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E4412A - TRS RenTelco

1. 1 2 1 15 SWR 1 1 1 05 1 0 2 4 6 8 10 12 14 16 18 Frequency GHz t 13 E series E9300 average power sensors Table 10 Power linearity after zero and cal at ambient environmental conditions Sensor Power Linearity Linearity 25 C 10 C 0 55 C E9300A E9301A E9304A 60 to 10 dBm 3 0 3 5 10 to 0 dBm 2 5 3 0 0 to 20 dBm 2 0 2 5 E9300B E9301B 30 to 20 dBm 3 5 4 0 20 to 30 dBm 3 0 3 5 30 to 44 dBm 2 5 3 0 E9300H E9301H 50 to 0 dBm 4 0 5 0 0 to 10 dBm 3 5 4 0 10 to 30 dBm 3 0 3 5 Typical E9300A 01A 04A Power Linearity at 25 C after zero and calibration with associated measurement uncertainty Error a ao qv nd 2 f 2 nx NS ay Power dBm Power range 30 to 20 dBm 20 to 10 dBm 10 to 0 dBm 0 to 10 dBm 10 to 20 dBm Measurement uncertainty 0 9 0 8 0 65 0 55 0 45 14 E series E9300 average power sensors Typical E9300B 01B power linearity at 25 C after zero and calibration with associated measurement uncertainty 10 5 0 5 10 15 20 25 30 Power Brn J Power range 6 to 0 dBm 0 to 10 dBm 10 to 20 dBm 20 to 26 dBm Measurement uncertainty 0 65 0 55 0 45 0 31 Typical E9300H 01H power linearity at 25 C after zero and calibration with associated measurement uncertainty 0 Power dBm Power range 26 to 20 dBm 20to 10dBm 10to0dBm Oto 10dBm 10to 20dBm 20 to
2. e Agilent o e EPM Series Power Meters e Qo E Series and 8480 Series Power Sensors e Data Sheet Product specifications and characteristics E Agilent Technologies EPM series E4418B and E4419B power meters Specifications Specifications describe the instru ment s warranted performance and apply after a 30 minute warm up These specifications are valid over its operating environmental range unless otherwise stated and after performing a zero and calibration procedure Supplemental characteristics Supplemental characteristics shown in italics are intended to provide additional information useful in applying the instrument by giving typical expected but not warrant ed performance parameters These characteristics are shown in italics or labeled as typical nominal or approximate For information on measurement uncertainty calculations refer to Application Note 64 1C Funda mentals of RF and Microwave Power Measurements literature number 5965 6380E Frequency range 9 kHz to 110 GHz sensor dependent Power range 70 dBm to 44 dBm 100 pW to 25 W sensor dependent Power sensors Compatible with all 8480 series and E series sensors Single sensor dynamic range 90 dB maximum E series sensors 50 dB maximum 8480 series sensors Display units Absolute Watts or dBm Relative Percent or dB Display resolution Selectable resolution of 1 0 0 1 0 0
3. 26 dBm Measurement uncertainty 0 9 0 8 0 65 0 55 0 45 0 31 15 Note If the temperature changes after calibration and you choose not to re calibrate the sensor the following additional power linearity error should be added to the linearity specs in table 10 the typical maximum additional power linearity error due to temperature change after calibration for small changes in temperature is 0 15 C valid after zeroing the sensor For large changes in temperature refer to Table 11 Typical maximum additional power linearity error due to temperature change after calibration at 25 C for any change in temperature valid after zeroing the sensor Table 11 Sensor Power Additional power Additional power linearity error linearity error 25 C 10 C 0 55 C E9300A E9301A E9304A 60 to 10 dBm 1 5 2 0 10 to 0 dBm 1 5 2 5 0 to 20 dBm 1 5 2 0 E9300B E9301B 30 to 20 dBm 1 5 2 0 20 to 30 dBm 1 5 2 5 30 to 44 dBm 1 5 2 0 E9300H E9301H 50 to 0 dBm 1 5 2 0 0 to 10 dBm 1 5 2 5 10 to 30 dBm 1 5 2 0 A420 dBm B 4d dBm H 30 dBm I I I I 10 dBm r 20 dBm 0 dBmnm I Measurect I Power I I I I I I I I I 60 dBm 30 dBm 50dBm A 80 dBm 10 Bm 20 dBm B 30 dBm 20 dBm 44 dBm H 50 dBm D dBin 30 dBm Figure 2 Relative mode power measurement linearity with an EPM series power meter at 25 C 10 C typical Figure 2
4. 2 kg 0 38 Ib 30 MHz to 50 MHz 1 18 30 W us per pulse Shipping 0 5 kg 1 0 Ib 50 MHz to 2 GHz 1 10 2 GHz to 12 4 GHz 1 18 12 4 GHz to 18 GHz 1 28 8482A 100kHzto4 2 GHz 100 kHz to 300 kHz 1 60 10 dBm to 20 dBm 396 300 mW avg 15 W p Type N m Net 0 2 kg 0 38 Ib 300 kHz to 1 MHz 1 20 30 W us per pulse Shipping 0 5 kg 1 0 Ib 1 MHz to 2 GHz 1 10 2 GHz to 4 2 GHz 1 30 8483A 100 kHz to 2 GHz 100 kHz to 600 kHz 1 80 10 dBm to 20 dBm 3 300 mW avg 10 W p Type N m Net 0 2 kg 0 38 Ib 75 ohm 600 kHz to 2 GHz 1 18 75 ohm Shipping 0 5 kg 1 0 Ib R8486A 26 5 GHz to 40 GHz 26 5 GHz to 40 GHz 1 40 10 dBm to 20 dBm 396 300 mW avg 15 W p Waveguide flange Net 0 26 kg 0 53 Ib 30 W us per pulse UG 599 U Shipping 66 kg 1 3 Ib 08486A 33 GHz to 50 GHz 33 GHz to 50 GHz 1 50 10 dBm to 20 dBm 396 300 mW avg 15 W p Waveguide flange Net 0 26 kg 0 53 Ib 30 W us per pulse UG 383 U Shipping 66 kg 1 3 Ib V8486A 50 GHz to 75 GHz 50 GHz to 75 GHz 1 06 10 dBm to 20 dBm 296 200 mW avg 40 W p Waveguide flange Net 0 4 kg 0 9 Ib 30 dBm to 10 dBm 196 10 us per pulse 0 5 UG 385 U Shipping 1 kg 2 1 Ib duty cycle W8486A 75 GHz to 110 GHz 75 GHz to 110 GHz 1 08 296 200 mW avg 40 W p Waveguide flange Net 0 4 kg 0 9 Ib 10 us per pulse 0 5 UG 387 U Shipping 1 kg 2 1 Ib duty cycle 8487A 50 MHzto 50 GHz 50 MHz to 100 MHz 1 15 10 dBm to 20 dBm 394 300
