signaling to request the mobile’s capabilities.
Requested parameters include: FCH: FCH supported, FCH 5 ms frames supported, F-FCH
radio configurations, R-FCH radio configurations DCCH: DCCH supported, DCCH frame size, F-DCCH radio configurations, R-DCCH radio configurations F-SCH: F-SCH supported, number of F-SCH channels supported, turbo encoder supported, turbo encoded rate set 1 max data rate, turbo encoded rate set 2 max data rate, convolutional encoder supported, convolutional encoded rate set 1 max data rate, convolutional encoded rate set 2 max data rate
R-SCH: R-SCH supported, number of R-SCH channels supported, turbo encoder supported, turbo encoded rate set 1 max data rate, turbo encoded rate set 2 max data rate, convolutional encoder supported, convolutional encoded rate set 1 max data rate, convolutional encoded rate set 2 max data rate
IMSI support: Class 0 only Supported IMSI class 0 types: MSIN only (00), MNC + MSIN (01), MCC + MSIN (10), or MCC + MNC + MSIN (11) Paging channel data rate: User selectable from either full or half rate
Service option support:
SO1– 9.6 kbps voice echo SO2– 9.6 kbps data loopback SO3 – 9.6 kbps EVRC voice echo SO9 – 14.4 kbps data loopback SO17– 14.4 kbps voice echo SO55 – RC1/2/3/4/5 data loopback SO32768 14.4 kbps voice echo
Handoff support: Hard handoff (new channel, band) Supported radio configuration combinations: Forward RC 1 + Reverse RC 1 Forward RC 2 + Reverse RC 2 Forward RC 3 + Reverse RC 3 Forward RC 4 + Reverse RC 3 Forward RC 5 + Reverse RC 4
Traffic data source: PRBS (CCITT 215-1 pattern)
Forward FCH data rate: RC2: 1.8, 3.6, 7.2, 14.4 kbps RC3: 1.5, 2.7, 4.8, 9.6 kbps RC4: 1.5, 2.7, 4.8, 9.6 kbps RC5: 1.8, 3.6, 7.2, 14.4 kbps
Forward SCH support: None
Reverse FCH data rate: RC1: 1.2, 2.4, 4.8, 9.6 kbps RC2: 1.8, 3.6, 7.2, 14.4 kbps RC3: 1.5, 2.7, 4.8, 9.6 kbps RC4: 1.8, 3.6, 7.2, 14.4 kbps
Reverse SCH support: None
Reverse link closed loop bit rate: fixed to 800 per second
Reverse link closed loop power control modes:
'ACTIVE’ ’ALTERNATING' - Alternating 0 and 1 power bits 'ALL UP' 'ALL DOWN'
Forward link power control support: None, test set ignores all power control data sent by the mobile station
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IS-2000 test mode functionality
Resident formats: IS-2000 SR1
Overhead channels: F-pilot - with user settable PN offset F-sync - with real-time long code and system time update
and updates for user entered parameters such as SID, NID, PRAT, CDMA_FREQ, and PN OFFSET
F-paging -with real-time overhead messages F-QPCH – all indicators on or all off
Protocol stack: Limited to IS-2000 revision 0 with
addendum sync channel message and paging channel overhead messages
Base station parameters: NID, SID, country code (MCC), network code (MNC), paging rate, CDG esc mode, F-QPCH state, F-QPCH relative level, F-QPCH data bits (all on or all off) and reverse link Traffic Pilot Gain
Call control ("one button commands"): None
Access parameters: None
Registration zupport: None
Service option support: None
