Page 1 Hewlett-Packard nel campo di Test & Misura, Semiconduttori, ed Analisi Chimica sono ora diventate parte di Agilent Technologies. Al fine di ridurre il rischio di confusione, l'unica modifica effettuata sui numeri di prodotto e sui nomi ha riguardato il prefisso con il nome dell'azienda : dove precedentemente compariva "HP XXXX"...
Page 2 マニュアル・チェンジ変更本文中の「HP（YHP）」、または「(横河)ヒューレット・パッカード株式会社」という語句を、「Agilent」、または「アジレント・テクノロジー株式会社」と変更してください。ヒューレット・パッカード社の電子計測、半導体製品、化学分析ビジネス部門は分離独立し、アジレント・テクノロジー社となりました。社名変更に伴うお客様の混乱を避けるため、製品番号の接頭部のみ変更しております。（例: 旧製品名 HP 4294A は、現在 Agilent 4294A として販売いたしております。）...
Page 3 EPM-P Series Peak and Average Power Meters 7UGT U )WKFG...
Page 4 Agilent Technologies merchantability and fitness for a particular further certifies that its calibration purpose. Agilent Technologies shall not be liable measurements are traceable to the United States for errors contained herein or for incidental or National Institute of Standards and Technology, consequential damages in connection with the to the extent allowed by the Institute’s...
Page 5 5CHGV[ 5[ODQNU 5CHGV[ 5[ODQNU The following symbols on the instrument and in the documentation indicate precautions which must be taken to maintain safe operation of the instrument. 6JG +PUVTWEVKQP &QEWOGPVCVKQP 5[ODQN 6JG RTQFWEV KU OCTMGF YKVJ VJKU U[ODQN YJGP KV KU PGEGUUCT[ HQT VJG WUGT VQ TGHGT VQ VJG KPUVTWEVKQPU KP VJG UWRRNKGF FQEWOGPVCVKQP #NVGTPCVKPI EWTTGPV #%...
Page 6 Agilent Technologies assumes no liability for the customer’s failure to comply with these requirements. W A RN I N G This is a Safety Class I instrument (provided with a protective earthing ground, incorporated in the power cord).
Page 7 )GPGTCN 5CHGV[ +PHQTOCVKQP DO NOT operate damaged equipment: Whenever it is possible that the safety protection features built into this product have been impaired, either through physical damage, excessive moisture, or any other reason, REMOVE POWER and do not use the product until safe operation can be verified by service-trained personnel.
Page 8 9GNEQOG 9GNEQOG Welcome to the EPM-P series power meter User’s Guide! Together with the E-series E9320 power sensors, the EPM-P series power meters can measure complex modulation formats such as TDMA, CDMA and W-CDMA. Pre-installed measurement setups for GSM900, EDGE,...
Page 9 &QEWOGPVCVKQP +PHQTOCVKQP &QEWOGPVCVKQP +PHQTOCVKQP As shown in the Installation Guide, this guide is only part of the information supplied. The documentation consists of: • The Installation Guide - Shows you how to check your power meter, switch it on and connect it to an Agilent power sensor. This information is presented in English, French, German, Italian, Japanese, and Spanish languages.
Page 10 &QEWOGPVCVKQP +PHQTOCVKQP 9JCV ;QW NN (KPF KP VJKU )WKFG This User’s Guide shows you how to operate your EPM-P series power meter using the front panel interface to make measurements with the E-series E9320, E-series E9300, E-series 4410, and 8480 series power sensors.
Page 11 %QPVGPVU %QPVGPVU +PVTQFWEVKQP Power Meter and Sensor Capability....... . 20 Specifications .
Page 12 %QPVGPVU Setting the Range ..........73 Scaling the Analog Display .
Page 13 Replacing the Power Line Fuse ........224 Contacting Agilent Technologies ....... . . 226 Before calling Agilent Technologies .
Page 14 %QPVGPVU 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU Introduction ........... . . 234 Power Meter Specifications .
Page 15 (KIWTGU (KIWTGU Figure 1 Reference Calibration Factor Pop Up Window ..41 Figure 2 Rmt I/O Port TTL Inputs......46 Figure 3 Rel Indicator .
Page 16 (KIWTGU Figure 38 E-series E9320 power sensor default Channel Setup. . . 98 Figure 39 Bandwidth Filter Shapes......100 Figure 40 Gates screen .
Page 17 (KIWTGU Figure 81 Wideband CDMA Error of E-series E9300 power sensor versus corrected CW sensor ....166 Figure 82 CDMA (IS-95A): 9Ch Fwd......166 Figure 83 Calibration Factors versus Frequency .
Page 18 (KIWTGU '2/2 7UGT U )WKFG...
Page 19 6CDNGU 6CDNGU Table 1 Power Sensor Connection Requirements ... . 43 Table 2 TTL Input Control Logic......46 Table 3 TTL Inputs Timing Diagram 1 .
Page 20 6CDNGU '2/2 7UGT U )WKFG...
Page 21 9JCV ;QW NN (KPF +P This Chapter introduces you to the front panel and display of the 6JKU %JCRVGT EPM-P series power meters. It contains these sections: • Power Meter and Sensor Capability on page 20 • Conventions Used in this Guide on page 21 •...
Page 22 +PVTQFWEVKQP 2QYGT /GVGT CPF 5GPUQT %CRCDKNKV[ 2QYGT /GVGT CPF 5GPUQT %CRCDKNKV[ Your E4416A or E4417A power meter is compatible with E-series E9320, E-series E9300, E-series E4400, and 8480 series power sensors. However, not all sensor and meter combinations have the same features or capabilities.
Page 23 %QPXGPVKQPU 7UGF KP VJKU )WKFG +PVTQFWEVKQP %QPXGPVKQPU 7UGF KP VJKU )WKFG The following conventions are used throughout this guide. This symbol and text represents a labeled key on the Channel power meter front panel. 5QHVMG[ This symbol and text represents a labeled softkey and is used to indicate you should press the unmarked key beside the displayed text.
Page 24 +PVTQFWEVKQP (TQPV 2CPGN -G[U CPF %QPPGEVKQPU (TQPV 2CPGN -G[U CPF %QPPGEVKQPU This section briefly describes the functions of the front panel keys and connectors. The User’s Guide shows you how to use them in more detail. These keys are located to the left of the display. Function Press this key to switch the meter between on and standby.
Page 25 (TQPV 2CPGN -G[U CPF %QPPGEVKQPU +PVTQFWEVKQP These keys are located along the lower edge of the display. Function Press this key to access general configuration-menus, System such as GPIB address. You can also access some measurement configuration-menus. The measurement screen remains visible. Press this key to access the channel configuration Channel tables and menus.
Page 26 +PVTQFWEVKQP (TQPV 2CPGN -G[U CPF %QPPGEVKQPU These keys are all associated with the menu labels and data entry. They are located to the right of the display. Function Press this key to access the next pages of a menu. For More QH example,...
Page 27 (TQPV 2CPGN -G[U CPF %QPPGEVKQPU +PVTQFWEVKQP These keys and connectors are associated with the measurement channels and are located on the right-hand side of the front panel. Function Press this key to access the input frequency, and Frequency Cal Fac sensor calibration factor menus.
Page 28 +PVTQFWEVKQP 6JG &KURNC[ .C[QWV 6JG &KURNC[ .C[QWV The following figure details the display layout when the two windows are configured in dual numeric mode. Other display formats are available by Meas &KUR 6[RG pressing Display 1 The status reporting line displays five fields, three associated with either GPIB, RS232 or RS422 status and two associated with error and warning conditions.
Page 29 6JG &KURNC[ .C[QWV +PVTQFWEVKQP 2 There are two measurement windows. This is the upper measurement window. The shading around the window indicates it has been selected (using the , or keys). With numeric measurement results you can choose either two rectangular windows, a single enlarged window, or a full screen display by pressing The display style is applied to the currently selected window or measurement line.
Page 30 +PVTQFWEVKQP 6JG &KURNC[ .C[QWV 9 This window is configured to show a single numeric display. 10 This window is configured to show an analog meter which displays the measurement result and the meter scaling. 11 This field displays the number of pages in the current menu. For example, QH indicates that there are two pages in the menu and the More first page is currently displayed.
Page 31 6JG &KURNC[ .C[QWV +PVTQFWEVKQP 13 This field displays the menu title. For example, when the power meter is initially switched on the %QPVTCUV menu is displayed, and if for Zero , the <GTQ%CN menu is displayed. example, you press 14 This field indicates the measurement result is out with any configured upper or lower limits.
Page 32 +PVTQFWEVKQP 6JG &KURNC[ .C[QWV N O T E The following trace displays are only available when an E-series E9320 power sensor is connected. 20 This window is configured to show a trace display. This is only available with an E-series E9320 power sensor connected. The captured trace and scaling are displayed.
Page 33 6JG &KURNC[ .C[QWV +PVTQFWEVKQP This display shows the *DWH &WUO menu and associated tables and markers. The *DWH &WUO screen is accessed by pressing )CVG %QPVTQN from the 7UDFH &WUO menu or by pressing )CVG %QPVTQN from the *DWHV menu. )CVG 22 Pressing scrolls through the 4 gates available for each channel.
Page 34 +PVTQFWEVKQP 6JG &KURNC[ .C[QWV 5GNGEV 6I&GN 26 Pressing hides the gate markers and displays the trigger marker(s). indicates when the trigger event occurs, whilst shows the delayed trigger point. When the two points coincide only the delayed trigger is shown. In the example display, the appears ahead of the as a trigger delay...
Page 35 6JG &KURNC[ .C[QWV +PVTQFWEVKQP The 7UDFH &WUO screen is accessed by pressing 6TCEG %QPVTQN from the *DWH &WUO menu or by pressing 6TCEG %QPVTQN from the 7UDFH 6HWXS menu. )CVG 27 Pressing scrolls through the 4 gates available for each channel. The selected gate number is repeated in the upper left corner of the window.
Page 36 +PVTQFWEVKQP 9KPFQY 5[ODQNU 9KPFQY 5[ODQNU There are a number of different graphic symbols and pop up windows that can occur on the power meter display. These can occur for a variety of reasons such as when: • an error or warning occurs. •...
Page 37 9KPFQY 5[ODQNU +PVTQFWEVKQP 9CKV 5[ODQN The wait symbol is displayed when the power meter is carrying out a procedure but no action is required from you. The symbol appears in a pop up window. It may appear, for example, during, zeroing or calibration. QH /CP[ 'PVT[ 2QRWR This pop up window is displayed when you are required to select an...
Page 38 +PVTQFWEVKQP 9KPFQY 5[ODQNU '2/2 7UGT U )WKFG...