5. capacity at 25 C 450 charge discharge cycles Chemistry nickel metal hydride Weight 1kg 1 Characteristics describe product performance that is useful in the application of the product but is not covered by the product warranty Environmental characteristics General conditions Complies with the requirements of the EMC Directive 89 336 EEC This includes Generic Immunity Standard EN 50082 1 1992 and Radiated Interference Standard EN 55011 1991 CISPR11 1990 Group 1 Class A Operating environment Temperature 0 C to 55 C Maximum humidity 95 at 40 C non condensing Minimum humidity 15 at 40 C non condensing Maximum altitude 3000 meters 9840 feet Storage conditions Storage temperature 20 C to 70 C Non operating maximum humidity 90 at 65 C non condensing Non operating maximum altitude 15240 meters 50 000 feet General Dimensions The following dimensions exclude front and rear protrusions 212 6 mm W x 88 5 mm H x 348 3 mm D 8 5 in x 3 5 in x 13 7 in Weight Net E4418B 4 0 kg 8 8 lb E4419B 4 1 kg 9 0 Ib Shipping E4418B 7 9 kg 17 4 lb E4419B 8 0 kg 17 6 Ib Remote programming Interface GBIB interface operates to IEEE 488 2 RS 232 and RS 422 serial interface supplied as standard Command language SCPI standard interface commands 436A and 437B code compatible E4418B only 438A code compatible E4419B only GPIB compatibility
6. mW avg 15 W p 2 4 mm m Net 0 14 kg 28 Ib 100 MHz to 2 GHz 1 10 2 GHz to 12 4 GHz 1 15 12 4 GHz to 18 GHz 1 20 18 GHz to 26 5 GHz 1 25 26 5 GHz to 40 GHz 1 30 40 GHz to 50 GHz 1 50 30 W us per pulse Shipping 0 5 kg 1 0 Ib 1 Negligible deviation except for those power ranges noted 2 For pulses greater than 30 W the maximum average power P4 is limited by the energy per pulse E in W us according to P4 30 0 02 E 20 8480 series sensors with EPM series power meters High sensitivity sensors 100 pW to 10 pW 70 dBm to 20 dBm Model Frequency range Maximum SWR Power linearity Maximum power Connector type Weight 8481D3 10 MHz to 18 GHz 10 MHz to 30 MHz 1 40 30 dBm to 20 dBm 1 100 mW avg 100 m W pk Type N m Net 0 16 kg 0 37 Ib 30 MHz to 3 GHz 1 15 Shipping 0 9 kg 2 0 Ib 4 GHz to 10 GHz 1 20 10 GHz to 15 GHz 1 30 15 GHz to 18 GHz 1 50 8485D3 50 MHz to 26 5 GHz 0 05 GHz to 0 1 GHz 1 19 30 dBm to 20 dBm 2 100 mW avg 100 m W pk APC 3 5mm m Net 0 2 kg 38 Ib 0 1 GHz to 4 GHz 1 15 Shipping 0 5 kg 1 0 Ib 4 GHz to 12 GHz 1 19 12 GHz to 18 GHz 1 25 18 GHz to 26 5 GHz 1 29 Option 50 MHz to 33 GHz 26 5 GHz to 33 GHz 1 35 30 dBm to 20 dBm 296 100 mW avg 100 m W pk APC 3 5mm m Net 0 2 kg 38 Ib 8485D 033 Shipping 0 5 kg 1 0 Ib 8487D3 50 kHz to 50 GHz 0 05 GHz to 0 1 GHz 1 19 30 dBm to 20 dBm 2 100 mW avg 100 m W
7. rack 2U high instruments 34141A Yellow soft carry operating case 34161A Accessory pouch E9287A1 Spare battery pack for the EPM power meter Complementary equipment 11683A Range calibrator Verifies the accuracy and linearity of the EPM series power meters Outputs corresponding to meter readings of 3 10 30 100 and 300 uW and 1 3 10 30 and 100 mW are provided Calibration uncertainty is 0 25 on all ranges Service options Warranty Included with each EPM series power meter is a standard 12 month return to Agilent warranty and service plan For warranty and service of 5 years please order 60 months of R 51B R 51B Return to Agilent warranty and service plan Calibration For 3 years order 36 months of the appropriate calibration plan shown below For 5 years specify 60 months R 50C 001 Standard calibration plan R 50C 002 Standard compliant calibration plan The E series and 8480 series power sensors have a 12 months return to Agilent warranty and service plan For more information contact your local sales and service office E series power sensor specifications The E series of power sensors have their calibration factors stored in EEPROM and operate over a wide dynamic range They are designed for use with the EPM series of power meters and two classes of sensors are available CW power sensors E4412A and EA44134A Average power sensors E9300 sensors Power linearity E se
8. to 4 2 GHz 1 18 3 Watt sensors 100 pW to 3 W 10 dBm to 35 dBm Model Frequency range Maximum SWR Power linearity 1 35 C to 550 C 25W avg 0 01 to 5 8 GHz 500W pk 5 8 to 18 GHz 125 W pk 500 W us per pulse Maximum power Connector type Shipping 1 5 kg 3 25 Ib Weight 8481H 10MHzto18GHz 10 MHz to 8 GHz 1 20 25 dBm to 35 dBm 596 3 5 W avg 100 W pk Type N m Net 0 2 kg 0 38 Ib 8 GHz to12 4 GHz 1 25 100 W us per pulse Shipping 0 5 kg 1 0 Ib 12 4 GHz to 18 GHz 1 30 8482H 100 kHzto4 2 GHz 100 kHz to 4 2 GHz 1 20 25 dBm to 35 dBm 596 3 5 W avg 100 W pk Type N m Net 0 2 kg 0 38 Ib 100 mW sensors 1 pW to 100 mW 30 dBm to 20 dBm Model Frequency range Maximum SWR Power linearity 1 100 W us per pulse Maximum power Connector type Shipping 0 5 kg 1 0 Ib Weight 8485A 50 MHz to 26 5 GHz 50 MHz to 100 MHz 1 15 10 dBm to 20 dBm 394 300 mW avg 15 W pk APC 3 5mm m Net 0 2 kg 38 Ib 100 MHz to 2 GHz 1 10 30 W us per pulse Shipping 0 5 kg 1 0 Ib 2 GHz to 12 4 GHz 1 15 12 4 GHz to 18 GHz 1 20 18 GHz to 26 5 GHz 1 25 Option 50 MHzto 33 GHz 26 5 GHz to 33 GHz 1 40 10 dBm to 20 dBm 396 300 mW avg 15 W pk APC 3 5mm m Net 0 2 kg 38 Ib 8485A 033 30 W us per pulse Shipping 0 5 kg 1 0 Ib 8481A 10MHzto18GHz 10 MHz to 30 MHz 1 40 10 dBm to 20 dBm 396 300 mW avg 15 W pk Type N m Net 0