Handoff support: None
R-access channel: Not supported
Chip rate: 1.2288 Mcps
Supported radio configuration combinations:
Forward RC 1 + Reverse RC 1 Forward RC 2 + Reverse RC 2 Forward RC 3 + Reverse RC 3 Forward RC 4 + Reverse RC 3 Forward RC 5 + Reverse RC 4
Channel coding: Convolutional or turbo on all rates with the exception that turbo coding is not available on RC3 at
9.6 kbps, RC4 at 9.6kbps, or RC5 at 14.4 kbps per IS-2000
Traffic data source: PRBS (CCITT 215-1 pattern)
Forward FCH data rate:
RC1: 1.2, 2.4, 4.8, 9.6 kbps RC2: 1.8, 3.6, 7.2, 14.4 kbps RC3: 1.5, 2.7, 4.8, 9.6 kbps RC4: 1.5, 2.7, 4.8, 9.6 kbps RC5: 1.8, 3.6, 7.2, 14.4 kbps
Forward SCH support: One supplemental channel
F-SCH data rate:
RC3: 9.6, 19.2, 38.4, 76.8, or 153.6 kbps RC4: 9.6, 19.2, 38.4, 76.8, 153.6, or 307.2 kbps RC5: 14.4, 28.8, 57.6, 115.2, or 230.4 kbps
Power control groups: 16 per frame
Reverse link closed loop support: Transmits bits only (no
reverse link demodulation)
Reverse link closed loopbit rate: fixed to 800 per second
Reverse link closed loop power control modes:
'ALTERNATING' - Alternating 0 and 1 power bits 'ALL UP' 'ALL DOWN'
Forward link power support: None
Mobile station identification:
User Entry of ESN (hexidecimal). Entry of all ‘F’ hex data results in using a zero long code mask
CDMA RF generator
Additive white Gaussian noise source: Ye s
AWGN bandwidth: typically 1.8 MHz< BW <2.1 MHz
CDMA channels:
CDMA cell consisting of these code channels:
F-Pilot - fixed at Walsh Code 0 F-Sync - fixed at Walsh Code 32 F-Paging - fixed at Walsh Code 1 F-QPCH – fixed at Walsh Code 80 F-FCH - user selectable Walsh Code from the following set:
10, 14, 26, 30, 42, 46, 58, or 62
F-SCH - Fixed to Walsh Code 3 F-OCNS – user-selectable Walsh Code from the following set:
5, 13, 21, 29, 37, 45, 53, and 61
CDMA cell PN offset: User selectable from 0 to 511
Frequency
Frequency range:
US Cellular band (869.04 to 893.97 MHz) Japan CDMA band (approx. 832 to 869.9875 MHz) US PCS band (1930 to 1990 MHz) Korean PCS band (1840 to1870 MHz) NMT- 450 band (approx. 421 to 494 MHz) IMT- 2000 band (2110 to 2169.950 MHz)
Frequency setting: By channel number or MHz (IS-2000 test mode only)
Frequency setting resolution: 1 Hz
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Amplitude
Composite signal level: Sum of the user set values of the
CDMA Cell power and the AWGN source
CDMA cell output level range (AWGN off):
–120 dBm/1.23 MHz to –13 dBm/1.23 MHz
AWGN output level range (cell power off):
–120 dBm/1.23 MHz to –18 dBm/1.23 MHz.
Over-range available with reduced performance to –15 dBm/1.23 MHz
Absolute output level accuracy (AWGN off): < 1 GHz Bands:
< ±1.25 dB, –109 to –15 dBm/1.23 MHz. Typically ±0.62 dB, –109 to –15 dBm/1.23 MH.
>1.5 GHz Bands:
< ±1.35 dB, –109 to –15 dBm/1.23 MHz.
Typically ±0.62 dB, –109 to –15 dBm/1.23 MHz
Absolute output level accuracy (AWGN on): < 1 GHz bands:
< ±1.5 dB, –109 to –20 dBm/1.23 MHz.
Typically ±0.75 dB, –109 to –20 dBm/1.23 MHz
>1.5 GHz bands:
< ±1.6 dB, –109 to –20 dBm/1.23 MHz.