Page 39 )GPGTCN 2QYGT /GVGT (WPEVKQPU 9JCV ;QW NN (KPF KP This chapter describes the general operation of the EPM-P series 6JKU %JCRVGT power meters. It contains the following sections: • Zeroing and Calibrating on page 38 • Setting the Units of Measurement on page 49 •...
Page 40 )GPGTCN 2QYGT /GVGT (WPEVKQPU <GTQKPI CPF %CNKDTCVKPI <GTQKPI CPF %CNKDTCVKPI This section describes how to zero and calibrate the power meter and sensor combination. You should always zero the power meter prior to calibrating it. <GTQKPI Zeroing adjusts the power meter for a zero power reading with no power applied to the power sensor.
Page 41 <GTQKPI CPF %CNKDTCVKPI )GPGTCN 2QYGT /GVGT (WPEVKQPU During calibration the wait symbol is displayed. Offset, relative and duty cycle settings are ignored during calibration. Some power sensors require adaptors or attenuator pads to enable connection to the POWER REF output. Refer to Table 1 on page 43 for details.
Page 42 )GPGTCN 2QYGT /GVGT (WPEVKQPU <GTQKPI CPF %CNKDTCVKPI %CNKDTCVKQP YKVJ '5GTKGU 2QYGT 5GPUQTU This section describes the calibration procedure for E-series power sensors. The power meter identifies that an E-series power sensor is connected and automatically downloads the calibration table. Since there 4GH %( is no requirement to enter any calibration factors the channel %CN (CE...
Page 43 <GTQKPI CPF %CNKDTCVKPI )GPGTCN 2QYGT /GVGT (WPEVKQPU %CNKDTCVKQP YKVJ 5GTKGU 2QYGT 5GPUQTU This section describes the calibration procedure for 8480 series power sensors. The reference calibration factor is entered manually. NO TE For most 8480 series sensors the correct (A type or D type) linearity correction table is automatically selected.
Page 44 )GPGTCN 2QYGT /GVGT (WPEVKQPU <GTQKPI CPF %CNKDTCVKPI <GTQ 6 Press More and the channel softkey to zero the channel. The <GTQKPI message and wait symbol are displayed. 7 Connect the power sensor to the POWER REF output. 8 Press the channel softkey to start the calibration routine.
Page 45 <GTQKPI CPF %CNKDTCVKPI )GPGTCN 2QYGT /GVGT (WPEVKQPU 6CDNG 2QYGT 5GPUQT %QPPGEVKQP 4GSWKTGOGPVU 5GPUQT %QPPGEVKQP 4GSWKTGOGPVU '# 6JGUG RQYGT UGPUQTU EQPPGEV FKTGEVN[ VQ VJG 219'4 4'( '# '# '# '# '# '# 6JGUG RQYGT UGPUQTU EQPPGEV FKTGEVN[ VQ VJG 219'4 4'( '* '# '*...
Page 46 )GPGTCN 2QYGT /GVGT (WPEVKQPU <GTQKPI CPF %CNKDTCVKPI 5GPUQT %QPPGEVKQP 4GSWKTGOGPVU 6JKU RQYGT UGPUQT TGSWKTGU CP #2% H VQ Ω O # 06[RG CFCRVGT VQ EQPPGEV VQ VJG 219'4 4'(4GOQXG VJKU CFCRVGT DGHQTG OCMKPI OGCUWTGOGPVU & 2TKQT VQ ECNKDTCVKQP CP #IKNGPV # F$ TGHGTGPEG CVVGPWCVQT CPF CP #2% H VQ Ω...
Page 47 <GTQKPI CPF %CNKDTCVKPI )GPGTCN 2QYGT /GVGT (WPEVKQPU <GTQ%CN .QEMQWV The Zero/Cal Lockout facility can help you make sure that a measurement cannot be made until the power meter/sensor combination has been zeroed and calibrated. When the Zero/Cal Lockout facility is enabled and a sensor is first 2NGCUG <GTQ CPF %CN connected, the message is displayed.
Page 48 )GPGTCN 2QYGT /GVGT (WPEVKQPU <GTQKPI CPF %CNKDTCVKPI <GTQKPI CPF %CNKDTCVKPI 7UKPI 66. +PRWVU You can use the TTL inputs on the rear panel Rmt I/O port to initiate zero and calibration cycles on the power meter. The connector is an RJ-45 series shielded modular jack with the TTL input pins connected as shown in Figure 2.
Page 49 <GTQKPI CPF %CNKDTCVKPI )GPGTCN 2QYGT /GVGT (WPEVKQPU 6CDNG 66. +PRWVU 6KOKPI &KCITCO 6KOKPI QH \GTQECN KPRWVU HQT EQPFKVKQPU CPF ,QSXW 2SHUDWLRQ 6KOG &GUETKRVKQP 8CNWG /KPKOWO YKFVJ QH KPRWV OU 6KOG DGVYGGP KPRWV FGVGEVKQP CPF /CZ OU V[RKECN UVCTV QH \GTQECN E[ENG 6JKU KU /KP OU...
Page 50 )GPGTCN 2QYGT /GVGT (WPEVKQPU <GTQKPI CPF %CNKDTCVKPI 6CDNG 66. +PRWVU 6KOKPI &KCITCO 6KOKPI QH \GTQECN KPRWVU HQT EQPFKVKQP ,QSXWV 2SHUDWLRQ 6KOG &GUETKRVKQP 8CNWG /CZKOWO VKOG DGVYGGP KPRWVU IQKPI NQY OU /KPKOWO QXGTNCR QH NQY KPRWVU OU 6KOG DGVYGGP KPRWV FGVGEVKQP CPF UVCTV QH \GTQECN E[ENG 6JKU KU FGVGTOKPGF D[...
Page 51 5GVVKPI VJG 7PKVU QH /GCUWTGOGPV )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI VJG 7PKVU QH /GCUWTGOGPV The 7PKVU menu is used to select the measurement units for the currently selected window. These can either be logarithmic (dBm or dB) or linear Preset (Watt or %) units.
Page 52 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI VJG 7PKVU QH /GCUWTGOGPV 5GNGEVKPI 7PKVU QH /GCUWTGOGPV HTQO VJG 5QHVMG[U In some menus you are required to enter the units of measurement for power. In some cases, due to the wide power range available, the following menu is displayed: Prev %CPEGN...
Page 53 5GVVKPI VJG 4GUQNWVKQP )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI VJG 4GUQNWVKQP The resolution of each of the power meter’s windows can be set to four different levels (1, 2, 3 or 4). These four levels represent: • 1, 0.1, 0.01, 0.001 dB respectively if the measurement suffix is dBm or •...
Page 54 )GPGTCN 2QYGT /GVGT (WPEVKQPU /CMKPI 4GNCVKXG /GCUWTGOGPVU /CMKPI 4GNCVKXG /GCUWTGOGPVU Relative mode enables comparison of a measurement result to a reference value. The relative reading, or difference, can be displayed in either dB or % terms. When the measurement result is displayed in % a prefix multiplier may be shown.
Page 55 5GVVKPI 1HHUGVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI 1HHUGVU The power meter can be configured to compensate for a signal loss or gain in your test setup. The power meter allows you to apply offsets at three different points in the measurement path as shown in Figure 4. Window Functions Channel Functions Upper Window...
Page 56 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI 1HHUGVU To enter a channel offset: Channel to display the %JCPPGN 5GVWR screen. Confirm the 1 Press %JCPPGN %J required channel setup is displayed. Press to change channel if required. keys to highlight the 1HHUGV setting. 2 Use the %JCPIG 3 Press...
Page 57 5GVVKPI 1HHUGVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI &KURNC[ 1HHUGVU This gain or loss is applied to the measured power after any channel offsets or mathematical functions have been included. Offsets are entered in dB. The allowable range of values is -100 dB to +100 dB.
Page 58 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI 1HHUGVU If either a channel or a display offset is set, is displayed. (KIWTG 1HHUGV CRRNKGF N O T E symbol is not displayed when the associated measurement is displayed in Dual Numeric, Trace, or Analog format. The display offset is a function of the window.
Page 59 5GVVKPI 1HHUGVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI (TGSWGPE[ &GRGPFGPV 1HHUGVU Frequency dependent offset tables provide a quick and convenient method of compensating for frequency related changes in the response of your test system. Note that when selected, frequency dependent offset corrections are applied IN ADDITION to any correction for sensor frequency response.
Page 60 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI 1HHUGVU 5GNGEVKPI C (TGSWGPE[ &GRGPFGPV 1HHUGV 6CDNG System You can select a frequency dependent offset table from the Channel . The 5VCVG column indicates if any frequency menu or the dependent offset tables are currently selected. The 1HHUGV 6DNU screen is shown in Figure 8.
Page 61 5GVVKPI 1HHUGVU )GPGTCN 2QYGT /GVGT (WPEVKQPU &QPG 4 Press to complete the selection of the offset table. (KIWTG (TGSWGPE[ &GRGPFGPV 1HHUGV 6CDNG UGNGEVGF &QPG 5 Press again to display the measurement screen. Frequency 6 Press . The current setting of the frequency is displayed under Cal Fac (TGS the channel...
Page 62 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI 1HHUGVU (KIWTG (TGSWGPE[ &GRGPFGPV 1HHUGV %QPHKIWTGF N O T E If the measurement frequency does not correspond directly to a frequency in the sensor calibration table (if selected) and the frequency dependent offset table being used, the power meter calculates the calibration factor and offset using linear interpolation.
Page 63 5GVVKPI 1HHUGVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 'FKVKPI (TGSWGPE[ &GRGPFGPV 1HHUGV 6CDNGU There are ten frequency dependent offset tables named CUSTOM_A through CUSTOM_J. They do not contain any data when the power meter is shipped from the factory. You cannot delete any of the 10 existing frequency dependent offset tables or create any additional tables.
Page 64 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI 1HHUGVU 'PVGT 4 Press to complete the entry. N O T E A frequency in the range of 0.001 MHz to 999.999 GHz can be entered. A calibration factor in the range of 1% to 150% can be entered. The following rules apply to naming sensor calibration tables: –...
Page 65 5GVVKPI 1HHUGVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 7 Enter the offset using the keys. Complete the entry by pressing the key. Continue adding/editing values until you have entered all the data you require. &QPG 8 When you have finished editing the table press to save the table.
Page 66 Figure 12 shows the typical the number of readings averaged for each range and resolution when the power meter is in auto filter mode and is set to normal speed mode. The EPM-P series power meters recognize different sensor types when they are connected and configure suitable averaging automatically.