9. with Option E441XB 001 installed 2 For Option E441XB 001 the 36 month warranty does not apply to the E9287A battery pack 3 Options not available in all countries Additional documentation Selections can be made for the local ization of the User s Guide and an English language Service Manual Option E441xB 915 English language Service Manual Option E441xB 916 English language manual set hard copy Users Guide and Programming Guide Option E441xB ABD German localiza tion hard copy Users Guide and English Programming Guide Option E441xB ABE Spanish localiza tion hard copy Users Guide and English Programming Guide Option E441xB ABF French localiza tion hard copy Users Guide and English Programming Guide Option E441xB ABJ Japanese localiza tion hard copy Users Guide and English Programming Guide Cables Option E441xB 004 Delete power sensor cable Additional cables 11730A Power sensor and SNS noise source cable length 1 5 meters 5 ft 11730B Power sensor and SNS noise source cable length 3 meters 10 ft 11730C Power sensor and SNS noise source cable length 6 1 meters 20 ft 11730D Power sensor cable length 15 2 meters 50 ft 11730E Power sensor cable length 30 5 meters 100 ft 11730F Power sensor cable length 61 meters 200 ft Accessories Option E441xB 908 Rackmount kit one instrument Option E441xB 909 Rackmount kit two instruments 34131A Transit case for half
10. 0 nW E4412A E4413A 15 pW 70 pW E9300 E9301A E9304A3 150 pW 700 pw E9300B E9301B3 lt 150 nW 700 nW E9300H E9301H3 lt 15 nW lt 7nW 1 Within 1 hour after zero set at a constant temperature after a 24 hour warm up of the power meter 2 The number of averages at 16 for normal mode and 32 for x2 mode at a constant temperature measured over a one minute interval and two standard deviations For E series sensors the measurement noise is measured within the low range Refer to the relevant sensor manual for further information 3 Specification applies to the low power path 15 to 75 relative humidity Measurement noise Sensor depen dent refer to table 2 and table 3 For E9300 sensors refer to table 12 Effects of averaging on noise Averaging over 1 to 1024 readings is available for reducing noise Table 2 provides the measurement noise for a particu lar sensor with the number of averages set at 16 for normal mode and 32 for x2 mode Use the noise multiplier for the appropriate mode normal or x2 and number of averages to determine the total mea surement noise value Example 8481D power sensor normal mode number of averages 4 Measurement noise calculation lt 45 pW x 2 75 121 pW Table 3 Number of averages 1 2 4 8 16 32 64 128 256 512 1024 Noise multiplier 5 5 3 89 2 15 1 94 1 0 85 0 61 0 49 0 34 0 24 0 17 normal mode Noise multiplier 6 5 4 6 3 25 2 3 1
11. 1 and 0 001 dB in Log mode or 1 to 4 digits in linear mode Default resolution 0 01 dB in log mode 3 digits in linear mode Accuracy Instrumentation Absolute 0 02 dB log or 0 5 linear Please add the correspond ing power sensor linearity percent age from tables 7 and 10 for the E series sensors and table 15 for the 8480 series sensors Relative 0 04 dB Log or 1 0 linear Please add the correspond ing power sensor linearity percent age from table 16 for the 8480 series sensors Zero set digital settability of zero sensor dependent refer to table 1 For E series sensors this specification applies to a ZERO performed when the sensor input is not connected to the POWER REF Power reference Power output 1 00 mW 0 0 dBm Factory set to 0 4 traceable to the National Physical Laboratory NPL UK Accuracy For two years 40 5 23 3 C 0 6 25 10 C 0 9 0 to 55 C Frequency 50 MHz nominal SWR 1 06 maximum 1 08 maximum for Option 003 Connector type Type N f 50 Q Table 1 Model ZERO SET 8481A 8482A 8483A 8485A 50 nW 8487A R8486A 08486A 8481B 8482B 50 pW 8481D 8485D 8487D 20 pW 8481H 8482H 5 pW R8486D 08486D 30 pW V8486A W8486A 200 nW E4412A E4413A 50 pW E9300A E9301A E9304A 2 500 pW E9300B E9301B 2 500 nW E9300H E9301H 5 nW National metrology institutes of member states of the Metre Convention such as