Typically ±0.75 dB, –109 to –20 dBm/1.23 MHz
Reverse power: <10 W continuous
VSWR at RF IN/OUT:
< 1.14:1, 400 MHz to 1000 MHz, <1.2:1, 1700 MHz to 2000 MHz, <1.32:1, 2010 MHz to 2180 MHz
F-Pilot relative level: –10 to 0 dB, or off
F-Sync relative level: –20 to 0 dB, or off
F-Paging relative level: –20 to 0 dB, or off
F-FCH channel relative level: User settable from –30 to 0
dB with 0.01 dB resolution, or off
AWGN channel relative level range: User- settable to ±10 dB relative to the user set CDMA cell power with 0.01 dB resolution
F-OCNS Walsh Code length: fixed to 64 bits
F-OCNS relative level range: Automatically calculated from
other code channel relative levels to provide the set CDMA cell power (range of –20 to 0 dB, or off)
Relative CDMA channel level accuracy:
Typically < ± 0.2 dB
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CDMA modulation
Modulation type: Parallel BPSK for Pilot, Sync, and Paging Channels and Complex QPSK for the F-FCH per IS-2000
Modulation quality:
RC1 & RC2 residual Rho: >0.98
RC3, RC4, and RC5 residual Rho (pilot only): > 0.98
Residual EVM: <10%
Carrier feedthrough: Typically < –25 dBc
CDMA RF analyzer (measurements only)
Frequency range (reverse channels):
US Cellular band Japan CDMA band US PCS band Korean PCS band NMT-450 band IMT-2000 band
Input level range: –71 dBm/1.23 MHz to +35 dBm/1.23 MHz
Receiver ranging:
Auto mode: Autoranges to the ideal RF power level
for the nominally expected open loop response. Provides calibrated results if actual received power is within ±9 dB of the expected open loop power.
Manual mode: User enters expected power. If the "Ac– tive" mode is selected, the Test Set uses Closed Loop Power control to drive the mobile to the expected power. Otherwise, the mobile’s TX power must be within ±9 dB of the expected power to provide calibrated results.
CDMA analyzer
Average power measurement
Input frequency ranges:
411 MHz to 484 MHz 800 MHz to 1000 MHz 1700 MHz to 2000 MHz
Detector types:
Peak detector – in R-RC1 and R-RC2 modes Thermal detector – in R-RC3 and R-RC4 modes
Maximum input level: +35 dBm (3 Watts continuous)
Measurement range: –10 to +35 dBm. Usable from –10 to
–27 dBm with reduced accuracy (peak detector only).
Measurement level ranging: Auto
Measurement data capture period: 10 ms
Available results: Average power
Concurrency capabilities: Average power measurements
can be made concurrently with all CDMA measurements. Peak detector measurement accuracy (20° C to 55° C, after calibration; reverse RC1, RC2):
-10 to +35 dBm:
400 to 500 MHz < ±7.4%. Typically < ±3.0 % 800 to 1000 MHz < ±7.1%. Typically < ±3.0 % 1700 to 2000 MHz < ±7.5%. Typically < ±4.4 %
-10 to -20 dBm:
400 to 500 MHz. Typically < ±4.4 % 800 to 1000 MHz. Typically < ±4.2 % 1700 to 2000 MHz. Typically < ±4.8 %
Thermal detector measurement accuracy (accuracy with 10 internal averages; reverse RC3 or RC4):
-10 to +35 dBm:
400 to 500 MHz < ±6.9%. Typically < ±3.0 % 800 to 1000 MHz < ±6.2%. Typically < ±3.0 % 1700 to 2000 MHz < ±7.4%. Typically < ±3.3 %
Measurement resolution: 0.01 dBm Auto zero function: Measurement automatically zeroes the average power meter (no user control)
Tuned channel power measurement
Input frequency ranges:
411 MHz to 420 MHz 450 MHz to 484 MHz 824 MHz to 934 MHz 1750 MHz to 1780 MHz 1850 MHz to 1980 MHz
Measurement method: Measures the total power in a 1.23 MHz bandwidth centered on the active reverse channel center frequency.
Measurement data capture period: 1.25 ms (fast mode) or 10 ms (normal mode)
Measurement trigger: 20 ms clock (frame trigger)
Maximum input level: +35 dBm (3 watts continuous)
Measurement range: -61 dBm to +30 dBm. Usable to <–69
dBm/1.23 MHz with reduced accuracy
Measurement level ranging: Auto and manual
Measurement accuracy: (Calibrated against average power
and within 10 degrees of calibration temperature): < ±1 dB 20° C to 55° C, typically < ±0.5 dB
Measurement resolution: 0.01 dBm/1.23 MHz Available results: Tuned channel power in a 1.23 MHz bandwidth
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Concurrency capabilities: Channel power measurements can be made concurrently with all CDMA measurements.