Page 67 5GVVKPI #XGTCIKPI )GPGTCN 2QYGT /GVGT (WPEVKQPU Resolution is a measurement display function and not a channel function. In the case where a channel is set up in both the upper and lower window and the resolution settings are different, the highest resolution setting is taken to calculate the averaging number.
Page 68 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5VGR &GVGEVKQP 5VGR &GVGEVKQP To reduce the filter settling time after a significant step in the measured power the filter can be set to re-initialize upon detection of a step increase/decrease in the measured power. Step detection can be set in both manual and automatic filter modes.
Page 69 5GVVKPI /GCUWTGOGPV .KOKVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI /GCUWTGOGPV .KOKVU You can configure the power meter to detect when a measurement is outwith a predefined upper and/or lower limit value. Limits are windows or measurement display line based and can be applied to power, ratio or difference measurements.
Page 70 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI /GCUWTGOGPV .KOKVU #ORNKVWFG (CKN F$O F$O (CKN (TGSWGPE[ (KIWTG .KOKVU %JGEMKPI 4GUWNVU 5GVVKPI .KOKVU The power meter can be configured to verify the current measurement in any measurement line against predefined upper and/or lower limit values. The range of values that can be set for the upper and lower limits and the default values depends on the measurement units in the currently selected measurement line - see Table 7...
Page 71 5GVVKPI /GCUWTGOGPV .KOKVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 2TQEGFWTG Set the limits as follows: Meas .KOKVU 1 Press . The current setting of the maximum and Setup minimum limits for the selected measurement line are displayed under softkeys respectively. 2 Use the , and keys to select the measurement line you want to configure.
Page 72 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI /GCUWTGOGPV .KOKVU 66. QWVRWVU The limits can also be set to output a TTL logic level at the rear panel Rmt I/O port when the predefined limits are exceeded. You can switch the rear panel TTL outputs on or off; set the TTL output level to active high or low;...
Page 73 5GVVKPI /GCUWTGOGPV .KOKVU )GPGTCN 2QYGT /GVGT (WPEVKQPU 66. 1WVRWV 3 Press (KIWTG 66. 1WVRWV 2QRWR 4 Use the , and keys to select TTL Output line 1, 2, or Off. Press 'PVGT to confirm your choice. The new setting appears under the 66.
Page 74 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI /GCUWTGOGPV .KOKVU 6 You can choose a high or low level TTL output to represent a limits (CKN 12 *KIJ failure. Press to select to set a logical ‘1’ or logical ‘0’ for a limits failure. %JGEMKPI HQT .KOKV (CKNWTGU Limit failures are displayed in the appropriate field in the measurement window on the power meter’s display as shown in Figure 21.
Page 75 5GVVKPI VJG 4CPIG )GPGTCN 2QYGT /GVGT (WPEVKQPU 5GVVKPI VJG 4CPIG The power meter has no internal ranges. The only ranges that can be set are those of the E-series power sensors. With an E-series power sensor the range can be set either automatically or manually. There are two manual settings, .19'4 and 722'4 .
Page 76 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5ECNKPI VJG #PCNQI &KURNC[ 5ECNKPI VJG #PCNQI &KURNC[ #PCNQI Configure a measurement displayed in format as follows: Meas More 1. Press Display 2. Use the , or keys to select the analog measurement window. #PNI /VT 5ECNKPI 3.
Page 77 5ECNKPI VJG #PCNQI &KURNC[ )GPGTCN 2QYGT /GVGT (WPEVKQPU 5. Similarly, press and use the keys to configure the required value in the /GVGT /KPKOWO pop-up window. Press , or , to complete the entry. (KIWTG /GVGT /KPKOWO 2QRWR 6 +2 If you have selected linear scaling for the analog measurement and the units you require are outwith the range of the displayed menu, an additional menu is available.
Page 78 )GPGTCN 2QYGT /GVGT (WPEVKQPU 4GEQTFGT 1WVRWV 4GEQTFGT 1WVRWV The rear panel Recorder Output connectors (A and B) produce a dc voltage that corresponds to the power level in Watts of the channel, depending on the measurement mode. This dc voltage ranges from 0 to +1 Vdc.
Page 79 4GEQTFGT 1WVRWV )GPGTCN 2QYGT /GVGT (WPEVKQPU (KIWTG 4GEQTFGT /CZKOWO 2QRWR /KP 2QYGT 4 Similarly, press and use the , and keys to enter the power level you want to generate a 0 V output in the 4GEQTFGT /KPKOWO Pop-up. Press F$O O9 , or , to...
Page 80 )GPGTCN 2QYGT /GVGT (WPEVKQPU 4GEQTFGT 1WVRWV 6+ 2 If you have selected linear scaling for the analog measurement and the units you require are outwith the range of the displayed menu, an additional menu is available. When the pop-up is displayed, you can press More to access the increment/decrement multiplier menu.
Page 81 5CXKPI CPF 4GECNNKPI 2QYGT /GVGT %QPHKIWTCVKQPU )GPGTCN 2QYGT /GVGT (WPEVKQPU 5CXKPI CPF 4GECNNKPI 2QYGT /GVGT %QPHKIWTCVKQPU To reduce repeated setup sequences, up to ten power meter configurations can be stored in non-volatile memory. The save/recall functions are part of the 5[U+PRWVU menu, accessed by System pressing the key.
Page 82 )GPGTCN 2QYGT /GVGT (WPEVKQPU 5CXKPI CPF 4GECNNKPI 2QYGT /GVGT %QPHKIWTCVKQPU %QPHKTO 3 The power meter prompts you to press to proceed. (KIWTG 5CXG 2QRWR If you need to modify a name: System 5CXG4GECNN 4 If you have not already done so, press 5 Use the keys to select the required register and press 'FKV 0COG...
Page 83 5CXKPI CPF 4GECNNKPI 2QYGT /GVGT %QPHKIWTCVKQPU )GPGTCN 2QYGT /GVGT (WPEVKQPU %QPHKTO 3 Press (KIWTG 4GECNN 2QRWR '2/2 7UGT U )WKFG...
Page 84 )GPGTCN 2QYGT /GVGT (WPEVKQPU /GCUWTKPI 2WNUGF 5KIPCNU /GCUWTKPI 2WNUGF 5KIPCNU 6+ 2 The E-series E9320 power sensors are best suited for peak and pulse power measurement. However, the E-series E9300 or 8480 series power sensors can be used to measure the power of a pulsed signal. The measurement result is a mathematical representation of the pulse power rather than an actual measurement (assumes constant peak power).
Page 85 /GCUWTKPI 2WNUGF 5KIPCNU )GPGTCN 2QYGT /GVGT (WPEVKQPU 2TQEGFWTG Set the duty cycle as follows: Channel 1 Press . Select the channel you want to configure. The current setting of the duty cycle is displayed in the channel setup table. 2 Use the , and keys to select the duty cycle setting and to select 1P .
Page 86 )GPGTCN 2QYGT /GVGT (WPEVKQPU /GCUWTKPI 2WNUGF 5KIPCNU 4 Again use the , and keys to select and change the values as required. Complete the entry by pressing (KIWTG &WV[ %[ENG 1P &QPG 5 Press N O T E Pulse power averages out any aberrations in the pulse such as overshooting or ringing.
Page 87 2TGUGVVKPI VJG 2QYGT /GVGT )GPGTCN 2QYGT /GVGT (WPEVKQPU 2TGUGVVKPI VJG 2QYGT /GVGT This section details the power meter’s preset conditions. The GPIB address, the data stored in the sensor calibration tables, and Preset the zeroing and calibration data are not affected by a (Preset).
Page 88 )GPGTCN 2QYGT /GVGT (WPEVKQPU 2TGUGVVKPI VJG 2QYGT /GVGT 5GPUQT /QFG Is active and set to 0QTOCN mode only when an Channel E-series E9320A sensor is connected, otherwise inactive and greyed out in #8) QPN[ setting. 4CPIG Is active and set to #WVQ only when an E-series E9320A or E-series E9300 sensor is connected, otherwise inactive and greyed out in #WVQ setting.
Page 89 2TGUGVVKPI VJG 2QYGT /GVGT )GPGTCN 2QYGT /GVGT (WPEVKQPU All Trigger configurations are inactive and greyed out unless an E-series Trigger E9320A power sensor is connected. Is set to (TGG 4WP . #ESP Is set to 4WP . 5VQR 4WP Is set to +PV . 5QWTEG Is set to #WVQ.XN .
Page 90 )GPGTCN 2QYGT /GVGT (WPEVKQPU 2TGUGVVKPI VJG 2QYGT /GVGT Upper window is set to 5KPING 0WOGTKE and the Lower &KUR 6[RG Meas Display window to #PCNQI . Is set to . 4GUQNWVKQP Is set to F$O . 66. 1WVRWV (TGS Is only available when an E-series power sensor is Frequency Cal Fac...
Page 91 9JCV ;QW NN (KPF +P This Chapter shows you how to use E-series E9320 power sensors 6JKU %JCRVGT with your EPM-P series power meter. It contains the following sections: • Introduction on page 90 • Power Meter Configuration on page 92 •...
Page 92 For a power meter it refers to the output of the sensor diodes in normal mode. In normal mode the EPM-P series power meters and E-series E9320 power sensors continuously sample the RF signal at a 20 mega-samples per second rate.
Page 93 +PVTQFWEVKQP 7UKPI '5GTKGU ' 2QYGT 5GPUQTU NO TE Maximum dynamic range is related to the maximum sensor bandwidth. Please refer to the documentation supplied with your E-series E9320 power sensor for specification information. '2/2 7UGT U )WKFG...
Page 94 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2QYGT /GVGT %QPHKIWTCVKQP 2QYGT /GVGT %QPHKIWTCVKQP The EPM-P series power meters automatically recognize an E-series E9320 power sensor when it is connected. The sensor calibration data, characterizing the sensor output versus input power, frequency, and temperature, is automatically read by the power meter.
Page 95 /GCUWTGOGPV /GVJQF 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV /GVJQF The E4416A meter and E-series E9320 power sensors continuously sample the RF signal at a 20 MHz rate. Similarly, the E4417A samples both channels at the same rate. Various trigger methods enable the measurement of continuously modulated signals or single events.
Page 96 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV /GVJQF /GCUWTGOGPV &KURNC[ Average, peak, and peak-to-average ratio measurements are made within each gate period generating 12 possible measurement results per channel as shown in Figure 37. Gates 1 to 4 2GCM @qqpÂ #XGTCIG Gate 1 2MVQ#XI @qqpÂ...