12. 1 8 8482H 8483A Freq GHz 8481A 8481B 8481H 8481D 8485A 8385D 8487A 8487D 1 1 6 3 1 9 1 9 1 6 1 8 1 6 2 2 1 4 3 1 1 7 1 8 1 6 1 8 1 6 2 4 1 5 3 1 1 8 1 8 1 7 1 8 1 6 2 6 1 5 3 1 1 8 1 8 1 8 2 1 1 7 2 3 8 1 7 3 2 2 2 1 9 2 2 1 8 2 3 10 1 9 3 3 2 2 2 2 2 2 1 1 8 2 3 12 2 1 4 1 24 2 8 2 22 1 9 2 3 14 2 6 41 2 8 3 2 2 2 2 2 2 1 2 8 16 2 9 4 2 3 3 4 2 3 2 5 2 2 2 8 18 3 2 4 3 3 1 3 7 2 2 6 2 3 2 8 22 2 1 2 1 8 2 8 26 5 2 1 2 3 2 1 2 8 Freq GHz R8486A 08486A R8486D Q8486D 8487A 8487D 26 5 2 2 3 2 1 2 8 28 2 4 3 2 2 3 3 30 2 5 3 2 1 3 33 2 1 2 8 3 4 2 2 3 3 34 5 2 1 2 8 3 4 2 2 1 3 37 2 2 2 8 3 4 2 2 3 3 40 2 2 2 9 3 4 2 2 6 3 42 3 9 4 9 3 2 2 9 44 3 9 5 1 3 6 2 9 46 3 9 5 5 4 1 3 1 48 4 9 5 8 4 5 4 5 50 5 3 6 2 5 4 5 19 8480 series sensors with EPM series power meters Table 15 25 Watt sensors 1 mW to 25 W 0 dBm to 44 dBm Model Frequency range Maximum SWR Power linearity Maximum power Connector type Weight 8481B 10 MHzto 18 GHz 10 MHz to 2 GHz 1 10 35 dBm to 44 dBm 496 0 C to 350 C 30W avg 2 Type N m Net 0 8 kg 1 75 Ib 2 GHz to 12 4 GHz 1 18 35 C to 550 C 25W avg Shipping 1 5 kg 3 25 Ib 12 4 GHz to 18 GHz 1 28 0 01 to 5 8 GHz 500W pk 5 8 to 18 GHz 125 W pk 500 W us per pulse 8482B 100 kHz to 4 2GHz 100 kHz to 2 GHz 1 10 35 dBm to 44 dBm 4 0 C to 350 C 30W avg 2 Type N m Net 0 8 kg 1 75 Ib 2 GHz
13. 4412A and E4413A sensors Auto filter default resolution 10 dB decreasing power step not across the range switch point For E series E9300A sensors For E series E9300B and H sensors Typical Settling Times X2 Normal Mode Mode Maximum Sensor Power 40 dBm 50 dBm 60 dBm Sensor Dynamic Range Typical Settling Times X2 Normal Mode Mode Maximum Sensor Power 10 dBm 2 dBm 4 dBm 10 dBm 20 dBm 30 dBm 40 dBm 50 dBm Sensor Dynamic Range High Power Path Typical Settling Times Low Powel Path X2 Normal Mode Mode Maximum Sensor Power Minimum Sensor power 20 dBm 12 dBm 6 dBn 0 dB Sensor Dynamic 10 d Range 20 d 30 d 40 Power meter functions Accessed by key entry either hardkeys or softkey menu and programmable Zero Zeros the meter Power refer ence calibrator is switched off during zeroing Cal Calibrates the meter using internal power reference calibrator or external source Reference cal factor settable from 1 to 150 in 0 1 increments Frequency Entered frequency range is used to interpolate the calibration factors table Range 1 kHz to 999 9 GHz settable in 1 kHz steps Cal factor Sets the calibration Factor for the meter Range 1 to 150 in 0 1 increments Relative Displays all successive measurements relative to the last displayed va
14. 63 1 0 72 0 57 0 41 0 29 0 2 x2 mode EPM series E4418B and E4419B power meters Settling time For 8480 series sensors Manual filter 10 dB decreasing power step Table 4 Number of 1 2 4 8 16 32 64 128 256 512 1024 averages Settling time s 0 15 0 2 0 3 0 5 1 1 1 9 3 4 6 6 13 27 57 normal mode Settling time s 0 15 0 18 0 22 0 35 0 55 1 1 1 9 3 5 6 9 14 5 33 x2 modes Auto filter default resolution 10 dB decreasing power step normal and x2 modes Normal Mode x2 Mode Max dBm Max dBm 150 ms 20 dB 150 ms 20 dB Typical Sensor Typical Sensor ott i 10dB Dynamic 180 ms 10dB Dynamic Settling 200 ms Renae Settling Range Times Times 500 ms 10 dB 350 ms 10 dB 6 6 s Uo dB 3 5s 10 dB Min dBm Min dBm iu a For E series sensors In FAST mode using free run trigger within the range 50 dBm to 17 dBm for a 10 dB decreasing power step the settling time is E4418B 10 ms E4419B 20 ms Table 5 Manual filter 10 dB decreasing power step not across the range switch point Number of 1 2 4 8 16 32 64 128 256 512 1024 averages Settling time s 0 07 0 12 0 21 0 4 1 1 8 33 6 5 13 27 57 Normal mode Settling time s 0 04 0 07 0 12 0 21 0 4 1 1 8 3 4 6 8 14 2 32 1 Settling time 0 to 99 settled readings over the GPIB 2 When a power step crosses through the sensor s auto range switch point add 25 mS Refer to the relevant sensor manual for switch point information For E
15. 9304A sensors zero and measurement noise Conditions Zero set Zero drift Measurement noise Low power path 500 pW 150 pW 700 pW 1596 to 7596 RH Low power path 500 pW 4 000 pW 700 pW 7596 to 9596 RH High power path 500 nW 150 nW 500 nW 1596 to 7596 RH High power path 500 nW 3 nW 500 nW 75 to 95 RH E9300B and E9301B sensors Conditions Zero set Zero drift Measurement noise Low power path 500 nW 150 nW 700 nW 1596 to 7596 RH Low power path 500 nW 4 uW 700 nW 7596 to 9596 RH High power path 500 pW 150 uW 500 uW 1596 to 7596 RH High power path 500 pW 3mW 500 uW 75 to 95 RH E9300H and E9301H sensors Conditions Zero set Zero drift Measurement noise Low power path 5 nW 1 5 nW 7nW 15 to 75 RH Low power path 5 nW 40 nw 7nW 75 to 95 RH High power path 5 yW 1 5 pW 5 uw 15 to 75 RH High power path 5 uW 30 pW 5 yW 75 to 95 RH 1 RH is the abbreviation for relative humidity 2 Within 1 hour after zero set at a constant temperature after a 24 hour warm up of the power meter with power sensor connected 3 The number of averages at 16 for normal mode and 32 for x2 mode at a constant temperature measured over a one minute interval and two standard deviations 17 Calibration factor CF and reflection coefficient Rho Calibration factor and reflection coefficient data are provided at frequency intervals on a data sheet included with the power sensor Thi