Calibrate function: Calibrates the channel power measurement over the entire operating frequency range of the test set against the average power measurement. No external cabling is required.
Calibration time: Typically < 120 seconds
Access probe power measurement
Input frequency ranges:
411 MHz to 420 MHz 450 MHz to 484 MHz 824 MHz to 934 MHz 1750 MHz to 1780 MHz 1850 MHz to 1980 MHz
Measurement method: Measures the total power in a 1.23 MHz bandwidth centered on the active reverse channel center frequency.
Measurement data capture period: 1.25 ms
Measurement trigger: Amplitude Rise only
Maximum input level: +35 dBm (3 watts continuous)
Measurement range: -54 dBm to +30 dBm
Measurement level ranging: Auto and manual
Measurement accuracy: (Calibrated against average power
and within 10 degrees of calibration temperature): < ±1 dB 20° C to 55° C, typically < ±0.5 dB
Available results: Access probe power in a 1.23 MHz bandwidth
Concurrency capabilities: None, once an access probe power measurement is armed, all TX measurements are held off until the access probe power measurement completes.
Modulation quality measurement
Input frequency ranges:
411 MHz to 484 MHz 800 MHz to 1000 MHz 1700 MHz to 2000 MHz
Measurement chip rate: 1.2288 Mcps
Modulation measurement method:
RC1, RC2: Single code rho RC3, RC4, and RC5: Multi-code rho and EVM with
code domain results
Maximum input level: +35 dBm/1.23 MHz (3 Watts continuous)
Input level range: –25 to +30 dBm/1.23 MHz. Usable to –50 dBm/1.23 MHz with reduced accuracy.
Modulation quality measurement range (for signals with < ±10 usec time error and < ±1 kHz frequency error):
RC1, RC2: 0.40 to 1.00 rho RC3, RC4, and RC5: 1% to 40% EVM
Measurement interval: 1.042 msec (5 Walsh symbols)
Modulation quality measurement accuracy:
RC1, RC2 rho: < ± 0.003 + residual error for 0.8 < rho <1.0 RC3, RC4, and RC5 EVM: < ± 1.25% rms + residual
error for 1% < EVM <20%
Modulation quality measurement residuals:
Residual rho: >0.999
Residual EVM: < 4.2% rms, typically <2.8% rms
Residual time error: ±0.11 usec
Frequency error: ±15 Hz plus timebase error
Residual code domain power: <–35 dBc
Code domain results:
Code domain power graph: displays the power in all
16 Walsh coded channels (16 bit) for both the I channel and the Q channel. Reported power in each graph is relative to the total combined I and Q channel power. Red bars indicate active channels, while yellow bars indicate inactive channels.
Code domain power and noise graph: displays the power and noise in all 16 Walsh coded channels (16 bit) for both the I channel and the Q channel. Reported power in each graph is relative to the total combined I and Q channel power. Red bars indicate active channels, while yellow bars indicate noise in each channel.
Code domain power relative measurement accuracy (R­RC3 and R-RC4 only): < ± 0.005 relative to total power for
linear code domain powers from 0.05 to 1.0.
Code domain power offset relative to reverse Pilot channel: < ± 0.20 dB
Available results (numeric rho): rho, frequency error, time
error, carrier feedthrough, phase error, amplitude error, and EVM
Concurrency capabilities: Modulation quality measurements can be made concurrently with all CDMA measurements.
