Spectrum Analyzers SPECMON Series Datasheet
Contents
1. Field pulse analysis for example airport radar is easier than ever with automated Pulse Analysis suite Save up to 12 years of gap free DPX Spectrogram Real Time Waterfall Traces Opt 53 or up to 7 seconds of IQ data at full 110 MHz BW Opt 110 with extra large real time memory eliminating the need for an external data recorder in many cases Full 110 MHz bandwidth real time IQ data can be streamed to external data recording devices Opt 55 for comprehensive post analysis Instrumentation needs for frequency domain modulation domain and time domain analysis are simplified by native 3 in 1 multiple domain correlation and analysis capability Modulation analysis for 20 general purpose analog and digital signal types including AM FM demodulation and flexible OFDM signal analysis Built in versatile field measurement items including Field Strength Signal Strength EMI test Channel Power ACPR OBW and Spurious search Ruggedness and data security achieved with standard field removable solid state drive Open data format improves asset utilization through compatibility with industry standard products Captured IQ data can be saved into Matlab CSV or other formats for use with third party software analysis tools RSA MAP supports MapInfo format and scanned version maps also supports exporting to popular Google Earth and MapInfo map format for post analysis Open interface for integration into customer applications Ea2. 60 3 dB typical 1 Hz to 20 MHz and gt 20 MHz to 60 MHz Opt 110 10 Minimum Settable Spectrum Analysis RBW vs Span Frequency Span gt 10 MHz gt 1 25 MHz to 10 MHz lt 1 MHz lt 100 kHz RBW 100 Hz 10 Hz 1 Hz 0 1 Hz Spectrum Display Traces Detector and Functions Characteristic Traces Detector Trace Functions Spectrum Trace Length Sweep Speed Typical RBW Auto RF IF Optimization minimize sweep time Description Three traces 1 math waveform 1 trace from spectrogram for spectrum display Peak Peak Average Vas Peak Sample CISPR Avg Peak Quasi peak Average of Logs Normal Average Max Hold Min Hold Average of Logs 801 2401 4001 8001 or 10401 points 1500 MHz s Std 2500 MHz s Opt 40 6000 MHz s Opt 110 DPX Digital Phosphor Spectrum Processing DPX Advanced DPX Characteristic Standard Opt 200 Spectrum Processing 48 828 s 292 969 s Rate RBW Auto Trace Length 801 DPX Bitmap Resolution 201 x 501 201 x 801 DPX Bitmap Color 64k 48 dB 8G 99 dB Dynamic Range Marker Information Amplitude frequency Amplitude frequency and hit count on the and signal density on DPX display the DPX display 31 us Std or Opt 40 See Minimum Signal 24 us Opt 110 Duration for 100 Probability of Trigger at 100 Amplitude table 100 Hz to 25 MHz 40 MHz with Opt 40 Minimum Signal Duration for 100 Probability of Detection Max hold On 100 Hz to 25 MHz
3. LF Band 30 MHz to 3 GHz 73 dBc 73 dBc 3 GHz to 6 2 GHz 73 dBc 73 dBc SPECMON6 Spurious Response with Signal at 3 5125 GHz lt 80 dBc RF input level 30 dBm Local Oscillator Feed through to Input Connector lt 60 dBm typical attenuator 10 dB Adjacent Channel Leakage Ratio Dynamic Range ACLR Typical Signal Type Adjacent Alternate Measurement Mode 3GPP Downlink 1 DPCH Uncorrected Noise Corrected 0 dB 0 dB 9 dB 79 dB 9 Measured with test signal amplitude adjusted for optimum performance CF 2 13 GHz IF Frequency Response and Phase Linearity 10 Amplitude Amplitude Phase Frequency Acquisition Flatness Flatness Flatness Range GHz Bandwidth Spec Typ RMS Typ RMS 0 001 to 0 032 lt 20 MHz 0 50 dB 0 4 dB TOF LF Band 0 01 to 6 2 11 lt 300 kHz 0 10 dB 0 05 dB 0 1 Opt 40 0 03 to 6 2 lt 40 MHz 0 30 dB 0 20 dB 0 5 Opt 110 0 07 to 3 0 lt 110 MHz 0 50 dB 0 30 dB 15 gt 3 0 to 6 2 lt 110 MHz 0 50 dB 0 40 dB 1 5 10 Amplitude flatness and phase deviation over the acquisition BW includes RF frequency response Attenuator Setting 10 dB 11 High Dynamic Range mode selected Spectrum Analyzers SPECMON Series Frequency Mask Trigger Opt 52 Characteristic Description Mask Shape User Defined Mask Point Horizontal lt 0 2 of span Resolution Level Range 0 dB to 80 dB from reference level Level Accuracy 12 0 to 50 dB from reference level 50 dB to
4. Spectrum Analyzers SPECMON Series Datasheet Tektronix SPECMONG Real Time Spectrum Analyzer 1Hz 6 2GHz DPX Features amp Benefits SPECMON Series 3 0 and 6 2 GHz Real time Spectrum Analyzers Leading real time technologies help to troubleshoot the toughest transient interferences in the field Unique Swept DPX enables the customer to Real Time Scan the whole 3 6 2 GHz frequency range for transient interference discovery Opt 200 Up to 110 MHz ultra wide real time BW for close in signal discovery capture and real time demodulation Unmatched ability to discover and capture signals with as short as 3 7 us duration with 100 Probability of Intercept POI Opt 200 Exceptional DPX Density Trigger Trigger on This Opt 200 Frequency Mask Trigger Opt 52 and other advanced triggering capabilities provide 100 probability of intercept for signals as short as 3 7 us in the frequency domain and 12 ns in the time domain Save hours of post capture review time with optional advanced triggering capabilities such as Save on Trigger which intelligently saves events of interest automatically Integrated solution design reduces total cost of ownership with lower initial purchase cost and annual maintenance cost Both manual and automatic drive test are supported by built in mapping software Commercial off the shelf 3rd party GPS receiver supported via USB or Bluetooth connection
5. 70 dB from Channel Response Flatness 2 5 dB reference level Span Range Channel Response Flatness 1 0 dB 100 Hz to 25 MHz 100 Hz to 40 MHz Opt 40 100 Hz to 110 MHz Opt 110 Span 25 MHz 15 us 9 us Opt 200 RBW Auto Span 40 MHz Opt 40 12 8 us 7 us Opt 200 RBW Auto Span 110 MHz Opt 110 5 12 us 5 us Opt 200 RBW Auto 12 For masks gt 30 dB above noise floor Center Frequency 250 MHz Trigger Position Uncertainty Minimum Signal Duration for 100 Probability of Trigger at 100 Amplitude 13 Opt 52 plus Acquisition Opt 52 plus Opt 52 plus Opt 200 BW Opt 52 Opt 09 Opt 200 plus Opt 09 25 MHz 35 9 us 25 6 us 17 7 us 4 us 40 MHz 27 3 US 15 4 us 17 5 us 3 9 us 85 MHz 23 9 us 10 3 us 17 3 us 3 7 us 110 MHz 23 9 us 10 3 us 17 3 us 3 7 us 13 RBW maximum for FMT with Opt 200 Opt 200 Advanced Triggers Swept DPX and DPX Zero Span Minimum Event Duration 100 POI RBW FFT Spectrums Opt 200 plus Span kHz Length Isec Opt 200 Opt 09 110MHz 10000 1024 292 969 17 3 3 7 1000 1024 292 969 19 5 5 8 300 2048 146 484 28 5 14 8 100 4096 73 242 37 6 37 6 30 16384 18 311 134 6 134 6 20 32768 9 155 229 2 229 2 40 MHz 5000 1024 292 969 17 5 3 9 1000 1024 292 969 19 4 58 300 1024 292 969 25 11 4 100 2048 292 969 37 6 30 8 30 4096 73 242 93 6 93 6 20 8192 36 621 147 3 147 3 10 16384 18 311 194 5 194 5 25 MHz 3800 1024 292 969 17 4 4 1000 1024 292 969 19 4 5 8 300 1024 292
6. Carrier Frequency 1 GHz 400 Hz 1 kHz Input Modulated Frequency 3 0 dBm Input at Center Carrier Frequency 1 GHz 1 kHz 5 kHz Input Modulated Frequency Description Touch panel 10 4 in 264 mm N type female 50 Q BNC High gt 2 0 V Low lt 0 4 V output current 1 mA LVTTL BNC 50 Q 5 kQ impedance nominal 5 V max input 2 5 V to 2 5 V trigger level 2 USB 2 0 Speaker 50 Q BNC gt 0 dBm 50 Q 10 MHz BNC BNC High 1 6 to 5 0 V Low 0 to 0 5 V IEEE 488 2 RJ45 10 100 1000BASE T 2 USB 2 0 VGA compatible 15 DSUB 3 5 mm headphone jack BNC 28 V 140 mA nominal 2 connectors LVDS Opt 55 RF Field Strength and Mapping Characteristic RF Field Strength Signal Strength Indicator Measurement Bandwidth Tone Type Mapping Map Types Directly Supported Saved Measurement Results Description Located at right side of display Up to 110 MHz dependent on span and RBW setting Variable frequency Pitney Bowes MapInfo mif Bitmap bmp Measurement data files exported results Map file used for the measurements Google Earth KMZ file Recallable results files trace and setup files MapInfo compatible MIF MID files General Characteristics Characteristic Description Temperature Range Operating 5 C to 40 C Storage 20 C to 60 C Warm up Time 20 min Altitude Operating Up to 3000 m approximately 10 000 ft Nonoperating Up to 12 190 m 40 000 ft Relativ