Page 97 /GCUWTGOGPV /GVJQF 7UKPI '5GTKGU ' 2QYGT 5GPUQTU Measurement Feeds …u€sxqÂ„Âiyhu€qp 2GCM Su€sxq @qqpÂ #XGTCIG @qqpÂ@qqpÂ Ag†qÂ 7yhu€qp 2MVQ#XI @qqpÂ @qqpÂ@qqpÂ 2GCM Su€sxq @qqpÂ @qqpÂ@qqpÂ #XGTCIG Ag†qÂ 7yhu€qp 2MVQ#XI @qqpÂ @qqpÂ@qqpÂ Su€sxq 2GCM @qqpÂ @qqpÂ@qqpÂ #XGTCIG Ag†qÂ! 7yhu€qp @qqpÂ 2MVQ#XI @qqpÂ@qqpÂ 2GCM Su€sxq @qqpÂ...
Page 98 7UKPI '5GTKGU ' 2QYGT 5GPUQTU %QPHKIWTKPI C 2GCM 2QYGT /GCUWTGOGPV %QPHKIWTKPI C 2GCM 2QYGT /GCUWTGOGPV While the EPM-P may at first seem complex, configuring a measurement and displaying the results are quickly achieved using trace markers or by following a step-by-step process of numeric data entry. Before configuring the measurements, you should have some information about the signal you want to measure.
Page 99 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 5GVVKPI 7R 7UKPI &CVC 'PVT[ Using the data entry method, the following steps are required to set-up one or several measurements. 1 Channel Setup - choose the sensor mode and range, configure filtering, averaging, bandwidth, and the RF frequency.
Page 100 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 5VGR 6JG %JCPPGN 5GVWR Channel • Press The %JCPPGN 5GVWR screen is displayed. Select the channel you want to configure and use the , and keys to select any parameters %JCPIG you want to change.
Page 101 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 8KFGQ $9 set to 1HH , 8 µs using *KIJ , /GF , and .QY settings, may impair your measurement. By using the upper or lower settings to hold the sensor in a specific range, the switching delay is removed.
Page 102 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU trace and reduce apparent noise. The measurement requires a continuously repeating signal. Increasing the value of the filter reduces noise but increases the time required to make the measurement. 8KFGQ $9 Select a value close to or greater than that of the modulating signal bandwidth.
Page 103 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU with the E9323A and E9327A power sensors. Table 8 on page 90 lists all the bandwidth settings. Selecting a bandwidth only slightly higher than required by your signal can help reduce noise and improve accuracy on peak measurements.
Page 104 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 5VGR 6JG )CVG 5GVWR )CVGU • Press The %JCPPGN )CVGU screen is displayed. (KIWTG )CVGU UETGGP • First select the )CVG 5VCTV value for the gate you want to configure using the , and keys.
Page 105 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU • Select the )CVG .GPIVJ parameter and press %JCPIG . Use the keys to configure the required value in the 6KOG )CVKPI , and .GPIVJ pop-up window. A maximum of 1 second can be entered. (KIWTG 6KOG )CVKPI .GPIVJ RQRWR •...
Page 106 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 5VGR 6JG 6TKIIGT 5GVWR Trigger • Press The 6TKIIGT menu is displayed. (The 6TKIIGT menu is disabled when the 5GPUQT /QFG is set to #8) QPN[ in the %JCPPGN 5GVWR .) label in the 6TKIIGT #ESP The trigger status is also displayed below the...
Page 107 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU #ESP • Press to configure a trigger. 5KPI 6TKI 5KPI 6TKI %QPV 6TKI – Select either is a single shot mode. After triggering, the measurement is halted, the symbol is displayed and 5VQR is highlighted. You can start another to select 4WP , and wait for the 5VQR 4WP measurement by pressing...
Page 108 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 0QTO below the label. When is selected you can choose the RF power level transition used as the trigger. The power meter automatically finds a #WVQ.XN triggering power level transition when selected.
Page 109 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU , and keys to enter the new value. (KIWTG 6TKIIGT &GNC[ 2QRWR Complete the entry by pressing More Press to display the second menu page. Rising edge trigger (KIWTG 6TKIIGT 5GVVKPI /GPW QH 5NQRG 5NQRG...
Page 110 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU This allows stable triggering to be achieved even when a signal has multiple edges, for example, a TDMA signal with non-constant amplitude modulation. Values up to 400 ms can be configured. *QNFQHH To change the setting press and use the...
Page 111 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU only when the input power rises above a level equal to the trigger level plus the configured hysteresis value. *[UVGTGUKU To change the setting press and use the , and keys to enter the new value. (KIWTG 6TKIIGT *[UVGTGUKU 2QRWR Complete the entry by pressing...
Page 112 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 5VGR 6JG &KURNC[ 5GVWR This step requires that you first check the power meter is set up to show the measurement results in the display format you require. Meas &KUR 6[RG Display •...
Page 113 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 5VGR 6JG /GCUWTGOGPV 5GVWR 0WOGTKE (QTOCV 5KPING 0WOGTKE &WCN 0WOGTKE Configure a measurement displayed in format as follows: Meas • Press Setup and use the , or keys to select the measurement window or measurement line you want to configure.
Page 114 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU %QODKPGF to select %1/$ . (WPEVKQP • Press /GCUWTGOGPV %JCPIG • Use the , and keys to assign a measurement type to a gate number as required. Figure 52 shows a Combined Measurement configuration; channel A, gate 1 peak power minus gate 3 peak power, with a 3dB display offset, to be displayed in the upper measurement line of the lower display window.
Page 115 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU #PCNQI (QTOCV #PCNQI Configure a measurement displayed in format as follows: Meas • Press Display • Use the , or keys to select the analog measurement window. #PNI /VT 5ECNKPI • Press (KIWTG #PCNQI FKURNC[ KP NQYGT YKPFQY scale values are shown on the analog display and...
Page 116 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU • Similarly, press and use the keys to configure the required value in the /GVGT /KPKOWO pop-up window. Press , or , to complete the entry. (KIWTG /GVGT /KPKOWO 2QRWR 6+ 2 If you have selected linear scaling for the analog measurement and the units you require are outwith the range of the displayed menu, an...
Page 117 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6TCEG (QTOCV 6TCEG Configure a measurement displayed in format as follows: Meas • Press Display and use the , or keys to select the trace window. Channel 6TCEG 5GVWR • Press to display the Trace Setup menu.
Page 118 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 5GVVKPI 7R 7UKPI 6TCEG /CTMGTU Setting up a measurement using the trace markers requires less information about the signal you are measuring than the data entry method. Similar steps are required but in a different and less ordered manner.
Page 119 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU Loosely follow this process until you are familiar with the trace and marker controls. • Channel - choose the sensor mode and range, configure filtering, averaging, bandwidth, and the RF frequency. •...
Page 120 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU 6TKIIGT The power meter must be in a triggered mode to allow access to the gate and trace control screens. Trigger Press and refer to “Step 3. The Trigger Setup” on page 104 to configure a suitable trigger.
Page 121 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU )CVG )CVGU )CVG %QPVTQN To access the gate control menu press Channel Trace Markers (KIWTG )CVG %QPVTQN /GPW CPF &KURNC[ )CVG )CVG Pressing scrolls through the 4 gates available for each channel.
Page 122 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU N O T E Your chosen trigger point is used as the reference point for the timing of all the measurement gates T rigger Markers (KIWTG 6TKIIGT /CTMGT 0GICVKXG &GNC[ Pressing the hardkeys decreases or increases the trigger delay.
Page 123 6JG 5GV 7R 2TQEGUU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU NO TE Gate and trigger markers are moved one pixel when the keys are pressed and released. They are moved up to 5 pixels at a time when the keys are pressed and held. To reduce the time interval represented by one pixel, decrease the length of the displayed trace.
Page 124 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6JG 5GV 7R 2TQEGUU &KURNC[ Now configure the display to show the measurement results you require Meas by pressing . Refer to “Step 4. The Display Setup” on page 110 for Display more information. 6+ 2 If you choose to configure one of the windows with a trace display, you can quickly re-display the )CVG %VTN screen by pressing (KIWTG ...
Page 125 /GCUWTGOGPV 'ZCORNG 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV 'ZCORNG This measurement example configures the power meter to measure an Enhanced Data for Global Evolution (or Enhanced Data for GSM Evolution) signal. Triggering is achieved using the rising edge of the burst.
Page 126 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV 'ZCORNG After a Preset, 8KFGQ $9 defaults to *KIJ for all sensors. N O T E 5VGR 6JG )CVG 5GVWR Only one gate is to be set up, starting 20 µs after the trigger for a duration of 520 µs.
Page 127 /GCUWTGOGPV 'ZCORNG 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 5VGR 6JG 6TKIIGT 5GVWR The trigger is now configured for a power level of -20 dBm on a rising edge. A trigger hold off is also setup for 4275 µs, disabling the trigger and ensuring the same time slot is measured at the next frame.
Page 128 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV 'ZCORNG 5VGR 6JG &KURNC[ 5GVWR Before configuring the measurement, first setup the display for a dual numeric window and a trace window. Configure the Display as follows: Meas . The &KUR (QTO menu is displayed. 1.
Page 129 /GCUWTGOGPV 'ZCORNG 7UKPI '5GTKGU ' 2QYGT 5GPUQTU Channel 6TCEG 5GVWR 10. Press and setup the parameters as follows: 6CDNG 6TCEG 5GVWR 2CTCOGVGTU 2CTCOGVGT 5GVVKPI F$O − F$O − µ U 5VCTV µ U .GPIVJ (KIWTG /GCUWTGOGPV 'ZCORNG /GCUWTGOGPV &KURNC[ 6 +2 If you require faster measurement speed, set the (KNVGT to /#0 (Channel...
Page 130 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU Pre-installed measurement setups for GSM900, EDGE, NADC, iDEN, Bluetooth, cdmaOne, W-CDMA, and cdma2000 help reduce the time required to measure these common wireless communications formats. Preset They are accessed quickly by pressing the key and using the Local cursor keys to select the required format from the displayed list.
Page 131 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI )5/ Preset The GSM900 configuration is available by pressing and using the Local %QPHKTO keys to select )5/ . Pressing completes the process. The pre-installed setup configures the power meter for an average power measurement in a GSM RF burst.
Page 132 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 6CDNG )5/ %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 6JG '# CPF '# UGPUQTU CTG DGUV UWKVGF CU VJG[ Channel JCXG VJG QRVKOWO F[PCOKE TCPIG CPF NQYNGXGN UVCDKNKV[ KP VJG M*\ DCPFYKFVJ #HVGT C 2TGUGV 8KFGQ $9 FGHCWNVU VQ *KIJ HQT CNN UGPUQTU 5GPUQT /QFG 0QTOCN...