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Frame error rate measurement
FER measurement method: Data loopback
supporting confidence limits
FER input level measurement range: –65 dBm/1.23 MHz to + 30 dBm/1.23 MHz
FER measurement residual error rate: < 1 x 10-6 for inputs levels in the specified input level measurement range and within ± 9 dB of the expected input power
Confidence limit range: User definable from 80.0% to 99.9% and Off
Available results:
Intermediate results: Measured FER, number of
errors, number of frames tested (every frame) Final results: Measured FER, number of errors, number of frames tested, and one of the following: passed confidence limit, failed confidence limit, or max frames
Concurrency capabilities: FER measurements can be made concurrently with all CDMA measurements.
Conditions for terminating FER test:
Max frames: Maximum number of frames to test
completed - test result is indeterminate
Failed: Measured FER failed the specified FER limit with specified confidence
Passed: Measured FER passed the specified FER limit with specified confidence
FER measurement indicators: Testing, passed, failed, and max frames. All indicators are available over GP-IB.
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Timebase specifications
Internal high stability 10 MHz oven controlled crystal oscillator (OCXO)
Aging rates: <±0.1 ppm per year, <±0.005 ppm peak-to-peak per day during any 24-hour period starting 24 hours or more after a cold start
Temperature stability: <±0.01 ppm frequency variation from 25° C over the temperature range 0° to 55° C
Warm-up times: 5 minutes to be within ±0.1 ppm of frequency at one hour, 15 minutes to be within ±0.01 ppm of frequency at one hour
Typical accuracy after a 30 minute warm-up period of continuous operation is derived from:
±[(time since last calibration) x (aging rate) + (temperature stability) + (accuracy of calibration)]
Typical initial adjustment: ±0.03 ppm
External reference input
Input frequency: 10 MHz
Input frequency range: typically <±5 ppm of nominal
reference frequency
Input level range: typically 0 to +13 dBm
Input impedance: typically 50 Ohms
External reference output
Output frequency: Same as timebase (internal 10 MHz
OCXO or external reference input)
Typical output level: typically 0.5 V rms
Output impedance: typically 50 Ohms
Trigger output
Frame clock output: User-selectable output of 20 ms,
80 ms, or 2 s
Remote programming
GPIB: IEEE Standard 488.2
Remote front panel lockout: Allows remote user to
disable the front panel display to improve GPIB measurement speed.
Implemented functions: T6, TE0, L4, LE0, SH1, AH1, RL1, SR1, PP0, DC1, DT0, C0, E2
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General specifications
Dimensions (H x W x D): 8.75 x 16.75 x 24.63 inches (222 x 426 x 625 mm), 7 rack spaces high
Weight: 66 lbs. (30 kg)
Display: 10.5 inches (26.7 cm), active matrix, color, liquid
crystal
LAN (local area network) Port (for firmware upgrades only): RJ-45 connector, 10 Base T Ethernet with TCP/IP
support
Operating temperature: 0 to +55° C
Storage temperature: -20 to +70° C
Power: 100 to 240 Vac, 50 to 60 Hz, 550 VA maximum
Calibration interval: 2 years
EMI: Conducted and radiated interference meets
CISPR-11
Radiated leakage due to RF generator: Typically <1 µV induced in a resonant dipole antenna one inch from any surface except the underside and rear panel at set RF generator output frequency and output level of -40 dBm
Spurious leakage: Typically <5 µV induced in a resonant dipole antenna one inch from any surface except the underside and rear panel at frequencies other than the RF generator output frequency and output level of -40 dBm
Power consumption: typically 400 to 450W continuous
Typical measurement speed: Measured using a 600 MHz
Pentium II processor PC and with the display off mode selected on the E5515C. Measurement speeds include the total time from GPIB measurement request until the controller receives the result using the INT/FETCH commands. Due to variations of trigger latencies and internal test set processor loading, individual measurement times may be faster or slower. Measurement speeds also vary depending on the controller GPIB environment and processor speed.
Measurement name One measurement Ten Measurements
Channel power (normal mode) 67 ms 820 ms
Channel power (fast mode) 21 ms 230 ms
Average power (RC3) 190 ms 1780 ms
Waveform quality RC3/4 261 ms 2220 ms
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Product specifications and descriptions in this document subject to change without notice.
Copyright © 2001 Agilent Technologies
Printed in U.S.A. June 19, 2001
5988-1889EN
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