7. 0 5 Opt 110 10 GHz 55 kHz 190 kHz 1 2 20 GHz 200 kHz 560 kHz 2 6 17 Pulse ON Power 2 20 dBm signal peak at Reference Level Attenuator Auto tmeas treterence S 10 MS Frequency Estimation Manual Pulse to Pulse Measurement time position excludes the beginning and ending of the pulse extending for a time 10 Measurement BW as measured from 50 of the trise OF tgan Absolute Frequency Error determined over center 50 of pulse Frequency and Phase Error Referenced to a Linear Chirp At stated frequencies and measurement bandwidths 8 typical CF RMS FreqErr Pulse to Pulse to Bandwidth Pulse Freq Pulse Phase 20 MHz 2 GHz 7 kHz 16 kHz 0 3 10 GHz 16 kHz 40 kHz 0 95 20 GHz 40 kHz 110 kHz 225 60 MHz 2 GHz 26 kHz 130 kHz 0 7 Opt 110 10GHz 55 kHz 370 kHz 1 3 20 GHz 200 kHz 630 kHz Ho 18 Pulse ON Power 2 20 dBm signal peak at Reference Level Attenuator 0 dB tmeas treference S 10 ms Frequency Estimation Manual Pulse to Pulse Measurement time position excludes the beginning and ending of the pulse extending for a time 10 Measurement BW as measured from 50 of the tyise OF tran Absolute Frequency Error determined over center 50 of pulse Note Signal type Linear Chirp Peak to Peak Chirp Deviation lt 0 8 Measurement BW Digital Modulation Analysis Opt 21 Description m 2DBPSK BPSK SBPSK QPSK DQPSK T 4DQPSK D8PSK 8PSK D16PSK OQPSK SOQPSK CPM 16 32 AP
8. 1 5 dB from lt 50 dB to 70 dB from reference level signal level Trigger Bandwidth Range at maximum 4 kHz to 10 MHz wide open standard acquisition BW 4 kHz to 20 MHz wide open Opt 40 11 kHz to 40 MHz wide open Opt 110 Trigger Position Timing Uncertainty 25 MHz Acquisition Uncertainty 15 ns BW 10 MHz BW Std 40 MHz Acquisition BW 20 MHz BW Opt 40 110 MHz Acquisition BW 40 MHz BW Opt 110 Trigger Re Arm Time Minimum Fast Frame On 10 MHz Acquisition BW lt 25 us 40 MHz Acquisition BW lt 10 us Opt 40 110 MHz Acquisition lt 5 us BW Opt 110 Minimum Event Duration Filter Off 25 MHz Acquisition BW 40 ns Std 40 MHz Acquisition BW 25 ns Opt 40 110 MHz Acquisition 12ns BW Opt 110 External Trigger 1 Level Range 2 5 V to 2 5 V Level Setting Resolution 0 01 V Trigger Position Timing Uncertainty 50 Q input impedance 25 MHz Acquisition Uncertainty 20 ns BW 25 MHz Span Std 40 MHz Acquisition Uncertainty 15 ns BW 40 MHz Span Opt 40 110 MHz Acquisition BW 110 MHz Span Opt 110 Input Impedance Uncertainty 10 ns Uncertainty 5 ns Uncertainty 12 ns Selectable 50 Q 5 KQ impedance nominal External Trigger 2 Threshold Voltage Fixed TTL Input Impedance 10 KQ nominal Trigger State Select High Low Trigger Output Voltage Output Current lt 1 mA High gt 2 0V Low lt 0 4 V Advanced trigger specifications are found in sec
9. FM PM and Direct Audio Measurement Opt 10 Characteristics typical for input frequencies lt 2 GHz RBW Auto Averaging Off Filters Off Characteristic Description Analog Demodulation Carrier Frequency Range 1 2 x Audio Analysis Bandwidth to maximum input for modulation and audio frequency measurements Maximum Audio 10 MHz Frequency Span Audio Filters Low Pass kHz 0 3 3 15 30 80 300 and user entered up to 0 9 x audio bandwidth High Pass Hz 20 50 300 400 and user entered up to 0 9 x audio bandwidth Standard CCITT C Message De emphasis us 25 50 75 750 and user entered File User supplied TXT or CSV file of amplitude frequency pairs Maximum 1000 pairs FM Modulation Analysis Modulation Index gt 0 1 FM Measurements Carrier Power Carrier Frequency Error Audio Frequency Deviation Peak Peak Peak Peak 2 RMS SINAD Modulation Distortion S N Total Harmonic Distortion Total Non harmonic Distortion Hum and Noise Carrier Power Accuracy 0 85 dB 10 MHz to 2 GHz 20 to 0 dBm input power Carrier Frequency 0 5 Hz transmitter frequency x reference frequency Accuracy Deviation error 1 to 10 kHz FM Deviation Accuracy Rate 1 kHz to 1 MHz FM Rate Accuracy Deviation 1 to 100 kHz Residuals FM Rate 1 to 10 kHz Deviation 5 kHz 1 of rate deviation 50 Hz 0 2 Hz THD 0 10 Distortion 0 7 SINAD 43 dB AM Modulation Analysis AM Measurements Ca
10. Frequency Accuracy Zero span Trigger Timing Zero span Sweep Time 400 at trigger point Uncertainty Power trigger DPX Frequency Display 100 MHz maximum Range DPX Phase Display 200 Degrees maximum Range DPX Waveforms s 50 000 triggered waveforms s for sweep time 20 us 12 www tektronix comrsa DPX Spectrogram Performance Characteristic Description Span Range 100 Hz to maximum acquisition bandwidth DPX Spectrogram Trace Peak Peak Avg Vrus Detection DPX Spectrogram Trace 801 to 4001 Length DPX Spectrogram Trace Length 801 60 000 traces Memory Depth Trace Length 2401 20 000 traces Trace Length 4001 12 000 traces Time Resolution per Line 110 us to 6400 s user settable Maximum Recording Time 6 6 seconds 801 points trace 110 us line to vs Line Resolution 4444 days 801 points trace 6400 s line Opt 200 Advanced Triggers Characteristic Description DPX Density Trigger Density Range Horizontal Range 0 to 100 density 0 25 Hz to 25 MHz Std 0 25 Hz to 40 MHz Opt 40 0 25 Hz to 110 MHz Opt 110 Minimum Signal Duration See Minimum Signal Duration for 100 Probability of for 100 Probability of Trigger at 100 Amplitude table Trigger at maximum acquisition bandwidth RBW Auto Trace Length 801 Points Frequency Edge Trigger Range x ACQ BW or TDBW if TDBW is active Minimum Event Duration 12 ns ACQ BW 110 MHz no TDBW Opt 110 25 ns ACQ BW 40 MHz no TD
11. P7350SMA P7360A P7380A P7380SMA P7500 Series RSAVu Software based on the RSA3000 Series platform for analysis supporting 3G wireless standards WLAN IEEE802 11a b g n RFID Audio Demodulation and more measurements E and H Near field Probes For EMI troubleshooting 119 4146 xx Additional Removable Windows 7 and instrument SW preinstalled Hard Drive 065 0939 xx Transit Case 016 2026 xx Rackmount Retrofit RSAS6KR Additional Quick Start 071 3064 xx User Manual Paper www tektronix comrsa 17 Datasheet International Power Plugs Option Opt Opt Opt Opt Opt Opt Opt Opt Opt Opt Opt AO A1 A2 A3 A4 A5 A6 A10 A11 A12 A99 Service Option Opt Opt Opt Opt Opt Opt Opt Opt Opt Opt CA1 C3 C5 D1 D3 D5 G3 G5 R3 R5 Description North America power Universal Euro power United Kingdom power Australia power 240 V North America power Switzerland power Japan power China power India power Brazil power No power cord or AC adapter Description Single Calibration or Functional Verification Calibration Service 3 Years Calibration Service 5 Years Calibration Data Report Calibration Data Report 3 Years with Opt C3 Calibration Data Report 5 Years with Opt C5 Complete Care 3 Years includes loaner scheduled calibration and more Complete Care 5 Years includes loaner scheduled calibration and more Repair Service 3 Years Repair Servi
12. g Guard Interval Subcarrier Spacing Channel Bandwidth Carrier Detect 802 11 802 16 2004 Auto detect Manual Select BPSK QPSK 16QAM 64QAM Channel Estimation Preamble Preamble Data Pilot Tracking Phase Amplitude Timing Advanced parameter settings Frequency Correction On Off Summary Measurements Symbol Clock Error Frequency Error Average Power Peak to Average CPE EVM RMS and Peak for all carriers plot carriers data carriers OFDM Parameters Number of Carriers Guard Interval Subcarrier Spacing Hz FFT Length Power Average Peak to Average Displays EVM vs Symbol vs Subcarrier Subcarrier Power vs Symbol vs Subcarrier Mag Error vs Symbol vs Subcarrier Phase Error vs Symbol vs Subcarrier Channel Frequency Response 44 dB WiMAX 802 16 2004 5 MHz BW 44 dB WLAN 802 11g 20 MHz BW Signal input power optimized for best EVM Residual EVM 16 www tektronix comrsa Analog Modulation Analysis Accuracy Typical Modulation AM FM PM Inputs And Outputs Characteristic Front Panel Display RF Input Connector Trigger Out Trigger In USB Ports Audio Rear Panel 10 MHz REF OUT External REF IN Trig 2 Gate IN GPIB Interface LAN Interface Ethernet USB Ports VGA Output Audio Out Noise Source Drive Digital IQ Out Description 2 0 dBm Input at Center Carrier Frequency 1 GHz 10 to 60 Modulation Depth 1 of Span 0 dBm Input at Center