16. SH1 AH1 T6 TEO L4 LEO SR1 RL1 PP1 DC1 DTI CO Non volatile memory Battery Lithium polycarbon Monoflouride approximate lifetime 5 years at 25 C Safety Conforms to the following product specifications EN61010 1 1993 TEC 1010 1 1990 A1 CSA C22 2 No 1010 1 1993 EN60825 1 1994 TEC 825 1 1993 Class 1 Low Voltage Directive 72 23 EEC Accessories supplied Power sensor cable 11730A E4418B has one 1 5 meter 5 ft sensor cable E4419B has two 1 5 meter 5 ft sensor cables Power cord One 2 4 meter 7 5 ft cable Power plug matches destination requirements EPM series power meters E4418B Single channel EPM series power meter E4419B Dual channel EPM series power meter Options available Power Option E441xB 001 Mains power and internal rechargeable battery Connectors Option E441xB 002 Parallel rear panel sensor input connector s and front panel reference calibrator connector Option E441xB 003 Parallel rear panel sensor input connectors and rear panel reference calibrator con nector Calibration documentation Option E441xB A6J ANSI Z540 compli ant calibration test data with mea surement uncertainties Documentation A hard copy and CD version of the English language User s Guide and Programming Guide is provided with the EPM power meter as standard A selection can be made to delete the hard copy Option E441xB 0BO Delete manual set 1 Only for EPM series power meter
17. hem successfully Every instrument and system we sell has a global warranty Support is available for at least five years beyond the production life of the product Two concepts underlie Agilent s overall support policy Our Promise and Your Advantage Our Promise Our Promise means your Agilent test and measurement equipment will meet its advertised performance and functionality When you are choosing new equipment we will help you with product information including realistic performance specifica tions and practical recommendations from experienced test engineers When you use Agilent equipment we can verify that it works properly help with product operation and provide basic measurement assistance for the use of specified capabilities at no extra cost upon request Many self help tools are avail able Your Advantage Your Advantage means that Agilent offers a wide range of additional expert test and measurement services which you can purchase according to your unique tech nical and business needs Solve problems efficiently and gain a competitive edge by contracting with us for calibration extra cost upgrades out of warranty repairs and onsite education and training as well as design system integration project management and other professional engineering services Experienced Agilent engineers and technicians worldwide can help you maximize your productivity opti mize the return on investment of your Agilent instruments and
18. igh power path 10 to 20 dBm A suffix sensors 20 to 44 dBm B suffix sensors and 0 to 30 dBm H suffix sensors Low power path 60 to 10 dBm A suffix sensors 30 to 20 dBm B suffix sensors and 50 to 0 dBm H suffix sensors Some specifications are detailed for an individual measurement path Table 9 Wide dynamic range 60 to 20 dBm sensors Model Frequency range Maximum SWR 25 C 10 C E9300B 10 MHz 18 0 GHz 10 MHz to 30 GHz 1 15 30 MHz to 2 GHz 1 13 2 GHz to 14 GHz 1 19 14 GHz to 16 GHz 1 22 16 GHz to 18 GHz 1 26 E9301A 10 MHz 6 0 GHz 10 MHz to 30 GHz 1 15 30 MHz to 2 GHz 1 13 2 GHz to 14 GHz 1 19 E9304A 9 MHz 6 0 GHz 9 kHz to 2 GHz 1 13 2 GHz to 6 GHz 1 19 Wide dynamic range 30 to 44 dBm sensors Model Frequency range Maximum SWR 25 C 10 C E9300B 10 MHz 18 0 GHz 10 MHz to 8 GHz 1 12 8 to 12 4 GHz 1 17 124 to 18 GHz 1 24 E9301B 10 MHz 6 0 GHz 10 MHz to 6 GHz 1 12 Wide dynamic range 50 to 30 dBm sensors Model Frequency range Maximum SWR 25 C 10 C E9300H 10 MHz 18 0 GHz 10 MHz to 8 GHz 1 15 8 to 12 4 GHz 1 25 12 4 to 18 GHz 1 28 E9301H 10 MHz 6 0 GHz 10 MHz to 6 GHz 1 15 Maximum SWR Maximum power Connector 0 55 C type 10 MHz to 30 MHz 1 21 25 dBm average Type N m 30 MHz to 2 GHz 1 15 33 dBm peak 2 GHz to 14 GHz 1 20 lt 10 usec 14 GHz t
19. libration factor uncertainties low power path Frequency Uncertainty 96 Uncertainty 95 25 C 10 C 0 to 55 C 10 MHz to 30 MHz 1 8 2 2 30 MHz to 500 MHz 1 6 2 0 E9304A 9kHz to 500MHz 500 MHz to 1 2 GHz 1 8 2 5 1 2 GHz to 6 GHz 1 7 2 0 6 GHz to 14 GHz 1 8 14 GHz to 18 GHz 2 0 2 0 2 2 Table 13B Calibration factor uncertainties high power path Frequency Uncertainty Uncertainty 25 C 10 C 0 to 55 C 10 MHz to 30 MHz 2 1 4 0 30 MHz to 500 MHz 1 8 3 0 E9304A 9kHz to 500MHz 500 MHz to 1 2 GHz 2 3 4 0 1 2 GHz to 6 GHz 1 8 2 1 6 GHz to 14 GHz 1 9 2 3 14 GHz to 18 GHz 2 2 3 3 18 8480 series power sensors with EPM series power meters The 8480 series power sensors are designed for use with the 435B 436A 437B 438A 70100A E1416A and now the E4418B and E4419B power meters These thermocouple and diode power sensors provide extraordinary accuracy stability and SWR over a wide range of frequencies 100 kHz to 110 GHz and power levels 70 dBm to 44 dBm Table 14 Root sum of squares rss uncertain ty on the calibration factor data printed on the power sensor Freq 8482A 8482B MHz 0 1 1 3 2 8 1 6 1 5 0 3 12 2 8 1 6 14 1 12 2 8 1 6 14 3 12 2 8 1 6 14 10 1 3 2 8 1 6 1 6 30 1 4 2 8 17 1 6 50 O ref 2 7 0 ref 0 ref 100 1 6 3 3 1 9 2 300 1 6 3 3 1 9 2 1000 14 3 3 1 7 2 2000 1 4 3 3 1 7 2 1 4000 1 5 3 1