Page 133 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2CTCOGVGT 5GVVKPI #ESP %QPV 6TKI 5QWTEG +PV KPVGTPCN − F$O .GXGN /QFG 0QTOCN 5NQRG TKUKPI µ U &GNC[ µ U *QNFQHH *[UVGTGUKU F$ 1WVRWV 6JG FKURNC[ KU UGVWR HQT C UKPING PWOGTKE YKPFQY CPF C Meas Display VTCEG YKPFQY...
Page 134 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU The maximum power level for the E-series E9320 power sensors is +20 dBm. Attenuation may be required when directly measuring GSM transmitter output. Enter the value of the attenuation as an 1HHUGV Meas /GCU 5GNGEV Setup...
Page 135 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI '&)' Preset The EDGE configuration is available by pressing and using the Local keys to select '&)' . Pressing %QPHKTO completes the process. Enhanced Data for Global Evolution or Enhanced Data for GSM Evolution is an enhancement of the GSM standard.
Page 136 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 6CDNG '&)' %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 6JG '# CPF '# UGPUQTU CTG DGUV UWKVGF CU VJG[ Channel JCXG VJG QRVKOWO F[PCOKE TCPIG CPF NQYNGXGN UVCDKNKV[ KP VJG M*\ DCPFYKFVJ #HVGT C 2TGUGV 8KFGQ $9 FGHCWNVU VQ *KIJ HQT CNN UGPUQTU 5GPUQT /QFG 0QTOCN...
Page 137 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2CTCOGVGT 5GVVKPI 6JG VTKIIGT KU EQPHKIWTGF HQT F$O QP C TKUKPI GFIG # Trigger VTKIIGT JQNF QHH KU CNUQ UGVWR HQT µ U FKUCDNKPI VJG VTKIIGT HQT VKOG UNQVU GPUWTKPI VJG UCOG VKOG UNQV KU OGCUWTGF KP VJG PGZV HTCOG #NUQ VTKIIGT J[UVGTGUKU KU KPENWFGF VQ RTGXGPV UOCNN RQYGT VTCPUKVKQPU FWTKPI VJG DWTUV ECWUKPI TGVTKIIGTKPI...
Page 138 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 6+ 2 If you require faster measurement speed, set the (KNVGT to /#0 (Channel Setup screen) and reduce the filter value. Conversely, if you are measuring low power levels and want to improve the stability of the measurements, increase the filter value.
Page 139 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI 0#&% Preset The NADC configuration is available by pressing and using the Local keys to select 0#&% . Pressing %QPHKTO completes the process. The pre-installed setup configures the power meter for average power measurements of both active time slots in NADC or IS-136 ‘full rate’...
Page 140 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU The display (Figure 71) is configured to show the Gate 1 and Gate 2 average results in the lower window in numeric format, while the upper window shows the power trace starting 0.2 ms before the trigger. (KIWTG 0#&% /GCUWTGOGPV &KURNC[ '2/2 7UGT U )WKFG...
Page 141 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6CDNG 0#&% %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 6JG PCTTQY DCPFYKFVJ QH VJG 0#&% UKIPCN TGSWKTGU Channel QPN[ VJG M*\ DCPFYKFVJ QH VJG '# CPF '# UGPUQTU KP VJG .QY UGVVKPI CPF VJGUG CTG DGUV UWKVGF 1VJGT ' UGPUQTU OC[ DG WUGF KP VJGKT NQYGUV UGVVKPI DWV VJG[ RTQXKFG NGUU F[PCOKE TCPIG CPF NQYNGXGN UVCDKNKV[ #HVGT C 2TGUGV 8KFGQ...
Page 142 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 2CTCOGVGT 5GVVKPI 6JG VTKIIGT KU EQPHKIWTGF HQT C RQYGT NGXGN QH Trigger F$O QP C TKUKPI GFIG # VTKIIGT JQNF QHH KU CNUQ UGVWR HQT OU FKUCDNKPI VJG VTKIIGT HQT VKOG UNQVU GPUWTKPI VJG UCOG VKOG UNQV KU OGCUWTGF GCEJ VKOG #ESP...
Page 143 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU If you require faster measurement speed, set the (KNVGT to /#0 (Channel Setup screen) and reduce the filter value. Conversely, if you are measuring low power levels and want to improve the stability of the measurements, increase the filter value.
Page 144 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU /GCUWTKPI K&'0 Preset The iDEN configuration is available by pressing and using the Local keys to select K&'0 . Pressing %QPHKTO completes the process. The pre-installed setup configures the power meter for average power and the peak-to-average power ratio measurements in one iDEN training and data pulse, and the average power in a 90 ms iDEN frame.
Page 145 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6CDNG K&'0 %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 6JG PCTTQY DCPFYKFVJ QH VJG K&'0 UKIPCN TGSWKTGU Channel QPN[ VJG M*\ DCPFYKFVJ QH VJG '# CPF '# UGPUQTU KP VJG .QY UGVVKPI CPF VJGUG CTG DGUV UWKVGF 1VJGT ' UGPUQTU OC[ DG WUGF KP VJGKT NQYGUV UGVVKPI DWV VJG[ RTQXKFG NGUU F[PCOKE TCPIG CPF NQYNGXGN UVCDKNKV[...
Page 146 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 2CTCOGVGT 5GVVKPI #ESP %QPV 6TKI 5QWTEG +PV KPVGTPCN − F$O .GXGN /QFG 0QTOCN 5NQRG TKUKPI &GNC[ *QNFQHH OU *[UVGTGUKU F$ 1WVRWV 6JG FKURNC[ KU UGVWR HQT C FWCN PWOGTKE YKPFQY CPF Meas Display C UKPING PWOGTKE YKPFQY...
Page 147 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI $NWGVQQVJ Preset The Bluetooth configuration is available by pressing and using the Local %QPHKTO keys to select $NWGVQQVJ . Pressing , and completes the process. The pre-installed setup configures the power meter for peak and average power measurements in a single Bluetooth DH1 data burst.
Page 148 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 6CDNG $NWGVQQVJ %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 6JG '# CPF '# CTG PQV TGEQOOGPFGF Channel FWG VQ NCEM QH DCPFYKFVJ #HVGT C 2TGUGV 8KFGQ $9 FGHCWNVU VQ *KIJ HQT CNN UGPUQTU 5GPUQT /QFG 0QTOCN 4CPIG #761...
Page 149 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2CTCOGVGT 5GVVKPI #ESP %QPV 6TKI 5QWTEG +PV KPVGTPCN − F$O .GXGN /QFG 0QTOCN 5NQRG TKUKPI &GNC[ µ U *QNFQHH *[UVGTGUKU F$ 1WVRWV 6JG FKURNC[ KU UGVWR HQT C FWCN PWOGTKE YKPFQY CPF Meas Display C VTCEG YKPFQY...
Page 150 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU The maximum power level for the E-series E9320 power sensors is +20 dBm. Attenuation may be required when directly measuring transmitter output. Enter the value of the attenuation as an 1HHUGV Meas /GCU 5GNGEV Setup...
Page 151 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI EFOC1PG Preset The cdmaOne configuration is available by pressing and using the Local %QPHKTO keys to select EFOC1PG . Pressing , and completes the process. The pre-installed setup configures the power meter for a continuous measurement on a cdmaOne signal.
Page 152 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 6CDNG EFOC1PG %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 6JG '# CPF '# UGPUQTU CTG DGUV UWKVGF Channel FWG VQ VJGKT /*\ DCPFYKFVJ 6JG '# CPF '# CTG PQV TGEQOOGPFGF FWG VQ VJGKT NCEM QH DCPFYKFVJ #HVGT C 2TGUGV 8KFGQ $9 FGHCWNVU VQ *KIJ HQT CNN UGPUQTU 5GPUQT /QFG...
Page 153 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2CTCOGVGT 5GVVKPI #ESP %QPV 6TKI 5QWTEG +PV KPVGTPCN − F$O .GXGN /QFG #WVQ .GXGN 5NQRG TKUKPI &GNC[ *QNFQHH *[UVGTGUKU F$ 1WVRWV 6JG FKURNC[ KU UGVWR HQT C UKPING PWOGTKE CPF C FWCN Meas Display PWOGTKE YKPFQY...
Page 154 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU /GCUWTKPI 9%&/# Preset The W-CDMA configuration is available by pressing and using the Local %QPHKTO keys to select 9%&/# . Pressing , and completes the process. The pre-installed setup configures the power meter for a continuous power measurement on a W-CDMA signal.
Page 155 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 6CDNG 9%&/# %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 9KVJ /*\ DCPFYKFVJ VJG '# CPF '# Channel UGPUQTU CTG DGUV UWKVGF 6JG '# '# '# CPF '# UGPUQTU CTG PQV TGEQOOGPFGF FWG VQ VJGKT NCEM QH DCPFYKFVJ /*\ TGSWKTGF #HVGT C 2TGUGV 8KFGQ $9 FGHCWNVU VQ *KIJ HQT CNN UGPUQTU 5GPUQT /QFG...
Page 156 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 2CTCOGVGT 5GVVKPI #ESP %QPV 6TKI 5QWTEG +PV KPVGTPCN − F$O .GXGN /QFG #WVQ .GXGN 5NQRG TKUKPI &GNC[ *QNFQHH *[UVGTGUKU F$ 1WVRWV 6JG FKURNC[ KU UGVWR HQT C UKPING PWOGTKE CPF C FWCN Meas Display PWOGTKE YKPFQY...
Page 157 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI EFOC Preset The cdma2000 configuration is available by pressing and using the Local %QPHKTO keys to select EFOC . Pressing , and completes the process. The pre-installed setup configures the power meter for a continuous power measurement on a cdma2000 signal.
Page 158 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 6CDNG EFOC %QPHKIWTCVKQPU 2CTCOGVGT 5GVVKPI 9KVJ /*\ DCPFYKFVJ VJG '# CPF '# Channel UGPUQTU CTG DGUV UWKVGF 6JG '# '# '# CPF '# UGPUQTU CTG PQV TGEQOOGPFGF FWG VQ VJGKT NCEM QH DCPFYKFVJ /*\ TGSWKTGF #HVGT C 2TGUGV 8KFGQ $9 FGHCWNVU VQ *KIJ HQT CNN UGPUQTU 5GPUQT /QFG...
Page 159 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2CTCOGVGT 5GVVKPI #ESP %QPV 6TKI 5QWTEG +PV KPVGTPCN − F$O .GXGN /QFG #WVQ .GXGN 5NQRG TKUKPI &GNC[ *QNFQHH *[UVGTGUKU F$ 1WVRWV 6JG FKURNC[ KU UGVWR HQT C UKPING PWOGTKE CPF C FWCN Meas Display PWOGTKE YKPFQY...