13. kHz 1 52 kS s 87960 s 351843 s 655 us 500 Hz 762 S s 175921 s 703687 s 1 31 ms 200 Hz 381 S s 351843 s 1407374 s 2 62 ms 100 Hz 190 S s 703686 s 2814749 s 5 24 ms 1 In spans 2 MHz higher resolution data is stored www tektronix comrsa 7 Datasheet Analysis Related Available Displays Frequency Views Spectrum Amplitude vs Linear or Log Frequency DPX Spectrum Display Live RF Color graded Spectrum Spectrogram Amplitude vs Frequency over Time Spurious Amplitude vs Linear or Log Frequency Phase Noise Phase Noise and Jitter Measurement Opt 11 Time and Statistics Amplitude vs Time Frequency vs Time Phase vs Time DPX Amplitude vs Time Opt 200 DPX Frequency vs Time Opt 200 DPX Phase vs Time Opt 200 Amplitude Modulation vs Time Frequency Modulation vs Time Phase Modulation vs Time RF IQ vs Time Time Overview CCDF Peak to Average Ratio Settling Time Frequency Frequency Settling vs Time Phase Settling vs Time and Phase Opt 12 Advanced Measurements Pulse Results Table Suite Pulse Trace selectable by pulse number Pulse Statistics Trend of Pulse Results FFT of Trend o andHistogram SS Digital Demod Opt 21 Constellation Diagram EVM vs Time Symbol Table Binary or Hexadecimal Magnitude and Phase Error versus Time and Signal Quality Demodulated IQ vs Time Eye Diagram Trellis Diagram Frequency Deviation vs Time Flexible OFDM Analysis Constellation Scalar Measurement Summa
14. line 1 Time dv 27 5 ms 11 10 2011 10 10 37 893764 3 D Pos 0 0 div 40 00 dBm dB div 7 00 dB Spit M 110 00 dBm Autoscale CF 868 5 MHz Span 85 0 MHz DPX Spectrograms Opt 200 provide gap free spectral monitoring for up to 12 years at atime 60 000 traces can be recorded and reviewed with resolution per line adjustable from 110 us to 6400 s Discover The patented DPX spectrum processing engine brings live analysis of transient events to spectrum analyzers Performing up to 292 000 frequency transforms per second transients of a minimum event duration of 3 7 us in length are displayed in the frequency domain This is orders of magnitude faster than swept analysis techniques Events can be color coded by rate of occurrence onto a bitmapped display providing unparalleled insight into transient signal behavior The DPX spectrum processor can be swept over the entire frequency range of the instrument enabling broadband transient capture previously unavailable in any spectrum analyzer In applications that require only spectral information Opt 200 provides gap free spectral recording replay and analysis of up to 60 000 spectral traces Spectrum recording resolution is variable from 110 us to 6400 s per line Se lect Span Zoom CF Pan Zoom Pan Reset scale Marker to peak Add marker Trigger On This Revolutionary DPX spectrum display reveals transient si
15. 0 1 Hz 20 GHz Single 2 kHz 100 Hz 10 Hz 5 Hz Measurement 100 Averages 200 Hz 10 Hz 1 Hz 0 5 Hz 1000 Averages 100 Hz 5 Hz 0 5 Hz 0 2 Hz Settled Phase Uncertainty 95 Confidence Typical at Stated Measurement Frequencies Bandwidths and of Averages Measurement Phase Uncertainty at Stated Frequency Measurement Bandwidth Averages 110 MHz 10 MHz 1 MHz 1 GHz Single 1 00 0 50 0 50 Measurement 100 Averages 0 10 0 05 0 05 1000 Averages 0 05 0 01 0 01 10 GHz Single 1 50 1 00 0 50 Measurement 100 Averages 0 20 0 10 0 05 1000 Averages 0102 0 05 0 02 20 GHz Single 1 00 0 50 0 50 Measurement 100 Averages 0 10 0 05 0 05 1000 Averages 0 05 0 02 0 02 14 Measured input signal level gt 20 dBm Attenuator Auto 14 www tektronix comrsa Advanced Measurement Suite Characteristic Measurements Description Average On Power Peak Power Average Transmitted Power Pulse Width Rise Time Fall Time Repetition Interval seconds Repetition Interval Hz Duty Factor Duty Factor Ratio Ripple dB Ripple Droop dB Droop Overshoot dB Overshoot Pulse Pulse Frequency Difference Pulse Pulse Phase Difference RMS Frequency Error Max Frequency Error RMS Phase Error Max Phase Error Frequency Deviation Phase Deviation Impulse Response dB Impulse Response Time Time Stamp Minimum Pulse Width for 150 ns standard Opt 40 50 ns Opt 110 Detect
16. 0 dBm Attenuator 0 dB 1 MHz tone separation Note 3rd order intercept point is calculated from 3rd order intermodulation performance 10 www tektronix comrsa 2nd Harmonic Distortion 4 Frequency 2nd Harmonic Distortion Typical 10 MHz to 1 GHz lt 80 dBc gt 1 GHz to 3 1 GHz lt 83 dBc 4 40 dBm at RF input Attenuator 0 Preamp Off typical Displayed Average Noise Level 5 Preamp Off Frequency Range Specification Typical LF Band 1 Hz to 100 Hz 129 dBm Hz gt 100 Hz to 4 kHz 124 dBm Hz 130 dBm Hz gt 4 kHz to 10 kHz 141 dBm Hz 144 dBm Hz gt 10 kHz to 32 MHz 150 dBm Hz 153 dBm Hz RF Band 9 kHz to 1 MHz 108 dBm Hz 111 dBm Hz gt 1 MHz to 10 MHz 136 dBm Hz 139 dBm Hz gt 10 MHz to 2 GHz 154 dBm Hz 157 dBm Hz gt 2 GHz to 3 GHz 153 dBm Hz 156 dBm Hz gt 3 GHz to 4 GHz 151 dBm Hz 154 dBm Hz SPECMON6 gt 4 GHz to 6 2 GHz 149 dBm Hz 152 dBm Hz SPECMONG 5 Measured using 1 kHz RBW 100 kHz span 100 averages Minimum Noise mode input terminated log average detector and trace function Preamplifier Performance Characteristic Description Frequency Range 1 MHz to 3 0 GHz or 6 2 GHz SPECMON6 Noise Figure at 2 GHz 7 dB Gain at 2 GHz 18 dB nominal Displayed Average Noise Level 5 Preamp On Frequency Range Specification Typical LF Band 1 MHz to 32 MHz 158 dBm Hz 160 dBm Hz RF Band 1 MHz to 10 MHz 158 dBm Hz 160 dBm Hz gt 10 MHz to 2 GHz 164 dBm Hz 167 dBm Hz gt 2 GHz to 3 GHz
17. 000 10000 Offset KHz Typical phase noise performance as measured by Opt 11 Amplitude Specifications excluding mismatch error Characteristic Description Measurement Range Displayed average noise level to maximum measurable input Input Attenuator Range 0dBto55dB 5 dB step Maximum Safe Input Level Average Continuous 30 dBm RF ATT 210 dB Preamp Off Average Continuous 20 dBm RF ATT 210 dB Preamp On Pulsed RF RF ATT 50 W 230 dB PW lt 10 us 1 Duty Cycle Maximum Measurable Input Level Average Continuous 30 dBm RF ATT Auto Pulsed RF RF ATT 50 W Auto PW lt 10 us 1 Duty Cycle Max DC Voltage 5 V Log Display Range 0 01 dBm div to 20 dB div Display Divisions 10 divisions Display Units dBm dBmV Watts Volts Amps dBuW dBuV dBuA dBW dBV dBV m and dBA m Marker Readout 0 01 dB Resolution dB Units Marker Readout Resolution Volts Units Reference Level Setting 0 1 dB step 170 dBm to 50 dBm minimum ref level Range 50 dBm at center frequency lt 80 MHz Level Linearity 0 1 dB 0 to 70 dB from reference level Reference level dependent as small as 0 001 uV www tektronix comrsa 9 Datasheet Frequency Response Range 18 C to 28 C Atten 10 dB Preamp Off 10 MHz to 32 MHz LF 0 7 dB Response Band 10 MHz to 3 GHz 0 35 dB gt 3 GHz to 6 2 GHz 0 5 dB SPECMON6 5 C to 40 C All Attenuator Settings Typical Preamp Off 1 Hz to 32 MHz LF 0 8 d
18. 1 800 833 9200 Central East Europe and the Baltics 41 52 675 3777 Central Europe amp Greece 41 52 675 3777 Denmark 45 80 88 1401 Finland 41 52 675 3777 France 00800 2255 4835 Germany 00800 2255 4835 Hong Kong 400 820 5835 India 000 800 650 1835 Italy 00800 2255 4835 Japan 81 3 6714 3010 Luxembourg 41 52 675 3777 Mexico Central South America amp Caribbean 52 55 56 04 50 90 Middle East Asia and North Africa 41 52 675 3777 The Netherlands 00800 2255 4835 Norway 800 16098 People s Republic of China 400 820 5835 Poland 41 52 675 3777 Portugal 80 08 12370 Republic of Korea 001 800 8255 2835 Russia amp CIS 7 495 6647564 South Africa 41 52 675 3777 Spain 00800 2255 4835 Sweden 00800 2255 4835 Switzerland 00800 2255 4835 Taiwan 886 2 2722 9622 United Kingdom amp Ireland 00800 2255 4835 USA 1 800 833 9200 European toll free number Ifnot accessible call 41 52 675 3777 Updated 10 February 2011 For Further Information Tektronix maintains a comprehensive constantly expanding collection of application notes technical briefs and other resources to help engineers working on the cutting edge of technology Please visit www tektronix com Copyright Tektronix Inc All rights reserved Tektronix products are covered by U S and foreign patents issued and pending Information in this publication supersedes that in all previously published material Specification and price change pr