20. lue Offset Allows power measurements to be offset by 100 dB to 100 dB settable in 0 001dB increments to compensate for external loss or gain Save recall Store up to 10 instru ment states via the save recall menu dBm W Selectable units of either Watts or dBm in absolute power or percent or dB for relative measurements Filter averaging Selectable from 1 to 1024 Auto averaging provides automatic noise compensation Duty cycle Duty cycle valuesbetween 0 001 to 99 999 in 0 001 incre ments can be entered to display a peak power representation of measured power The following equation is used to calculate the displayed peak power value peak power measured power dutycycle Sensor cal tables Selects cal factor versus frequency tables correspond ing to specified sensors 8480 series only Limits High and low limits can be set in the range 150 000 dBm to 230 000 dBm in 0 001 dBm increments Preset default values dBm mode rel off power reference off duty cycle off offset off frequency 50 MHz AUTO average free run AUTO range for E series sensors Display Selectable single and split screen formats are available A quasi analog display is available for peaking measurements The dual channel power meter can simultane ously display any two configurations of A B A B B A A B B A and relative General characteristics Rear panel connectors Recorder outputs Analog 0 to 1 V
21. o 16 GHz 1 23 16 GHz to 18 GHz 1 27 10 MHz to 30 MHz 1 21 25 dBm average Type N m 30 MHz to 2 GHz 1 15 33 dBm peak 2 GHz to 14 GHz 1 20 lt 10 usec 9 kHz to 2 GHz 1 15 25 dBm average Type N m 2 GHz to 6 GHz 1 20 33 dBm peak lt 10 usec Maximum SWR Maximum power Connector 0 55 C type 10 MHz to 8 GHz 1 14 0 35 C 30 W avg Type N m 8 to 12 4 GHz 1 18 35 55 C 25 W avg 12 4 to 18 GHz 1 25 6 GHz 500 W pk gt 6 GHz 125 W pk 500 W mS per pulse 10 MHz to 6 GHz 1 14 0 35 C 30 W avg Type N m 35 55 C 25 W avg 6 GHz 500 W pk 500 W mS per pulse Maximum SWR Maximum power Connector 0 55 C type 10 MHz to 8 GHz 1 17 3 16 W avg Type N m 8 to 12 4 GHz 1 26 100 W pk 12 4 to 18 GHz 1 29 100 W uS per pulse 10 MHz to 6 GHz 1 17 3 16 W avg Type N m 100 W pk 100 W uS per pulse 11 Typical SWR 10 MHz to 18 GHz 25 C 10 C for E9300A and E9301A sensors 12 1 18 1 16 1 14 1 12 SWR 1 1 1 08 ecce 106 Lag uu 104 1 02 001 200 400 600 800 1000 1200 1400 16 00 18 00 Frequency GHz Typical SWR 9kHz to 6 GHz 25 C 10 C for E9304A sensors 1 2 1 15 swr 1 1 a Typical SWR 10 MHz to 18 GHz 25 C 10 C for E9300B and E9301B sensors 1 20 1 15 SWR 1 10 1 00 0 2 4 6 8 10 12 14 16 18 Frequency GHz A Typical SWR 10 MHz to 18 GHz 25 C 10 C for E9300H and E9301H sensors
22. olt 1 kQ output impedance BNC connector E4419B recorder outputs are dedicated to channel A and channel B Remote input output A TTL logic level is output when the measure ment exceeds a predetermined limit TTL inputs are provided to initiate zero and calibration cycles RJ 45 series shielded modular jack assem bly connector TTL Output high 4 8V max low 0 2V max TTL Input high 3 5V min 5V max low 1V max 0 3V min GPIB Allows communication with an external controller RS 232 442 Allows communication with an external RS 232 or RS 422 controller Male plug 9 position D subminiature connector Ground Binding post accepts 4 mm plug or bare wire connection Line power Input voltage range 85 to 264 VAC automatic selection Input frequency range 50 to 440 Hz Power requirement approximately 50 VA 14 Watts for E4418B and E4419B Battery Option 001 operational characteristics The following information describes characteristic performance based at a temperature of 25 C unless other wise noted Typical operating time up to 3 5 hours with LED backlight on up to 5 5 hours with LED backlight off E4418B power meter Charge time 2 hours to charge fully from an empty state 50 minutes charging enables 1 hour of operation with LED backlight on 35 minutes charging enables 1hr operation with LED backlight off Power meter is operational whilst charging Service life to 70 of initial
23. pk 2 4 mm m Net 0 2 kg 0 38 Ib 0 1 GHz to 4 GHz 1 15 30 W us per pulse Shipping 0 5 kg 1 0 Ib 2 GHz to 12 4 GHz 1 20 12 4 GHz to 18 GHz 1 29 18 GHz to 34 GHz 1 37 34 GHz to 40 GHz 1 61 40 GHz to 50 GHz 1 89 R8486D3 26 5 GHz to 40 GHz 26 5 GHz to 40 GHz 1 40 30 dBm to 25 dBm 3 100 mW avg or pk Waveguide flange Net 0 26 kg 0 53 Ib 25 dBm to 20 dBm 596 40 V dc max UG 599 U Shipping 66 kg 1 3 Ib 8486D3 33 GHz to 50 GHz 33 GHz to 50 GHz 1 40 30 dBm to 25 dBm 2396 100 mW avg or pk Waveguide flange Net 0 26 kg 0 53 Ib 25 dBm to 20 dBm 5 40 V dc max UG 383 U Shipping 0 66 kg 1 3 Ib 1 Negligible deviation except for those power ranges noted 2 For pulses greater than 30 W the maximum average power P4 is limited by the energy per pulse E in W us according to P4 30 0 02 E 3 Includes 11708A 30 dB attenuator for calibrating against 0 dBm 50 MHz power reference The 11708A is factory set to 30 dB 0 05 dB at 50 MHz traceable to NIST SWR 1 05 at 50 MHz 21 Agilent Technologies Test and Measurement Support Services and Assistance Agilent Technologies aims to maximize the value you receive while minimizing your risk and problems We strive to ensure that you get the test and measurement capabilities you paid for and obtain the support you need Our extensive support resources and services can help you choose the right Agilent products for your applications and apply t