Page 160 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 7UKPI 2TGKPUVCNNGF /GCUWTGOGPV 5GVWRU '2/2 7UGT U )WKFG...
Page 161 9JCV ;QW NN (KPF +P This Chapter shows you how to use E-series E9300 power sensors 6JKU %JCRVGT with your EPM-P series power meter. It contains the following sections: • Introduction on page 160 • Power Meter Configuration on page 161 •...
Page 162 7UKPI '5GTKGU ' 2QYGT 5GPUQTU +PVTQFWEVKQP +PVTQFWEVKQP The E-series E9300 power sensors are true average, wide dynamic range RF microwave power sensors. They are based on a dual sensor diode pair/attenuator/diode pair. This technique ensures the diodes in the selected signal path are kept in their square law region, thus the output current (and voltage) is proportional to the input power.
Page 163 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2QYGT /GVGT %QPHKIWTCVKQP The EPM-P series power meters automatically recognize an E-series E9300 power sensor when it is connected. The sensor calibration data is automatically read by the power meter. The power meter also configures the auto-averaging settings shown in Figure 77 to suit the power sensor characteristics.
Page 164 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 2QYGT /GVGT %QPHKIWTCVKQP &GHCWNV %JCPPGN 5GVWR When an E-series E9300 power sensor is connected the following %JCPPGN 5GVWR is automatically configured. Carrying out a Preset returns the power meter to this configuration. Any changes made to the %JCPPGN 5GVWR are retained after a power cycle.
Page 165 /GCUWTGOGPV #EEWTCE[ 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV #EEWTCE[ Power sensors have small errors in their response over frequency. The response of each sensor is measured during manufacture to determine correction factors. With E-series power sensors, correction factors are held in Electrically Erasable Programmable Read Only Memory (EEPROM) and are downloaded to the power meter automatically.
Page 166 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV #EEWTCE[ 3 Connect the power sensor to the POWER REF output using the connection method specified in Power Sensor Connection Requirements on page 163. 4 Press the channel softkey to start the calibration routine. The %CNKDTCVKPI message and wait symbol are displayed.
Page 167 /GCUWTKPI 5RTGCF 5RGEVTWO CPF /WNVKVQPG 5KIPCNU 7UKPI '5GTKGU ' 2QYGT /GCUWTKPI 5RTGCF 5RGEVTWO CPF /WNVKVQPG 5KIPCNU To achieve high data transfer rates within a given bandwidth, many transmission schemes are based around phase and amplitude (I and Q) modulation. These include CDMA, W-CDMA and digital television. The signals are characterized by their appearance on a spectrum analyzer display —...
Page 168 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI 5RTGCF 5RGEVTWO CPF /WNVKVQPG %&/# 5KIPCN /GCUWTGOGPVU Figure 81 and Figure 82 show typical results obtained when measuring a CDMA signal. In these examples, the error is determined by measuring the source at the amplitude of interest, with and without CDMA modulation, adding attenuation until the difference between the two values stops changing.
Page 169 /GCUWTKPI 5RTGCF 5RGEVTWO CPF /WNVKVQPG 5KIPCNU 7UKPI '5GTKGU ' 2QYGT /WNVKVQPG 5KIPCN /GCUWTGOGPVU In addition to wide dynamic range, the E-series E9300 power sensors also have an exceptionally flat calibration factor versus frequency response as shown in Figure 83. This is ideal for amplifier intermodulation distortion measurements where the components of the two-tone or multitone test signal can be separated by hundreds of MHz.
Page 170 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTKPI 6&/# 5KIPCNU /GCUWTKPI 6&/# 5KIPCNU 2QYGT /GVGT CPF 5GPUQT 1RGTCVKQP The voltages generated by the diode detectors in the power sensor can be very small. Gain and signal conditioning are required to allow accurate measurement.
Page 171 /GCUWTKPI 6&/# 5KIPCNU 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 5 Use to select and change the values as required. 'PVGT Confirm your entry by pressing (You can delete any changes and return to the Channel Setup simply by %CPEGN pressing &QPG 6 Press to complete the procedure.
Page 172 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 'NGEVTQOCIPGVKE %QORCVKDKNKV[ '/% 'NGEVTQOCIPGVKE %QORCVKDKNKV[ '/% /GCUWTGOGPVU The low frequency range of the E9304A make it the ideal choice for making EMC measurements to CISPR (Comite International Special Perturbations Radioelectriques) requirements, and electromagnetic interference (EMI) test applications such as the radiated immunity test (IEC61000-4-3).
Page 173 /GCUWTGOGPV #EEWTCE[ CPF 5RGGF 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV #EEWTCE[ CPF 5RGGF The power meter has no internal ranges. The only ranges you can set are those of the E-series E9300 power sensors (and other E-series power sensors). With an E-series E9300 power sensor the range can be set either automatically or manually.
Page 174 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV #EEWTCE[ CPF 5RGGF 2TQEGFWTG Set the range as follows: Channel to display the %JCPPGN 5GVWR . In addition, on dual 1 Press %JCPPGN channel meters, you may need to press to display the %JCPPGN 5GVWR for the channel you want to use. to highlight the 4CPIG setting.
Page 175 /GCUWTGOGPV #EEWTCE[ CPF 5RGGF 7UKPI '5GTKGU ' 2QYGT 5GPUQTU 5RGGF CPF The same signal also requires that consideration is given to measurement #XGTCIKPI speed. As shown above, in autoranging mode the power meter selects the low power path in the E-series E9300 power sensor. With auto-averaging also configured, minimal filtering is applied.
Page 176 7UKPI '5GTKGU ' 2QYGT 5GPUQTU /GCUWTGOGPV #EEWTCE[ CPF 5RGGF '2/2 7UGT U )WKFG...
Page 177 9JCV ;QW NN (KPF +P This Chapter shows you how to use E-series 4410 power sensors with 6JKU %JCRVGT your EPM-P series power meter. It contains the following sections: • Introduction on page 176 • Power Meter Configuration on page 177...
Page 178 7UKPI '5GTKGU 2QYGT 5GPUQTU +PVTQFWEVKQP +PVTQFWEVKQP The E-series 4410 power sensors are diode based power sensors. They are intended for the measurement of CW microwave power levels in a wide dynamic range from -70 dBm to +20 dBm (100 pW to 100 mW). These are high-speed power sensors, and do not incorporate narrow-bandwidth averaging used in average-power sensors.
Page 179 2QYGT /GVGT %QPHKIWTCVKQP 7UKPI '5GTKGU 2QYGT 5GPUQTU 2QYGT /GVGT %QPHKIWTCVKQP The EPM-P series power meters automatically recognize an E-series 4410 power sensor when it is connected. The sensor calibration data is automatically read by the power meter. Also, the power meter automatically configures the averaging as shown in Figure 84.
Page 180 7UKPI '5GTKGU 2QYGT 5GPUQTU 2QYGT /GVGT %QPHKIWTCVKQP &GHCWNV %JCPPGN 5GVWR When an E-series 4410 power sensor is connected the following &KDQQHO 6HWXS is automatically configured. Carrying out a Preset returns the channel to this configuration. Any changes made to the %JCPPGN 5GVWR are retained through a power cycle.
Page 181 /GCUWTGOGPV #EEWTCE[ 7UKPI '5GTKGU 2QYGT 5GPUQTU /GCUWTGOGPV #EEWTCE[ Power sensors have small errors in their response over frequency. The response of each sensor is measured during manufacture (and during periodic calibration). With E-series power sensors, the resulting frequency compensation information is written into Electrically Eraseable Programmable Read Only Memory (EEPROM).
Page 182 7UKPI '5GTKGU 2QYGT 5GPUQTU /GCUWTGOGPV #EEWTCE[ Now set the frequency of the signal you want to measure. The power meter automatically selects the apporpriate calibration factor. Frequency (TGSWGPE[ (TGS 5 Press and the channel softkey to display the Cal Fac pop up window.
Page 183 This Chapter applies to all Agilent 8480 series power sensors. It 6JKU %JCRVGT shows you how to use the 8480 series power sensors with your EPM-P series power meter. It contains the following sections: • Introduction on page 182 • Power Meter Configuration on page 183 •...
Page 184 7UKPI 5GTKGU 2QYGT 5GPUQTU +PVTQFWEVKQP +PVTQFWEVKQP The 8480 series offers a wide range of both thermocouple and diode based power sensors. Many have very specific applications, for example the 110GHz W8486A or the +44 dBm 8482B. However, they do not have their calibration factors stored in EEPROM, unlike all E-series power sensors, and require that you use default calibration tables or manually enter the required correction factors.
Page 185 2QYGT /GVGT %QPHKIWTCVKQP 7UKPI 5GTKGU 2QYGT 5GPUQTU 2QYGT /GVGT %QPHKIWTCVKQP The EPM-P series power meters automatically recognize an 8480 series power sensor when it is connected. The averaging settings shown in Figure 87 are automatically configured. Resolution Setting Maximum Sensor Power...
Page 186 7UKPI 5GTKGU 2QYGT 5GPUQTU 2QYGT /GVGT %QPHKIWTCVKQP Any changes made to the %JCPPGN 5GVWR are retained after a power cycle. (KIWTG UGTKGU UGPUQT FGHCWNV %JCPPGN 5GVWR '2/2 7UGT U )WKFG...
Page 187 Using calibration factors enables you to achieve improved measurement accuracy. The EPM-P series peak power meters provide two methods of using the calibration factors: – inputting the individual calibration factor for a frequency prior to making the measurement, or –...
Page 188 7UKPI 5GTKGU 2QYGT 5GPUQTU (TGSWGPE[ 5RGEKHKE %CNKDTCVKQP (CEVQTU (TGSWGPE[ 5RGEKHKE %CNKDTCVKQP (CEVQTU This section shows you how to make a measurement using the calibration factor for the frequency of the signal you want to measure. 6+ 2 This method is best suited to making several measurements at one frequency as you need only enter a small amount of data.
Page 189 (TGSWGPE[ 5RGEKHKE %CNKDTCVKQP (CEVQTU 7UKPI 5GTKGU 2QYGT 5GPUQTU 4GH %( 4 If required, change this setting by pressing the channel . The reference calibration factor pop up window is displayed as shown in Figure 89. (KIWTG 4GHGTGPEG %CNKDTCVKQP (CEVQT 2QR 7R 9KPFQY Modify this (see below) as required.