19. 163 dBm Hz 165 dBm Hz gt 3 GHz to 6 2 GHz 162 dBm Hz 164 dBm Hz SPECMONG6 5 Measured using 1 kHz RBW 100 kHz span 100 averages Minimum Noise mode input terminated log average trace detector and function Residual Response 6 Frequency Range 500 kHz to 32 MHz LF Band 500 kHz to 80 MHz RF Band 80 MHz to 200 MHz 200 MHz to 3 GHz 3 GHz to 6 2 GHz SPECMON6 6 Input terminated RBW 1 kHz Attenuator 0 dB Reference Level 30 dBm Specified Typical lt 100 dBm lt 75 dBm lt 95 dBm 95 dBm 95 dBm Image Response Frequency Spec 100 Hz to 30 MHz lt 75 dBc 30 MHz to 3 GHz lt 75 dBc gt 3 GHz to 6 2 GHz lt 65 dBc SPECMONG6 7 Ref 30 dBm Attenuator 10 dB RF Input Level 30 dBm RBW 10 Hz Spurious Response with Signal Offset 2400 kHz Span 25 MHz Opt 40 110 Swept Spans gt 25 MHz 25 MHz lt Span lt 110 MHz Frequency Specification Typical Specification Typical 10 kHz to 71 dBc 75 dBc NA NA 32 MHz LF Band 30 MHz to 73 dBc 8 dBc 73 dBc 5 dBc 3 GHz gt 3 GHz to 73 dBc 8 dBc 73 dBc 5 dBc 6 2 GHz SPECMONG6 8 RF Input Level 15 dBm Attenuator 10 dB Mode Auto Input signal at center frequency Center Frequency gt 90 MHz Opt 40 110 Spurious Response with Signal 10 kHz lt offset lt 400 kHz Typical Opt 40 110 Span lt 25 MHz Swept 25 MHz lt Spans Frequency Spans gt 25 MHz 110 MHz 10 kHz to 32 MHz 71 dBc NA
20. 40 MHz with Opt 40 110 MHz with Opt 110 110 MHz with Opt 110 Span Range Swept Not Available Up to instrument frequency range Dwell Time per Step Not Available 50 ms to 100 s Trace Processing Color graded bitmap Color graded bitmap Peak Peak Average Peak Peak Average Trace Length 501 801 2401 4001 10401 Resolution BW Accuracy 7 1 Note For complete Advanced DPX specifications see the Opt 200 section of this data sheet Span Range Continuous processing Minimum RBW Swept Spans Opt 200 10 kHz Stability Residual FM lt 2 Hz in 1 second 95 confidence typical Phase Noise Sidebands dBc Hz at Specified Center Frequency CF Offset CF CF 1 GHz CF CF 10 MHz 2 GHz 6 GHz Typical Spec Typical Typical Typical 1 kHz 128 103 107 107 104 10 kHz 134 109 113 112 109 100 KHz 134 112 116 115 114 1 MHz 135 130 139 137 135 6 MHz 140 134 144 142 141 10 MHz NA 135 144 142 141 Integrated Phase 100 Hz to 100 MHz typical Measurement Integrated Phase Radians Frequency 100 MHz 2 91 x 103 1 GHz 3 14 x 10 3 2 GHz 3 77 x 10 3 5 GHz 6 28 x 10 3 spectrum Analyzers SPECMON Series Phase Noise Lit I 20 HENS HE MEE EBEN 410 in int m Re ir INT IT SnD limes NN 111 120 MT iii mai MELLIN REN S N Phase Noise dBc Hz oO EN 130 pilil aa ATT TIN NA 140 411111111 111111111 101 a ee IT SHH 150 bass 0 01 0 1 1 10 100 1
21. 969 25 1 11 4 200 1024 292 969 25 7 15 4 Minimum RBW Swept Spans Opt 200 10 kHz www tektronix comrsa 11 Datasheet Minimum FFT Length vs Trace Length Independent of Span and RBW Opt 200 Trace Length Points Minimum FFT Length Resolution BW Range vs Acquisition Bandwidth DPX Acquisition Stangar Bandwidth RBW Min RBW Min RBW Max 110 MHz Opt 110 640 kHz 20 kHz 10 MHz 55 MHz Opt 110 320 kHz 10 kHz 5 MHz 40 MHz 320 kHz 10 kHz 5 MHz Opt 40 110 25 MHz 214 kHz 10 kHz 3 MHz 20 MHz 107 kHz 5 kHz 2 MHz 10 MHz 53 3 KHZ 2 kHz 1 MHz 5 MHz 26 7 kHz 1 kHz 500 kHz 2 MHz 13 4 kHz 500 Hz 200 kHz 1 MHz 6 66 kHz 200 Hz 100 kHz 500 kHz 3 33 kHz 100 Hz 50 kHz 200 kHz 1 67 kHz 50 Hz 20 kHz 100 kHz 833 Hz 20 Hz 10 kHz 50 kHz 417 Hz 10 Hz 5 kHz 20 kHz 209 Hz 5 Hz 2 kHz 10 kHz 105 Hz 2 Hz 1 kHz 5 kHz 52 Hz 0 1 Hz 500 Hz 2 kHz 13 1 Hz 0 1 Hz 200 Hz 1 kHz 6 51 Hz 0 1 Hz 100 Hz 500 Hz 3 26 Hz 0 1 Hz 50 Hz 200 Hz 1 63 Hz 0 1 Hz 20 Hz 100 Hz 0 819 Hz 0 1 Hz 10 Hz Zero span Amplitude Frequency Phase Performance Nominal Characteristic Description Measurement BW Range 100 Hz to maximum acquisition bandwidth of instrument Time Domain BW TDBW Atleast 1 10 to 1 10 000 of acquisition bandwidth 1 Hz Range minimum Time Domain BW TDBW 1 Accuracy Sweep Time Range 100 ns minimum 1 s maximum Measurement BW gt 60 MHz 2000 s maximum Measurement BW lt 60 MHz Time Accuracy 0 5 Reference
22. B Band 9 kHz to 3 GHz 0 5 dB gt 3 GHz to 6 2 GHz 1 0 dB SPECMON6 Preamp On Atten 10 dB 10 MHz to 32 MHz LF 0 8 dB Band 1 MHz to 3 GHz gt 3 GHz to 6 2 GHz SPECMON6 0 8 dB 1 3 dB Amplitude Accuracy Characteristic Absolute Amplitude Accuracy at Calibration Point 100 MHz 20 dBm signal 10 dB ATT 18 C to 28 C Input Attenuator Switching 0 3 dB Uncertainty Absolute Amplitude Accuracy at Center Frequency 95 Confidence 2 Description 0 31 dB 10 MHz to 3 GHz 0 3 dB 3 GHz to 6 2 GHz 0 5 dB SPECMON6 VSWR Typical Atten 10 dB CF set within 200 MHz of VSWR frequency Frequency Range Preamp OFF Preamp ON 10 kHz to 10 MHz lt 1 6 1 10 MHz to 2 0 GHz lt 1 12 1 lt 1 6 1 gt 2 0 GHz to 3 0 GHz lt 1 3 1 lt 1 6 1 gt 3 0 GHz to 5 0 GHz lt 1 3 1 lt 1 6 1 SPECMON6 gt 5 0 GHz to 6 2 GHz lt 1 45 1 lt 1 6 1 SPECMON6 2 18 C to 28 C Ref Level lt 15 dBm Attenuator Auto coupled Signal Level 15 dBm to 50 dBm 10 Hz lt RBW lt 1 Mhz after alignment performed Noise and Distortion 3rd Order Intermodulation Distortion 84 dBc at 2 13 GHz Specified 3 3rd Order Intermodulation Distortion dBc 3rd Order Intercept Frequency Range Typical dBm Typical 10 KHz to 32 MHz LF 5 12 5 Band 9 kHz to 80 MHz 12 11 gt 80 MHz to 300 MHz 6 13 gt 300 MHz to 3 GHz 84 17 gt 3 GHz to 6 2 GHz 84 17 3 Each Signal Level 25 dBm Ref Level 2
23. BW Opt 40 40 ns ACQ BW 25 Mhz no TDBW Standard Timing Uncertainty Same as Power Trigger Position Timing Uncertainty Runt Trigger Runt Definitions Accuracy for trigger levels 0 5 dB level 2 50 dB from reference level gt 30 dB ab EN gt CEN aD SA AD PAs cc floor A o A 1 5 dB from lt 50 dB to 70 dB from reference level signal level Positive Negative Time qualified Triggering Trigger Types and Source Time qualification may be applied to Level Frequency Mask Opt 02 DPX Density Runt Frequency Edge Ext 1 Ext 2 Time Qualification Range T1 0 to 10 seconds T2 0 to 10 seconds Time Qualification Shorter than T1 Definitions Longer than T1 Longer than T1 AND shorter than T2 Shorter than T1 OR longer than T2 Holdoff Trigger Range 0 to 10 seconds Digital IQ Output Opt 55 Characteristic Description Connector Type MDR 3M 50 pin x 2 Data Output Data is corrected for amplitude and phase response in real time data 16 bit LVDS Q data 16 bit LVDS Clock LVDS Max 50 MHz 150 MHz Opt 55 DV Data Valid MSW Most Significant Word indicators LVDS IQ data output enabled connecting GND enables output of IQ data Clock Rising Edge to Data 8 4 ns typical standard 1 58 ns typical Opt 110 Transition Time Hold time Data Transition to Clock Rising Edge Setup time Data format Control Output Control Input 8 2 ns typical standard 1 54 ns typical Opt 110 AM
24. DMA HSUPA HSDPA GSM EDGE CDMA2000 1x CDMA2000 1xEV DO RFID Phase Noise Jitter IEEE 802 11 a b g n WLAN IEEE 802 15 4 OQPSK Zigbee Audio Analysis B X 1DPX Spectrum Peak EVM 1 501 3 271 112 00 Sym 36 474 dB 29 705 dB Phase Error 0 600 1 875 112 00 Sym Mag Error 1 075 2 868 149 00 Sym MER RMS 36 474 dB Rho 0 999775 IQ Origin Offset 52 742 dB Frequency Error 30 04 Hz i lance 0 012 dB Quadrature Error 0 108 100 00 dBm CF 2 70000 GHz Seles Channel Power and ACPR Freq Error 30 04 Hz Auto Avg Freq 10 0 00 dBm dB div 10 0 dB 100 00 dem 2 Pos 2 70000 GHz x va Channel ch Offset Low Upp er Main a1 2 500MHz 62 s dB 62 m dB dBm Time correlated views in multiple domains provide a new level of insight into design problems not possible with conventional analyzers Here ACLR and modulation quality are performed simultaneously in a single acquisition combined with the continuous monitoring of the DPX spectrum display lt Fail Ref 87 00 dBuV Normal Clear 86 99 dBuV I dB div 10 0 dB 13 01 dBuV Autoscale Start 9 000 kHz Stop 1 000 GHz Spur Rar Freq Abs 5 Ampl Rel 399 706731 kHz ARETY i u 15 62 dB 198 793269 kHz gai u 18 72 dB 500 163462 kHz K 4 uV 19 76 dB 299 250000 kHz ZASE MY A uV 24 35 dB Spurious Search U