24. red Example A P 10 P 10 x 1 mW P2106 10x 1 mW P 3 98 mW 3 x 3 98 mW 119 4 uW where P power in Watts and P power in dBm Example B P 10 P 10 x1 mW P 10 35 10 x 1 mW P 316 nW 3 x 316 nW 9 48 nW General Dimensions E4412A 130 mm L x 38 mm W x 30 mm H 5 1 in x 1 5 in x 1 2 in E4413A 102 mm L x 38 mm W x 30 mm H 4 in x 1 5 in x 1 2 in Weight E4412A 0 18 kg 0 4 Ib E4413A 0 18 kg 0 4 Ib Calibration factor CF and reflection coefficient Rho Calibration factor and reflection coefficient data are provided at 1 GHz increments on a data sheet included with the power sensor This data is unique to each sensor If you have more than one sensor match the serial number on the data sheet with the serial number on the power sensor you are using The CF cor rects for the frequency response of the sensor The EPM power meter automatically reads the CF data stored in the sensor and uses it to make the corrections For power lev els greater than 0 dBm add 0 5 dB to the calibration factor uncertainty specification Reflection coefficient Rho relates to the SWR according to the follow ing formula SWR 1 Rho 1 Rho Maximum uncertainties of the CF data are listed in table 8a for the E4412A power sensor and table 8b for the E4413A power sensor The uncertainty analysis for the calibra tion of the sensors was done in accordance with the ISO TAG4 Guide The unce
25. ries CW power sensor specifications Wide dynamic range CW sensors 100 pW to 100 mW 70 dBm to 20 dBm Table 6 Model Frequency range Maximum SWR Maximum power Connector type E4412A 10 MHz 18 GHz 10 MHz to 30 MHz 1 12 200 mW 23 dBm Type N m 30 MHz to 2 Ghz 1 15 2 GHz to 6 Ghz 1 17 6 GHz to 11 Ghz 1 2 11 GHz to 18 Ghz 1 27 E4413A 50 MHz 26 5 GHz 50 MHz to 100 MHz 1 21 200 mW 23 dBm APC 3 5bmm m 100 MHz to 8 Ghz 1 19 8 GHz to 18 Ghz 1 21 18 GHz to 26 5 Ghz 1 26 Applies to sensors with serial prefix US 3848 or greater Table 7 Power Temperature 25 C 5 C Temperature 0 to 55 C 100 pW to 10 mW 3 7 70 dBm to 10 dBm 10 mW to 100 mW 4 5 10 10 dBm to 20 dBm Power Level Being Measured dBm Power Level Used as Reference dBm Figure 1 Relative mode power measurement linearity with EPM series power meter E series CW power sensor at 25 C 5 C typical The chart in figure 1 shows the typi cal uncertainty in making a relative power measurement using the same power meter channel and the same power sensor to obtain the reference and the measured values Example A illustrates a relative gain amplifier measurement Example B illustrates a relative loss insertion loss mea surement This chart assumes negli gible change in frequency and mis match occur when transitioning from the power level used as the reference to the power level being measu
26. rtainty data report ed on the calibration certificate is the expanded uncertainty with a 95 confidence level and a coverage factor of 2 Table 8a E4412A calibration factor uncertainty at 1 mW 0 dBm Frequency Uncertainty 10 MHz 1 8 30 MHz 1 8 50 MHz Reference 100 MHz 1 8 1 0 GHz 1 8 2 0 GHz 24 4 0 GHz 24 6 0 GHz 24 8 0 GHz 24 10 0 GHz 24 11 0 GHz 24 12 0 GHz 24 14 0 GHz 24 16 0 GHz 2 6 18 0 GHz 2 6 Table 8b E4413A calibration factor uncertainty at 1 mW 0 dBm Frequenc Uncertainty 50 MHz Reference 100 MHz 1 8 1 0 GHz 1 8 2 0 GHz 24 4 0 GHz 24 6 0 GHz 24 8 0 GHz 24 10 0 GHz 2 6 11 0 GHz 2 6 12 0 GHz 2 8 14 0 GHz 2 8 16 0 GHz 2 8 17 0 GHz 2 8 18 0 GHz 2 8 20 0 GHz 3 22 0 GHz 3 24 0 GHz 3 26 0 GHz 3 28 0 GHz 3 10 E series E9300 average power sensor specifications The E series E9300 wide dynamic range average power sensors are designed for use with the EPM fami ly of power meters These specifica tions are valid ONLY after proper calibration of the power meter and apply for CW signals unless other wise stated Specifications apply over the tem perature range 0 C to 55 C unless otherwise stated and specifications quoted over the temperature range 25 C 10 C conform to the stan dard environmental test conditions as defined in TIA EIA IS 97 A and TIA EIA IS 98 A 1 The E series E9300 power sensors have two independent measurement paths high and low power paths H