Page 190 7UKPI 5GTKGU 2QYGT 5GPUQTU (TGSWGPE[ 5RGEKHKE %CNKDTCVKQP (CEVQTU %CN (CE 10 If required, change this setting by pressing the channel . The calibration factor pop up window is displayed as shown in Figure 90. (KIWTG %CNKDTCVKQP (CEVQT 2QR 7R 9KPFQY Modify this (see below) as required.
Page 191 (TGSWGPE[ 5RGEKHKE %CNKDTCVKQP (CEVQTU 7UKPI 5GTKGU 2QYGT 5GPUQTU 5KPING 0WOGTKE NO TE When no sensor tables are selected and display mode is chosen, the calibration factor used for the measurement is displayed in the upper window as shown in Figure 91. Calibration Factor (KIWTG %CNKDTCVKQP (CEVQT &KURNC[GF...
Page 192 7UKPI 5GTKGU 2QYGT 5GPUQTU (TGSWGPE[ 5RGEKHKE %CNKDTCVKQP (CEVQTU 5GPUQT %QPPGEVKQP 4GSWKTGOGPVU 4# 6JGUG YCXGIWKFG RQYGT UGPUQTU JCXG VYQ EQPPGEVQTU 7UG 3# VJG 06[RG EQPPGEVQT VQ ECNKDTCVG VJG RQYGT OGVGT 8# 9# 4& 3& $ 6JGUG RQYGT UGPUQTU CTG EQPHKIWTGF YKVJ CP CVVGPWCVQT $ 2TKQT VQ ECNKDTCVKQP VJKU CVVGPWCVQT OWUV DG TGOQXGF 4GRNCEG VJG CVVGPWCVQT DGHQTG OCMKPI OGCUWTGOGPVU...
Page 193 (TGSWGPE[ 5RGEKHKE %CNKDTCVKQP (CEVQTU 7UKPI 5GTKGU 2QYGT 5GPUQTU 'ZCORNG To make a measurement on channel A with a power sensor which has a reference calibration factor of 99.8% and a calibration factor of 97.6% at the measurement frequency. • Disconnect the power sensor from any signal source. 4GH %( Zero •...
Page 194 The EPM-P series power meters are capable of storing 20 sensor calibration tables each containing up to 80 frequency points. The power meter is supplied with a set of 9 predefined sensor calibration tables plus a “100%”...
Page 195 5GPUQT %CNKDTCVKQP 6CDNGU 7UKPI 5GTKGU 2QYGT 5GPUQTU 2TQEGFWTG First select the table for the sensor you are using as follows: System to display the 5GPUQT 6DNU 6CDNGU 5GPUQT %CN 6CDNGU 1 Press screen. The selected sensor table is indicated in the 5VCVG column as shown in Figure 92.
Page 196 7UKPI 5GTKGU 2QYGT 5GPUQTU 5GPUQT %CNKDTCVKQP 6CDNGU Frequency (TGS softkey to display the (TGSWGPE[ 5 Press and the channel Cal Fac pop up window. (KIWTG (TGSWGPE[ 2QR 7R 9KPFQY 6 Use the keys to select and change the digits to match the frequency of the signal you want to measure.
Page 197 5GPUQT %CNKDTCVKQP 6CDNGU 7UKPI 5GTKGU 2QYGT 5GPUQTU Frequency Sensor Table (KIWTG (TGSWGPE[%CNKDTCVKQP 6CDNG &KURNC[ '2/2 7UGT U )WKFG...
Page 198 7UKPI 5GTKGU 2QYGT 5GPUQTU 5GPUQT %CNKDTCVKQP 6CDNGU 'FKVKPI)GPGTCVKPI 5GPUQT %CNKDTCVKQP 6CDNGU To help achieve the best accuracy in your measurement you can enter the values supplied for the sensors you are using by editing the installed sensor calibration tables or by generating your own custom tables. While you cannot delete any of the 20 sensor calibration tables, you can edit or delete their contents.
Page 199 5GPUQT %CNKDTCVKQP 6CDNGU 7UKPI 5GTKGU 2QYGT 5GPUQTU Editing or generating power sensor tables requires the following steps: 1. Identify and select the sensor table you want to edit or create. 2. Rename the table. 3. Edit/enter the frequency and calibration factor data pairs. 4.
Page 200 7UKPI 5GTKGU 2QYGT 5GPUQTU 5GPUQT %CNKDTCVKQP 6CDNGU N O T E A frequency in the range of 0.001 MHz to 999.999 GHz can be entered. A calibration factor in the range of 1% to 150% can be entered. The following rules apply to naming sensor calibration tables: –...
Page 201 5GPUQT %CNKDTCVKQP 6CDNGU 7UKPI 5GTKGU 2QYGT 5GPUQTU +PUGTV 7 Enter additional frequency/calibration factor pairs by pressing when the 'FKV %CN screen is displayed. You are prompted to enter the frequency first followed by the respective calibration factor. The power meter automatically sets up the table in frequency ascending order.
Page 202 7UKPI 5GTKGU 2QYGT 5GPUQTU 5GPUQT %CNKDTCVKQP 6CDNGU 2TGKPUVCNNGF %CNKDTCVKQP 6CDNG %QPVGPVU The following lists detail the contents of the installed sensor calibration tables. &'(#7.6 #IKNGPV # /*\ /*\ )*\ /*\ /*\ /*\ #IKNGPV # /*\...
Page 203 5GPUQT %CNKDTCVKQP 6CDNGU 7UKPI 5GTKGU 2QYGT 5GPUQTU #IKNGPV & #IKNGPV # /*\ /*\ /*\ )*\ )*\ )*\ )*\ )*\ )*\ )*\ )*\ )*\...
Page 204 7UKPI 5GTKGU 2QYGT 5GPUQTU 5GPUQT %CNKDTCVKQP 6CDNGU #IKNGPV # #IKNGPV # EQPVKPWGF )*\ /*\ )*\ /*\ )*\ /*\ )*\ )*\ )*\ )*\ )*\ ...
Page 205 This chapter describes the built in tests, error messages, and general 6JKU %JCRVGT maintenance. It contains these sections: • Self Test on page 204 • Error Messages on page 211 • Operator Maintenance on page 224 • Contacting Agilent Technologies on page 226...
Page 206 /CKPVGPCPEG 5GNH 6GUV 5GNH 6GUV The power meter has two self test modes: • Power on self test - occurs automatically when you turn on the power meter. • Troubleshooting mode - accessed via the front panel or remotely. The front panel softkey menu allows you to run individual tests, whereas the remote command runs a complete series of tests as listed in Remote Testing on page 207.
Page 207 NO TE The RS232 and RS422 loop back tests require a specially wired connector - refer to the EPM-P series power meter Service Guide. Each of these tests can be run individually. Information on the instrument self test and confidence check are described in Instrument Self Test on page 206.
Page 208 /CKPVGPCPEG 5GNH 6GUV +PUVTWOGPV 5GNH 6GUV +PUVTWOGPV 5GNH 6GUV is selected, the following tests are run: (These are the same tests which are run using the *TST? command.) • ROM checksum • RAM • Lithium Battery • Display Assembly • Calibrator •...
Page 209 5GNH 6GUV /CKPVGPCPEG 4GOQVG 6GUVKPI To invoke the remote self test, the IEEE 488.1 compliant standard command, *TST? is used. This command runs a full self test and returns one of the following codes: • 0 - no tests failed •...
Page 210 /CKPVGPCPEG 5GNH 6GUV 6GUV &GUETKRVKQPU This section specifies what is actually checked by each of the tests. Some of the tests may only be applicable to one method of invocation (for example, from the front panel). If this is the case, it is specified in the test description.
Page 211 RS232 loop back and RS422 loop back. Both the RS232 and RS422 loop back tests require a specially wired connector - refer to the EPM-P series power meter Service Guide. • UART Configuration - confirms that the baud rate, stop bits and parity settings are correctly configured on the UART.
Page 212 (CUV 2CVJ #EEWTCE[ This test requires specialized test equipment and is beyond the scope of this guide. Please refer to the EPM-P series power meters Service Guide. '2/2 7UGT U )WKFG...
Page 213 'TTQT /GUUCIGU /CKPVGPCPEG 'TTQT /GUUCIGU +PVTQFWEVKQP This section contains information about error messages. It explains how to read the power meter’s error queue and lists all error messages and their probable causes. When there is a hardware related problem, for example, a power sensor overload, the error message is displayed on the status line at the top of the display.
Page 214 /CKPVGPCPEG 'TTQT /GUUCIGU Error queue messages have the following format: Error Error Device “ ” Number Description Dependent Info (KIWTG 'TTQT 3WGWG /GUUCIG For example, -330, “Self-test Failed;Battery Fault”. Errors are retrieved in a first in first out (FIFO) order. If more than 30 errors occur, the error queue overflows and the last error in the queue is replaced with error -350, “Queue Overflow”.
Page 215 'TTQT /GUUCIGU /CKPVGPCPEG 'TTQT /GUUCIG .KUV -101 Invalid character An invalid character was found in the command string. You may have inserted a character such as #, $, or % in the command header or within a parameter. For example, LIM:LOW O#. -102 Syntax error Invalid syntax was found in the command string.
Page 216 /CKPVGPCPEG 'TTQT /GUUCIGU -113 Undefined header A command was received that is not valid for this power meter. You may have misspelled the command, it may not be a valid command or you may have the wrong interface selected. If you are using the short form of the command, remember that it may contain up to four letters.
Page 217 'TTQT /GUUCIGU /CKPVGPCPEG -138 Suffix not allowed A suffix was received following a numeric parameter which does not accept a suffix. For example, INIT:CONT 0Hz. -148 Character data not allowed A discrete parameter was received but a character string or a numeric parameter was expected.
Page 218 /CKPVGPCPEG 'TTQT /GUUCIGU -211 Trigger ignored Indicates that <GET> or *TRG, or TRIG:IMM was received and recognized by the device but was ignored because the power meter was not in the wait for trigger state. -213 Init ignored Indicates that a request for a measurement initiation was ignored as the power meter was already initiated.
Page 219 'TTQT /GUUCIGU /CKPVGPCPEG -226 Lists not same length This occurs when SENSe:CORRection:CSET[1]|CSET2:STATe is set to ON and the frequency and calibration/offset lists do not correspond in length. -230 Data corrupt or stale This occurs when a FETC? is attempted and either a reset has been received or the power meter state has changed such that the current measurement is invalidated (for example, a change of frequency setting or triggering conditions).