25. Distortion Hum and Noise Direct Input Frequency 1 Hz to 156 kHz Range for audio measurements only Maximum Audio 156 kHz Frequency Span Audio Frequency 0 2 Hz Accuracy Signal Power Accuracy 1 5dB Residuals Rate 1 to 10 kHz Input Level 0 316 V THD 0 1 Distortion 0 1 SINAD 60 dB Phase Noise and Jitter Measurement Opt 11 Characteristic Carrier Frequency Range 1 MHz to maximum instrument frequency Measurements Carrier Power Frequency Error RMS Phase Noise Jitter Time Interval Error Residual FM See Phase Noise specifications Minimum Offset from Carrier 10 Hz Maximum Offset from Carrier 1 GHz Description Residual Phase Noise Phase Noise and Jitter Integration Bandwidth Range Number of Traces 2 Trace and Measurement Detection Average or Peak Functions Smoothing Averaging Optimization Speed or Dynamic Range www tektronix comrsa 13 Datasheet Settling Time Frequency and Phase Opt 12 14 Settled Frequency Uncertainty 95 Confidence Typical at Stated Measurement Frequencies Bandwidths and of Averages Measurement Frequency Uncertainty at Stated Measurement Frequency Bandwidth Averages 110 MHz 10 MHz 1 MHz 100 kHz 1 GHz Single 2 kHz 100 Hz 10 Hz 1 Hz Measurement 100 Averages 200 Hz 10 Hz 1 Hz 0 1 Hz 1000 Averages 50 Hz 2 Hz 1 Hz 0 05 Hz 10 GHz Single 5 kHz 100 Hz 10 Hz 5 Hz Measurement 100 Averages 300 Hz 10 Hz 1 Hz 0 5 Hz 1000 Averages 100 Hz 5 Hz 0 5 Hz
26. Hz Span 110 0 MHz Scale 203 413 us Autoscale DR C Pusetaae ei v 2 10 0 dB v Freg Error 518 1 Hz Auto Result PR Ampl dg Width IPR Amol IPR Time y 10 002149793 us 41 61017990 dB 4 0000014 u 10 001972441 us EI 72E 40000014 u 10 002072486 us 41 69377899 dB 4 0000014 u 10 002047020 us 41 90905762 dB 4 0000014 u 10 002090676 us 41 98531723 dB 4 0000014 u 10 001916962 us 41 49234772 dB 4 0000014 u 94 4 dB 1n AN19ANA 7 ic 41 OPSA PARS AR l4 u Ms 4 2 2 us Pulse Trace Freq 1 999999482 GHz gt Pulse 5 41 87 dB Scale 5 85 us Advanced Signal Analysis package offers over 20 automated pulse parameter calculations on every pulse Easily validate designs with measurements of peak power pulse width rise time ripple droop overshoot and pulse to pulse phase Gain insight into linear FM chirp quality with measurements such as Impulse Response and Phase Error A pulse train upper left is seen with automatic calculation of pulse width and impulse response lower right A detailed view of the Impulse Response is seen in the lower left and a DPX display monitors the spectrum on the upper right Measurements Description Flexible OFDM Analysis OFDM Analysis for WLAN 802 11a j g and WiMAX Opt 22 802 16 2004 DPX Density Measures signal density at any location on the Measurement Opt 200 DPX spectrum display and triggers on specified signal density RSAVu Analysis Software W C
27. MIL Residual EVM 22 4 kS s lt 0 3 CF 250 MHz 20 kS s lt 0 5 100 kS s lt 0 5 1 MS s lt 0 5 2 4 8 16 FSK Residual RMS FSK Error 23 10 kS s deviation 10 kHz lt 0 5 19 CF 2 GHz Measurement Filter root raised cosine Reference Filter raised cosine Analysis Length 200 symbols 20 CF 2 GHz Measurement Filter root raised cosine Reference Filter raised cosine Analysis Length 400 symbols 21 CF 2 GHz unless otherwise noted Reference Filters MIL STD ARTM Measurement Filter none 22 CF 2 GHz unless otherwise noted Reference Filter MIL STD 23 CF 2 GHz Reference Filter None Measurement Filter None www tektronix comrsa 15 Datasheet Adaptive Equalizer Characteristic Description Type Linear decision directed Feed forward FIR equalizer with coefficient adaptation and adjustable convergence rate BPSK QPSK OQPSK 11 2DBPSK m 4DQPSK 8PSK 8DPSK 16DPSK 16 32 APSK 16 32 64 128 256QAM Raised Cosine Rectangular None Modulation Types Supported Reference Filters for All Modulation Types except OQPSK Reference Filters for Raised Cosine Half Sine OQPSK Filter Length 1 to 128 taps Taps Symbol Raised 1 2 4 8 Cosine Half Sine No Filter Taps Symbol 1 Rectangular Filter Equalizer Controls Off Train Hold Reset Flexible OFDM Characteristics Opt 22 Characteristic Recallable Standards Parameter settings Description WiMAX 802 16 2004 WLAN 802 11 a
28. SK 16 32 64 128 256QAM MSK 2 FSK 4 FSK 8 FSK 16 FSK C4FM Up to 80 000 Samples Characteristic Modulation Formats Analysis Period Filter Types Measurement filters Square root raised cosine raised cosine Gaussian rectangular IS 95 IS 95 EQ C4FM P25 half sine None User Defined Raised cosine Gaussian rectangular IS 95 SBPSK MIL SOQPSK MIL SOQPSK ARTM None User Defined 0 001 to 1 0 001 step Constellation Error Vector Magnitude EVM vs Time Modulation Error Ratio MER Magnitude Error vs Time Phase Error vs Time Signal Quality Symbol Table rho FSK only Frequency Deviation Symbol Timing Error symbol Rate Range 1 kS s to 85 MS s Modulated signal must be contained entirely within acquisition BW Reference filters Alpha BxT Range Measurements spectrum Analyzers SPECMON Series Digital Opt 21 Symbol Rate Residual EVM Typical QPSK Residual EVM 19 100 kS s lt 0 35 1 MS s lt 0 35 10 MS s lt 0 5 30 MS s Opt 40 110 lt 1 5 60 MS s Opt 110 lt 2 0 256 QAM Residual EVM 20 10 MS s lt 0 4 30 MS s Opt 40 110 lt 1 0 60 MS s Opt 110 lt 1 5 Offset QPSK Residual EVM 19 100 kS s lt 0 4 1 MS s lt 0 4 10 MS s lt 1 3 S OQPSK MIL ARTM Residual EVM 21 4 kS s lt 0 3 CF 250 MHz 20 kS s lt 0 5 100 kS s lt 0 5 1 MS s lt 0 5 S BPSK MIL Residual EVM 22 4 kS s lt 0 2 CF 250 MHz 20 kS s lt 0 5 100 kS s lt 0 5 1 MS s lt 0 5 CPM
29. anges in frequency occupancy within the acquisition bandwidth A Power Trigger working in the time domain can be armed to monitor for a user set power threshold Resolution bandwidths may be used with the power trigger for band limiting and noise reduction Two external triggers are available for synchronization to test system events Capture Capture once make multiple measurements without recapturing All signals in an acquisition bandwidth are recorded into the SPECMON Series deep memory Record lengths vary depending upon the selected acquisition bandwidth up to 7 seconds at 110 MHz 343 seconds at 1 MHz or 6 1 hours at 10 kHz bandwidth with Memory Extension Opt 53 Real time capture of small signals in the presence of large signals is enabled with 73 dB SFDR in all acquisition bandwidths even up to 110 MHz Opt 110 Acquisitions of any length can stored in MATLAB Level 5 format for offline analysis Most spectrum analyzers in the market utilize narrowband tunable band pass filters often YIG tuned filters YTF to serve as a preselector These filters provide image rejection and improve spurious performance in swept applications by limiting the number of signals present at the first mixing stage YTF s are narrow band devices by nature and are usually limited to bandwidths less than 50 MHz These analyzers bypass the input filter when performing wideband analysis leaving them susceptible to image responses when operating in mo
30. ce 5 Years 18 www tektronix comrsa Upgrades SPECMONUP Upgrade Options for SPECMONS3 SPECMON6 Factory HW or Calibration SPECMONUP Option Description SW Required Opt 52 Frequency Mask Trigger SW No Opt 53 Memory Extension 4 GB Acquisition HW No Memory Total Opt 55 Digital IQ Output HW No Opt 09 Enhanced Real Time SW No Opt 10 AM FM PM Modulation and Audio SW No Measurements Opt 11 Phase Noise Jitter Measurements SW No Opt 12 Settling Time Frequency and Phase SW No Opt 21 General Purpose Modulation Analysis SW No Opt 22 Flexible OFDM Analysis SW No Opt 40 SPECMONS only 40 MHz Acquisition HW Yes Bandwidth Opt 110 110 MHz Acquisition Bandwidth HW Yes Opt 200 Advanced DPX Swept DPX with HW No Density Time Qualified and Runt Triggers and Zero span DPX Languages Option Description Opt LO English Manual Opt L5 Japanese Manual Opt L7 Simplified Chinese Manual Opt L10 Russian Manual Tektronix is registered to ISO 9001 and ISO 14001 by SRI Quality System Registrar N Qe GPI Product s complies with IEEE Standard 488 1 1987 RS 232 C and with Tektronix Standard Codes and Formats spectrum Analyzers SPECMON Series www tektronix comrsa 19 Datasheet www tektronix comrsa Contact Tektronix ASEAN Australasia 65 6356 3900 Austria 00800 2255 4835 Balkans Israel South Africa and other ISE Countries 41 52 675 3777 Belgium 00800 2255 4835 Brazil 55 11 3759 7627 Canada