27. s data is unique to each sensor If you have more than one sensor match the serial number on the data sheet with the serial number on the power sensor you are using The CF cor rects for the frequency response of the sensor The EPM series power meter automatically reads the CF data stored in the sensor and uses it to make the corrections Reflection coefficient Rho relates to the SWR according to the follow ing formula SWR 1 Rho 1 Rho Maximum uncertainties of the CF data are listed in tables 13A and 13B As the E series E9300 power sensors have two independent measurement paths high and low power paths there are two calibra tion factor uncertainty tables The uncertainty analysis for the calibra tion of the sensors was done in accordance with the ISO Guide The uncertainty data reported on the calibration certificate is the expanded uncertainty with a 95 confidence level and a coverage factor of 2 General Dimensions Length 130 mm width 38 mm height 30 mm Weight 0 18 kg 0 4 Ibs References 1 TIA is the Telecommunications Industry Association EIA is the Electronic Industries Association TIA EIA IS 97 A is the recommend ed minimum performance standards for base stations supporting dual mode wideband spread spectrum cellular mobile stations TIA EIA IS 98 A is the recommended mini mum performance standards for dual mode wideband spread spectrum cellular mobile stations Table 13A Ca
28. shows the typical uncertainty in making a relative power measurement using the same power meter channel and same power sensor to obtain the reference and the measured values and assumes that negligible change in frequency and mismatch error occur when transitioning from the power level used as the reference to the power level being measured E series E9300 average power sensors Switch point data The E9300 power sensors have two paths a low power path covers 60 to 10 dBm A suffix sensors 30 to 20 dBm B suffix sensors and 50 to 0 dBm H suffix sen sors The high power path covers 10 to 20 dBm A suffix sensors 20 to 44 dBm B suffix sensors and 0 to 30 dBm H suffix sen sors The power meter automatical ly selects the proper power level path To avoid unnecessary switch ing when the power level is near the switch point switching point hysteresis has been added E9300 A suffix sensors example hysteresis causes the low power path to remain selected until approxi mately 9 5 dBm as the power level is increased above this power the high power path will be selected The high power path will remain selected until approximately 10 5 dBm is reached as the signal level decreases below this power the low power path will be selected Switching point linearity Typically lt 40 5 0 02 dB Switching point hysteresis 0 5 dB typical Table 12 E9300A E9301A and E
29. systems and obtain dependable measurement accuracy for the life of those products ina Agilent Email Updates www agilent com find emailupdates Get the latest information on the products and applications you select Agilent T amp M Software and Connectivity Agilent s Test and Measurement software and connectivity products solutions and developer network allows you to take time out of connecting your instruments to your computer with tools based on PC standards so you can focus on your tasks not on your connections Visit www agilent com find connectivity for more information By internet phone or fax get assistance with all your test amp measurement needs Phone or Fax fax 81 426 56 7840 United States Korea tel 800 452 4844 tel 82 2 2004 5004 Canada fax 82 2 2004 5115 tel 877 894 4414 Latin America fax 905 282 6495 tel 305 269 7500 China fax 305 269 7599 tel 800 810 0189 Taiwan fax 800 820 2816 tel 0800 047 866 Europe fax 0800 286 331 tel 31 20 547 2323 Other Asia Pacific Countries fax 31 20 547 2390 tel 65 6375 8100 Japan fax 65 6836 0252 tel 81 426 56 7832 Email tm_asia agilent com Online Assistance www agilent com find assist Product specifications and descriptions in this document subject to change without notice Agilent Technologies Inc 2002 2003 2004 Printed in USA February 1 2004 5965 6382E Agilent Technologies 22
30. the National Institute of Standards and Technology in the USA are signatories to the ComitE International des Poids et Mesures Mutual Recognition Arrangement Further information is available from the Bureau International des Poids et Mesures at http www bipm fr 2 Specification applies to the low power path 1596 to 7596 relative humidity Supplemental characteristics Power reference Frequency 50 MHz nominal SWR 1 05 maximum Connector Type N f 50 Q Measurement speed Three measurement speed modes over the GPIB are available as shown along with the typical maxi mum measurement speed for each mode With the E4418B power meter Normal 20 readings second x2 40 readings second Fast 200 readings second With the E4419B the measurement speed is reduced for example with both channels in FAST mode the typical maximum measurement speed is 100 readings second Fast mode is for E series sensors only Maximum measurement speed is obtained using binary output and in free run trigger mode Zero drift of sensors Sensor depen dent refer to table 2 For E9300 sensors refer to table 12 for complete data Table 2 Model Zero drift Measurement noise 8481A 8482A 8483A 8485A lt 10 nW 110 nW 8487A R8486A 08486A 8481B 8482B lt 10 pW lt 110 pw 8481D 8485D 8487D lt 4 pW lt 45 pW 8481H 8482H lt 1 W 10 pW R8486D 08486D lt 6 pW lt 65 pW V8486A W8486A 40 nW 45

E4412A - TRS RenTelco

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