Page 220 /CKPVGPCPEG 'TTQT /GUUCIGU -230 Data corrupt or stale;Please calibrate Channel A When CAL[1|2]:RCAL is set to ON and the sensor currently connected to channel B has not been calibrated, then any command which would normally return a measurement result (for example FETC?, READ?, or MEAS?) will generate this error message -230 Data corrupt or stale;Please calibrate Channel B...
Page 221 'TTQT /GUUCIGU /CKPVGPCPEG -231 Data questionable;Lower window log error This indicates that a difference measurement in the lower window has given a negative result when the units of measurement were logarithmic. -231 Data questionable;Upper window log error This indicates that a difference measurement in the upper window has given a negative result when the units of measurement were logarithmic.
Page 222 /CKPVGPCPEG 'TTQT /GUUCIGU -310 System error;Ch B Dty Cyc may impair accuracy with ECP sensor This indicates that the sensor connected to channel B is for use with CW signals only. -310 System error;Sensor EEPROM Read Failed - critical data not found or unreadable This indicates a failure with your E-series power sensor.
Page 223 'TTQT /GUUCIGU /CKPVGPCPEG -330 Self-test Failed; The -330, “Self-test Failed” errors indicate that you have a problem with your power meter. Refer to see Contacting Agilent Technologies on page 226 for details of what to do with your faulty power meter. -330 Self-test Failed;Measurement Channel Fault Refer to see Measurement Assemblies on page 208 if you require a...
Page 224 /CKPVGPCPEG 'TTQT /GUUCIGU -330 Self-test Failed;Serial Interface Fault Refer to see Serial Interface on page 209 if you require a description of this test. -350 Queue overflow The error queue is full and another error has occurred which could not be recorded.
Page 225 'TTQT /GUUCIGU /CKPVGPCPEG -440 Query UNTERMINATED after indefinite response The *IDN? command must be the last query command within a command string. '2/2 7UGT U )WKFG...
Page 226 This section describes how to replace the power line fuse and clean the power meter. If you need additional information about replacing parts or repairing the power meter, refer to the EPM-P series power meter Service Guide. To clean the power meter, disconnect its supply power and wipe with a damp cloth only.
Page 227 1RGTCVQT /CKPVGPCPEG /CKPVGPCPEG 4 Replace the fuse holder assembly in the rear panel. In line fuse Spare fuse (KIWTG 4GRNCEKPI VJG (WUG '2/2 7UGT U )WKFG...
Page 228 Sales and Service Offices on page 229. If you wish to return the power meter to Agilent Technologies refer to see Returning Your Power Meter for Service on page 230.
Page 229 • Check operation by performing the self tests. • Check with a different power sensor. +PUVTWOGPV UGTKCN PWODGTU Agilent Technologies makes frequent improvements to its products to enhance their performance, usability and reliability. Agilent Technologies service personnel have access to complete records of design changes for each instrument.
Page 230 This is a code identifying the date of the last major design change. • The suffix indicates an alpha numeric code which is used to ensure unique identification of each product throughout Agilent Technologies. SERIAL NUMBER SER GB12345678 $JLOHQW H69@ÃDIÃVFÃPAÃ9PH@TUD8...
Page 231: Australia And New Zealand
Contacting Agilent Technologies Maintenance Sales and Service Offices For more information about Agilent Technologies test and measurement products, applications, services, and for a current sales office listing, visit our web site: http://www.agilent.com You can also contact one of the following centers and ask for a test and measurement sales representative.
Page 232 4GVWTPKPI ;QWT 2QYGT /GVGT HQT 5GTXKEG Use the information in this section if you need to return your power meter to Agilent Technologies. 2CEMCIG VJG 2QYGT /GVGT (QT 5JKROGPV Use the following steps to package the power meter for shipment to...
Page 233 %QPVCEVKPI #IKNGPV 6GEJPQNQIKGU /CKPVGPCPEG 4 Seal the shipping container securely with strong nylon adhesive tape. 5. Mark the shipping container “FRAGILE, HANDLE WITH CARE” to ensure careful handling. 6. Retain copies of all shipping papers. '2/2 7UGT U )WKFG...
Page 234 /CKPVGPCPEG %QPVCEVKPI #IKNGPV 6GEJPQNQIKGU '2/2 7UGT U )WKFG...
Page 235 %JCTCEVGTKUVKEU 9JCV ;QW NN (KPF KP 6JKU This Chapter describes the Specifications and Characteristics of %JCRVGT your EPM-P series power meter. It contains the following sections: • Power Meter Specifications on page 235 • Measurement Characteristics on page 240 • Environmental Specifications on page 244...
Page 236 Compatibility - the EPM-P series power meters operate with the E-series E9320 family of power sensors for peak, average and time gated measurements. The EPM-P series meters also operate with existing 8480 series, E-series E4410 and E9300 ranges of power sensors for average power measurements.
Page 237 2QYGT /GVGT 5RGEKHKECVKQPU 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 2QYGT /GVGT 5RGEKHKECVKQPU (TGSWGPE[ 4CPIG 9 kHz to 110 GHz, power sensor dependent 2QYGT 4CPIG -70 dBm to +44 dBm (100 pW to 25 W), power sensor dependent 2QYGT 5GPUQTU Compatible with all Agilent 8480 series power sensors and Agilent E-series power sensors.
Page 238 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 2QYGT /GVGT 5RGEKHKECVKQPU &GHCWNV 4GUQNWVKQP 0.01 dB in logarithmic mode 3 digits in linear mode 1HHUGV 4CPIG ±100 dB in 0.001 dB increments, to compensate for external loss or gain. 8KFGQ $CPFYKFVJ /QFWNCVKQP $CPFYKFVJ 5 MHz (set by meter and is sensor dependent) N O T E The video bandwidth represents the ability of the power sensor and meter to follow the power envelope of the input signal.
Page 239 2QYGT /GVGT 5RGEKHKECVKQPU 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 8KFGQ $CPFYKFVJ &[PCOKE 4CPIG 1RVKOK\CVKQP The power measurement system, comprising the sensor and meter, has its maximum video bandwidth defined by the E-series E9320 power sensor. To optimize the system’s dynamic range for peak power measurements, the Video Bandwidth in the meter can be set to High, Medium, or Low as detailed in Table 101.
Page 240 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 2QYGT /GVGT 5RGEKHKECVKQPU #EEWTCE[ +PUVTWOGPVCVKQP Please add the corresponding power sensor linearity percentage (Refer to the Specifications section in the User’s Guide supplied with your power sensor). #XGTCIGQPN[ /QFG Logarithmic ±0.02 dB Absolute: Linear ±0.5% Logarithmic ±0.04 dB Relative: Linear ±1.0% %CNKDTCVKQP...
Page 241 2QYGT /GVGT 5RGEKHKECVKQPU 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU O9 2QYGT 4GHGTGPEG Power Output: 1.00 mW (0.0 dBm). Factory set to ±0.5% traceable to the US National Institute of Standards and Technology (NIST), and National Physical Laboratories (NPL), UK. ±1.2% (0 to 55 ºC) Accuracy: (for one year) ±1.07% (25±10 ºC) ±1.03% (23±3 ºC)
Page 242 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU /GCUWTGOGPV %JCTCEVGTKUVKEU /GCUWTGOGPV %JCTCEVGTKUVKEU /GCUWTGOGPV %JCTCEVGTKUVKEU Measurements: Average Power Peak Power Peak-to-Average ratio Measurements between two time offsets (time gating) Averaging: Averaging over 1 to 1024 readings is available for reducing noise Measurement Speed (GPIB): Over the GPIB, three measurement modes are available - Normal, X2 and Fast. The typical maximum speed for each mode is shown in the table below: /GCUWTGOGPV 5RGGF TGCFKPIU RGT UGEQPF...
Page 243 /GCUWTGOGPV %JCTCEVGTKUVKEU 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU Channel Functions: A, B, A/B, B/A, A−B, B−A, and relative Storage Registers: 10 instrument states can be saved via Save/Recall menu. Predefined setups: For common wireless standards (GSM900, EDGE, NADC, iDEN, Bluetooth, IS-95 CDMA, WCDMA and cdma2000),predefined setups are provided.
Page 244 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU /GCUWTGOGPV %JCTCEVGTKUVKEU 5CORNKPI %JCTCEVGTKUVKEU Sampling Rate: 20 Msamples/second Sampling Technique: continuous sampling 4GCT 2CPGN +PRWVU1WVRWVU Recorder Output(s): Analog 0 to 1 V, 1 kΩ output impedance, BNC connector. (Two outputs are available on the E4417A, Channel A and B.) Remote Input/Output: TTL Output: used to signal when measurement has exceeded a defined limit...
Page 245 /GCUWTGOGPV %JCTCEVGTKUVKEU 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 4GOQVG 2TQITCOOKPI Interface: GPIB interface operates to IEEE 488.2 and IEC-625 RS-232 and RS-422 interfaces are supplied as standard Command Language: SCPI standard interface commands GPIB Compatibility: SH1, AH1, T6, TE0, L4, LE0, SR1, RL1, PP1, DC1, DT1, C0 2J[UKECN 5RGEKHKECVKQPU Dimensions: The following dimensions exclude front and rear panel protrusions:...
Page 246 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 'PXKTQPOGPVCN 5RGEKHKECVKQPU 'PXKTQPOGPVCN 5RGEKHKECVKQPU 1RGTCVKPI 'PXKTQPOGPV Temperature: 0ºC to 55ºC Maximum Humidity: 95% at 40ºC (non-condensing) Minimum Humidity: 15% at 40ºC Maximum Altitude: 3,000 meters (9,840 feet) 5VQTCIG %QPFKVKQPU −20ºC to +70ºC Storage Temperature: Non-Operating Maximum Humidity: 90% at 65ºC (non-condensing) Non-Operating Maximum Altitude: 15,240 meters (50,000 feet)
Page 247 4GIWNCVQT[ +PHQTOCVKQP 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 4GIWNCVQT[ +PHQTOCVKQP 'NGEVTQOCIPGVKE %QORCVKDKNKV[ This product conforms with the protection requirements of European Council Directive 89/336/EEC for Electromagnetic Compatibility (EMC). The conformity assessment requirements have been met using the technical construction file route to compliance, using EMC test specifications EN 55011:1991 (Group 1, Class A) and EN 50082-1:1992.
Page 248 5RGEKHKECVKQPU CPF %JCTCEVGTKUVKEU 4GIWNCVQT[ +PHQTOCVKQP 2J[UKECN 5RGEKHKECVKQPU Dimensions: The following dimensions exclude front and rear panel 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): E4416A: 4.0 Kg (8.8 lb) approximately E4417A: 4.1 Kg (9.0 lb) approximately Weight (Shipping):...

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