31. d reducing time to fault Here three distinct pulse shapes are captured in zero span amplitude vs time Two of the three waveforms occur only once in 10 000 pulses but all are displayed with DPX www tektronix comrsa 5 Datasheet Bu wWes orbed pfs yya Locate ee with azimuth direction Erden It lets you ia a line or an arrow ona mapped measurement to indicate the direction your antenna was pointing when you take a measurement User label can also be displayed this example shows real time DPX measurement taken from Hospital School and Park Lot Te Weg gt 4 ea Re i tay p i 5 g N ei Ze j i ax TA ERA DPX E oPx p valey m DPX P a Sou Sere 7 et Si t E E Di i A a ve 7 Fez 3 Ben way 2 OR 10 F Founta 2 5 lt i i Suara n A ua 3 3 Apar mens Road st 300 tenes J te j A von i fas Beayeron Higi z n ped 5 He Schoal MY yarmieget j sia utes 7 ST irn i 5 E ia ne 2 ih B a g 2 5 gt cet weit inte P 5 f 4 Sop a A p s p t E 3 2 A E meat se B 3 w re 6 er X j 3 3 A Fo sgp 4 Z Zn A 3 OITV ELN Stinet gt 3 3 Both manual and automatic drive test measurements are supported The Repeat measurements function automatically takes measurements at a user set time or distance interval Integrated Solution for Mapping SPECMON series Real Time Spectrum Analyzers provi
32. de an integrated solution for field interference and coverage problems The built in RSA Map lets you use an on screen map to record the location and value of SPECMON measurements 6 www tektronix comrsa With RSA Map you can do the following Select a measurement and touch the displayed map where you want the measurement to be placed Use a GPS receiver customer supplied to automatically position measurements at your current location on maps with geophysical reference information Collect and export measurement data and position data when using a GPS receiver to common formats to help analyze measurements position value and direction and prepare reports to resolve interference problems RSA Map uses MapInfo format map files mif or Windows bitmap files bmp to indicate location The omp format map files can be either geo referenced or non geo referenced Saved test results give you complete measurement data along with exporting compatibility to Google Earth kmz and Mapinfo MIF MID formats Characteristics Frequency Related Characteristic Description Frequency Range 1 Hz to 3 0 GHz SPECMON3 1 Hz to 6 2 GHz SPECMONG Initial Center Frequency Within 10 7 after 10 minute warm up Setting Accuracy Center Frequency Setting 0 1 Hz Resolution Frequency Marker RE x MF 0 001 x Span 2 Hz Readout Accuracy RE Reference Frequency Error MF Marker Frequency Hz Span Accuracy 0 3 of Span Auto m
33. des where wideband analysis is required such as for real time signal analysis Unlike spectrum analyzers with YTF s Tektronix Real Time Signal Analyzers use a wideband image free architecture guaranteeing that signals at frequencies outside of the band to which the instrument is tuned don t create spurious or image responses This image free response is achieved with a series of input filters designed such that all image responses are suppressed The input filters are overlapped by greater than the widest acquisition bandwidth ensuring that full bandwidth acquisitions are always available This series of filters serves the purpose of the preselector used by other spectrum analyzers but has the benefit of always being on while still providing the image free response in all instrument bandwidth settings and at all frequencies www tektronix comrsa 3 Datasheet Analyze The SPECMON Series offers analysis capabilities that advance productivity for engineers working on components or in RF system design integration and performance verification or operations engineers working in networks or spectrum management In addition to spectrum analysis spectrograms display both frequency and amplitude changes over time Time correlated measurements can be made across the frequency phase amplitude and modulation domains This is ideal for signal analysis that includes frequency hopping pulse characteristics modulation switching settling time ba
34. e Humidity Operating and 90 RH at 30 C nonoperating No condensation max wet bulb 29 C 80 RH max when accessing DVD Vibration Operating 0 22 Grus Profile 0 00010 g2 Hz at 5 350 Hz 3 dB octave slope from 350 500 Hz 0 00007 g2 Hz at 500 Hz 3 Axes at 10 min axis CD DVD operation not specified under vibration spectrum Analyzers SPECMON Series Ordering Information SPECMON3 Real Time Signal Analyzer 1 Hz to 3 GHz SPECMON6 Real Time Signal Analyzer 1 Hz to 6 2 GHz All Include Quick start Manual Printed Application Guide Printed Printable Online Help File on CD Programmer s manual on CD power cord BNC N adapter USB Keyboard USB Mouse Front Cover One year Warranty Note Please specify power plug and language options when ordering Options Product Options Description SPECMON3 Real Time Spectrum Analyzer 1 Hz 3 GHz internal preamplifier 25 MHz real time bandwidth pulse analysis suite removable solid state drive 3 year warranty SPECMONG6 Real Time Spectrum Analyzer 1 Hz 6 2 GHz internal preamplifier 40 MHz real time bandwidth pulse analysis suite removable solid state Nonoperating 2 28 Grus Profile 0 0175 g2 Hz at 5 100 Hz 3 dB octave from 100 200 Hz 0 00875 g2 Hz at 200 350 Hz 3 dB octave from 350 500 Hz 0 00613 g2 Hz at 500 Hz 3 Axes at 10 min axis Shock Operating 15 G half sine 11 ms duration 1 G max when accessing DVD and Opt 06 Removable HDD Nonoperat
35. ggered the DPX Density Trigger the frequency domain view right panel automatically updates to show the detailed spectrum view at that precise moment in time Trigger Tektronix has a long history of innovative triggering capability and the SPECMON Series spectrum analyzers lead the industry in triggered signal analysis The SPECMON Series provides unique triggers essential for troubleshooting modern digitally implemented RF systems Includes time qualified power runt density frequency and frequency mask triggers Time qualification can be applied to any internal trigger source enabling capture of the short pulse or the long pulse in a pulse train or when applied to the Frequency Mask Trigger only triggering when a frequency spectrum Analyzers SPECMON Series domain event lasts for a specified time Runt triggers capture troublesome infrequent pulses that either turn on or turn off to an incorrect level greatly reducing time to fault DPX Density Trigger works on the measured frequency of occurrence or density of the DPX display The unique Trigger On This function allows the user to simply point at the signal of interest on the DPX display and a trigger level is automatically set to trigger slightly below the measured density level You can capture low level signals in the presence of high level signals at the click of a button The Frequency Mask Trigger FMT is easily configured to monitor all ch
36. gnal behavior that helps you discover instability glitches and interference Here three distinct signals can be seen Two high level signals of different frequency of occurrence are seen in light and dark blue and a third signal beneath the center signal can also be discerned The DPX Density trigger allows the user to acquire signals for analysis only when this third signal is present Trigger On This has been activated and a density measurement box is automatically opened measuring a signal density 7 275 Any signal density greater than the measured value will cause a trigger event EX DPX Spectrum Peak Normal Y 7 Bitmap M Show On Scale 2 Bane at 1 280 s MR 82 57 dBm FSO GEM Mr 4 096 HES Mese 2445312852 GHz dBjdiv 2 445312852 GHz U I RK FL RBW 519 000 us 12 00 dBm VE SISOS 9 854 m peepee 10 0 dB ae AWAY Pate O vew en 100 kee Overlap 75 109 50 dm E 2 2 CF 2 44673 GHz 2 Span 10 00 MHz Time Overview 4 Era 9 50 dBm Actual 2 000 ms 0 100 dB Pos 2 1 976 ms CF 2 44673 GHz 10 50 dBm gt Span 10 00 MHz Position 0 000 s Scale 2 000 ms Trigger and Capture The DPX Density Trigger monitors for changes in the frequency domain and captures any violations into memory The spectrogram display left panel shows frequency and amplitude changing over time By selecting the point in time in the spectrogram where the spectrum violation tri
37. ing 30 G half sine 11 ms duration Safety UL 61010 1 2004 CSA C22 2 No 61010 1 04 Electromagnetic EU Council EMC Directive 2004 108 EC Compatibility EN61326 CISPR 11 Class A Complies with Power Requirements Power Consumption Data Storage Calibration Interval Warranty GPIB 90 Vac to 264 Vac 50 Hz to 60 Hz 90 Vac to 132 Vac 400 Hz 450 W max Internal HDD Opt 59 USB ports DVD R CD RW Opt 57 Removable HDD Opt 56 One year One year SCPI compatible IEEE488 2 compliant drive 3 year warranty Physical Characteristics Dimensions mm in Height 282 11 1 Width 413 18 6 Depth 531 20 9 Weight kg Ib With All Options 24 6 54 Note Physical characteristics with feet Opt 52 Frequency Mask Trigger Opt 53 Memory Extension 4 GB Acquisition Memory Total Opt 55 Digital and Q output Opt 09 Enhanced Real Time Opt 10 AM FM PM Modulation and Audio Measurements Opt 11 Phase Noise Jitter Measurement Opt 12 Settling Time Frequency and Phase Opt 21 General Purpose Modulation Analysis Opt 22 Flexible OFDM Analysis Opt 40 40 MHz Acquisition Bandwidth SPECMON3 only Opt 110 110 MHz Acquisition Bandwidth Opt 200 Advanced Triggers Swept DPX and DPX Zero Span RSA56KR Rackmount for RSA5K RSA6K SPECMON Real Time Analyzers Accessories Accessory Description RTPA2A Spectrum Supports TekConnect probes P7225 P7240 Analyzer Probe Adapter P7260 P7330 P7313 P7313SMA P7340A compatibility P7350
38. ion Number of Pulses 1 to 10 000 system Rise Time lt 40 ns standard lt 17 ns Opt 40 lt 12 ns Opt 110 Typical Pulse Measurement Signal Conditions Unless otherwise stated Pulse Accuracy Width gt 450 ns 150 ns Opt 110 S N Ratio 230 dB Duty Cycle 0 5 to 0 001 Temperature 18 C to 28 C Measurement Range 15 to 40 dB across the width of the chirp Measurement Accuracy typical 2 dB for a signal 40 dB in amplitude and delayed 1 to 40 of the pulse chirp width 15 Taylor Window Impulse Response Impulse Response Weighting 15 Chirp Width 100 MHz Pulse Width 10 us minimum signal delay 1 of pulse width or 10 chirp bandwidth whichever is greater and minimum 2000 sample points during pulse on time Pulse Measurement Performance Pulse Amplitude and Timing Measurement Average On Power 6 Average Transmitted Accuracy Typical 0 3 dB Absolute Amplitude Accuracy 0 4 dB Absolute Amplitude Accuracy Power 16 Peak Power 6 0 4 dB Absolute Amplitude Accuracy Pulse Width 3 of reading Duty Factor 3 of reading 16 Pulse Width gt 300 ns 100 ns Opt 110 SNR 230 dB Frequency and Phase Error Referenced to Nonchirped Signal At stated frequencies and measurement bandwidths typical CF RMS Freg Err Pulse to Pulse to Bandwidth Pulse Freq Pulse Phase 20 MHz 2 GHz 7 kHz 12 kHz 0 3 10 GHz 16 kHz 40 kHz 0 75 20 GHz 40 kHz 110 kHz 1 8 60 MHz 2 GHz 26 kHz 80 kHz
39. ivileges reserved TEKTRONIX and TEK are registered trademarks of Tektronix Inc All other trade names referenced are the service marks trademarks or registered trademarks of their respective companies 28 Jun 2013 37W 28248 1 Tektronix
40. ndwidth changes and intermittent signals The measurement capabilities of the SPECMON Series and available options and software packages are summarized below Measurement Functions Measurements Description Spectrum Analyzer Channel Power Adjacent Channel Power Multicarrier Measurements Adjacent Channel Power Leakage Ratio Occupied Bandwidth xdB Down dBm Hz Marker dBc Hz Marker Time Domain and RF IQ vs Time Power vs Time Frequency vs Time Statistical Measurements Phase vs Time CCDF Peak to Average Ratio Spur Search Up to 20 frequency ranges user selected detectors Measurement Peak Average QP filters RBW CISPR MIL and VBW in each range Linear or Log frequency scale Measurements and violations in absolute power or relative to a carrier Up to 999 violations identified in tabular form for export in CSV format Amplitude Modulation Total Frequency Modulation Peak Peak Peak RMS Peak Peak 2 Frequency Error Phase Modulation Peak RMS Peak Peak AM FM PM Modulation Carrier Power Frequency Error Modulation Frequency and Audio Measurements Modulation Parameters Peak Peak Peak 2 RMS Opt 10 SINAD Modulation Distortion S N THD TNHD Phase Noise and Jitter 10 Hz to 1 GHz Frequency Offset Range Log Measurements Opt 11 Frequency Scale Traces 2 Peak Trace Average Trace Trace smoothing and Averaging Settling Time Frequency Measured Frequency Settling Time from las
41. ode Reference Frequency Initial accuracy atcal 1x 10 7 after 10 minute warm up Aging per day 1 x 10 9 after 30 days of operation Aging per 10 years 3 x 10 7 after 10 years of operation Temperature drift 2 x 10 8 5 to 40 C Cumulative error 4 x 10 7 within 10 years after calibration typical temperature aging Reference Output Level gt O dBm internal or external reference selected 4 dBm typical External Reference Input 10 MHz 30 Hz Frequency External Reference Input Spurious level on input must be lt 80 dBc within Frequency Requirements 100 kHz offset to avoid on screen spurs Spurious lt 80 dBc within 100 kHz offset Input level range 10 dBm to 6 dBm Trigger Related Characteristic Description Trigger Modes Free Run Triggered FastFrame Trigger Event Source RF Input Trigger 1 Front Panel Trigger 2 Rear Panel Gated Line Trigger Types Power Std Frequency Mask Opt 52 Frequency Edge DPX Density Runt Time Qualified Opt 200 Trigger Setting Trigger position settable from 1 to 99 of total acquisition length Trigger Combinational Trig 1 AND Trig 2 Gate may be defined as a trigger Logic event Trigger Actions Save acquisition and or save picture on trigger Power Level Trigger Characteristic Level Range Accuracy for trigger levels gt 30 dB above noise floor 10 to 90 of Description 0 dB to 100 dB from reference level 0 5 dB level 50 dB from reference level
42. p to 20 noncontiguous frequency regions can be defined each with their own resolution bandwidth video bandwidth detector peak average quasi peak and limit ranges Test results can be exported in CSV format to external programs with up to 999 violations reported Spectrum results are available in linear or log scale Freg Error 197 8 Hz Auto Peak Normal 100 kHz Position 0 000 Hz Spectrum 100 kHz 114 00 dBm i 33 2 kHz 2 Position 16 000 ms 2 Scale 200 000 ms 2 CF 100 300 MHz Span 2 000 MHz i 96 1kHz Pki B9 1kHe Pk pki2 92 6kH2 Pk Pk 185 kHz Audio monitoring and modulation measurements simultaneously can make spectrum management an easier faster task Here the DPX spectrum display shows a live spectrum of the signal of interest and simultaneously provides demodulated audio to the internal instrument loudspeaker FM deviation measurements are seen in the right side of the display for the same signal y 7 Trace2 show Avg VRMS Avg 10 iclear 2 105 00 dBc Hz dB div 5 00 dB Marker 20 00 kHz 155 00 dBc Hz autoscale gt 1 000 kHz 10 00 MHz 1 Carrier power 10 30 dBm offset Trace 1 Trace 2 kreaiEtter 346 5MH2 kHz 108 66 dBc Hz 111 46 dBc Hz RMS Phase Noise 0 0801 10kHz 119 47 dBcfHe 122 46 dBc Hz mE ae 100kHz 117 46 dBc Hz 120 81 dBc Hz Residual FM 6 563 kKH2 a ie 125 11 dBc Hz 130 89 dBc Hz 10MHz 123 94 dBc H
43. rrier Power Audio Frequency Modulation Depth Peak Peak Peak Peak 2 RMS SINAD Modulation Distortion S N Total Harmonic Distortion Total Non harmonic Distortion Hum and Noise Carrier Power Accuracy 0 85 dB 10 MHz to 2 GHz 20 to 0 dBm input power spectrum Analyzers SPECMON Series Description 0 2 0 01 x measured value Characteristic AM Depth Accuracy Rate 1 to 100 kHz Depth 10 to 90 AM Rate Accuracy 0 2 Hz Rate 1 kHz to 1 MHz Depth 50 Residuals AM THD 0 16 Distortion 0 13 SINAD 58 dB PM Modulation Analysis PM Measurements Carrier Power Carrier Frequency Error Audio Frequency Deviation Peak Peak Peak Peak 2 RMS SINAD Modulation Distortion S N Total Harmonic Distortion Total Non harmonic Distortion Hum and Noise Carrier Power Accuracy 0 85 dB 10 MHz to 2 GHz 20 to 0 dBm input power Carrier Frequency 0 2 Hz transmitter frequency x reference frequency Accuracy Deviation error 0 628 rad PM Deviation Accuracy Rate 1 to 20 kHz Deviation 0 628 to 6 rad PM Rate Accuracy Rate 0 2 Hz 1 to 10 kHz Deviation 100 x 0 005 rate 1 MHz 0 628 rad Residuals PM Rate 1 to 10 kHz Deviation 0 628 rad THD 0 1 Distortion 1 SINAD 40 dB Direct Audio Input Audio Measurements Signal Power Audio Frequency Peak Peak Peak Peak 2 RMS SINAD Modulation Distortion S N Total Harmonic Distortion Total Non harmonic
44. ry Opt 22 EVM or Power vs Carrier Symbol Table Binary or Hexadecimal Frequency Offset Signal analysis can be performed either at center Measurement frequency or the assigned measurement frequency up to the limits of the instrument s acquisition and measurement bandwidths 8 www tektronix comrsa RF Spectrum and Analysis Performance Bandwidth Related Characteristic Resolution Bandwidth Resolution Bandwidth Range Spectrum Analysis Resolution Bandwidth Shape Resolution Bandwidth Accuracy Alternative Resolution Bandwidth Types Video Bandwidth Video Bandwidth Range RBW VBW Maximum RBW VBW Minimum Resolution Accuracy Typical Detector Average Description 0 1 Hz to 5 MHz 10 MHz Opt 110 1 2 3 5 sequence Auto coupled or user selected arbitrary Approximately Gaussian shape factor 4 1 1 60 3 dB 10 typical 1 Auto coupled RBW mode Kaiser window RBW 6 dB Mil CISPR Blackman Harris 4B Window Uniform none Window Flat top CW Ampl Window Hanning Window 1 Hz to 5 MHz plus wide open 10 000 1 1 1 plus wide open 5 Of entered value 10 Time Domain Bandwidth Amplitude vs Time Display Time Domain Bandwidth Range Time Domain BW Shape Time Domain Bandwidth Accuracy At least 1 10 to 1 10 000 of acquisition bandwidth 1 Hz minimum lt 10 MHz approximately Gaussian shape factor 4 1 1 60 3 dB 10 typical 20 MHz 60 MHz Opt 110 shape factor lt 2 5 1
45. se of use platform improves field test efficiency and lowers system training cost 10 4 inch ultra bright touchscreen display Windows 7 Ultimate 64 bit with support to Microsoft language localization Applications Spectrum Management Reduce Time to Intercept and Identify Known and Unknown Signals lektronix Datasheet Integrated Real Time Solution to Your Toughest Field Interference Challenges CF 1 000 GHz 2 Span 1 000 GHz Advanced Triggers and Swept DPX re invents the way swept spectrum analysis is done The DPX engine collects hundreds of thousands of spectrums per second over a 110 MHz bandwidth Users can sweep the DPX across the full input range of the SPECMON Series up to 6 2 GHz In the time a traditional spectrum analyzer has captured one spectrum the SPECMON Series has captured orders of magnitude more spectrums This new level of performance reduces the chance of missing time interleaved and transient signals during broadband searches 2 CF 2 4500 GHz Span 150 0 MHz Advanced Triggers Swept DPX and Zero Span Opt 200 provides superior swept spectrum analysis for transient signals Here a 150 MHz swath of spectrum is swept across the ISM band Multiple WLAN signals are seen and narrow signals seen in the blue peak hold trace are Bluetooth access probes Multiple interfering signals are seen below the analyzers noise level in the multi color DPX display 2 www tektronix comrsa Spectrums
46. t settled and Phase Opt 12 frequency Settling Time from last settled phase Settling Time from Trigger Automatic or manual reference frequency selection User adjustable measurement bandwidth averaging and smoothing Pass Fail Mask Testing with 3 user settable zones Average On Power Peak Power Average Transmitted Power Pulse Width Rise Time Fall Time Repetition Interval Seconds Repetition Interval Hz Duty Factor Duty Factor Ratio Ripple dB Ripple Overshoot dB Overshoot Droop dB Droop Pulse Pulse Frequency Difference Pulse Pulse Phase Difference RMS Frequency Error Max Frequency Error RMS Phase Error Max Phase Error Frequency Deviation Delta Frequency Phase Deviation Impulse Response dB Impulse Response Time Time Stamp Error Vector Magnitude EVM RMS Peak EVM vs Time Modulation Error Ratio MER Magnitude Error RMS Peak Mag Error vs Time Phase Error RMS Peak Phase Error vs Time Origin Offset Frequency Error Gain Imbalance Quadrature Error Rho Constellation Symbol Table Analog Modulation Analysis Measurement Functions Advanced Pulse Measurements Suite General Purpose Digital Modulation Analysis Opt 21 4 www tektronix comrsa 7 Bitmap M Show On 2 0 00 dBm o Edi 200 000 us Actual 200 000 2 0 00 dBm gt dB div dBjdiv es 10 0 dB RBW 1 00 MHz 100 00 dBm es 00 dBm Position 0 on S gt CF 2 0000 G
47. tions on Opt 52 Frequency Mask Trigger and Opt 200 DPX Time Qualified Runt and Frequency Edge triggers spectrum Analyzers SPECMON Series Acquisition Related Characteristic Real time Acquisition Bandwidth A D Converter Opt 40 110 Acquisition Memory Size Minimum Acquisition Length Description 25 MHz Std 40 MHz Opt 40 110 MHz Opt 110 100 MS s 14 bit optional 300 MS s 14 bit 1 GB 4 GB Opt 53 64 Samples Acquisition Length Setting 1 Sample Resolution Fast Frame Acquisition Mode gt 64 000 records can be stored in a single acquisition for pulse measurements and spectrogram analysis Memory Depth Time and Minimum Time Domain Resolution Acquisition Sample Rate Record Record Time BW For land Q Length Length Resolution Opt 53 110 MHz 150 MS s 1 79 s 7 15 5 6 6667 ns Opt 110 40 MHz 75 MS s 3 57 S 14 3 s 13 33 ns Opt 40 25 MHz 50 MS s 477s 19 0 s 20 ns 20 MHz 25 MS s 9 54 s 38 1 s 40 ns 10 MHz 12 5 MS s 19 0 s 76 3 S 80 ns 5 MHz 6 25 MS s 38 1 s 152 7 s 160 ns 2 MHz 3 125 MS s 42 9 s 171 7 S 320 ns 1 MHz 1 56 MS s 85 8 s 343 5 s 640 ns 500 kHz 781 kS s 171 7 S 687 1 s 1 28 us 200 kHz 390 kS s 343 5 s 1347 s 2 56 US 100 kHz 195 kS s 687 1 s 2748 s 5 12 us 50 kHz 97 6 kS s 1374 s 55497 s 10 24 us 20 kHz 48 8 kS s 2748 s 10955 s 20 48 us 10 kHz 24 4 kS s 5497 s 21990 s 40 96 us 5 kHz 12 2 kS s 10955 s 43980 s 81 92 us 2 kHz 3 05 kS s 43980 s 175921 s 328 US 1
48. z 131 54 dBc Hz Phase noise and jitter measurements Opt 11 on the SPECMON Series may reduce the cost of your measurements by reducing the need for a dedicated phase noise tester Outstanding phase noise across the operating range provides margin for many applications Here phase noise on a 13 MHz carrier is measured at 119 dBc Hz at 10 kHz offset The instrument phase noise of lt 134 dBc Hz at this frequency provides ample measurement margin for the task Spectrum Analyzers SPECMON Series 7 Trace1 M Show Peak Avg 2 3 5000 MHz Position 1 0000 MHz 1 5000 MHz U Position 100 000 u Scale 322 080 us Settling Time s Settled Freg 2 445320 GHz from Trigger 78 28 us Settling time measurements Opt 12 are easy and automated The user can select measurement bandwidth tolerance bands reference frequency auto or manual and establish up to 3 tolerance bands vs time for Pass Fail testing Settling time may be referenced to external or internal trigger and from the last settled frequency or phase In the illustration frequency settling time for a hopped oscillator is measured from an external trigger point from the device under test Pos 0 000 s gt Sweep 20 00 us DPX Zero span produces real time analysis in amplitude frequency or phase vs time Up to 50 000 waveforms per second are processed DPX Zero span ensures that all time domain anomalies are immediately foun
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