Anritsu TDOA simulation tool (Vers. 0.9)

[b]Introduction into scope and operation of Anritsu TDOA Simulation Tool[/b][br][justify]Welcome to Anritsu TDOA simulation tool. The purpose of the tool is to visualize the multilateration of an unknown transmitter using Time Difference On Arrival (TDOA). The unknown signal is emitted from a transmitter (TX) and it will generally arrive at slightly different times at two or more spatially separated receiver sites (e.g. RSM1 and RSM2). The locations of a constant Time Difference On Arrival being due to the different distances of each receiver from the RSM locations are forming a hyperbola. The intersection of different hyperbolas from different pairs of RSMs are equal to the calculated TX location. Somebody can imagine that the geometrical arrangement of a TDOA bearing base will have an important impact on the intersecting angle of the hyperbolas and thus the accuracy of the calculated emitter location. This tool is intuitively visualizing the results of a deploymenr of up to four Remote Spectrum Monitor in the field.[/justify][b]Tool operation and usage[/b][br][justify]The user can select between a default TDOA bearing base with 3 RSMs, or use up to 4 spectrum sensors. By drag /drop it is possible to change the location of the RSMs thus changing the geometry. It is also possible to change the TX location dragging green TX point to another location on the screen. The RSM deployment geometry together with the absolute RSM location precision is leading in addition of the inherent TDOA inaccuracies to additional error terms called Geometrical Dilution Of Precision (GDOP). [/justify][justify]By clicking the check boxes of the RSM paires (Red, Green, Purple and Light Blue), the user can activate the hyperbola calculation between a pair of RSMs. For instance, the first check box is activating the red hyperbola between RSM1 and RSM2. Green is used between RSM1 and RSM3, purple between RSM1 and RSM4. Finally Light Blue is representing the hyperbola between RSM2 and RSM3. [/justify][justify]The check boxes "Show TX" and "Show base line to TX" are revealing the bearing result. Clicking "RSM Distances" is displaying the distance in kilometers between the deployed sensors.In the next section clicking to "RSM n" is displaying the azimut against north, the distance to the TX location and Hata Model based radio pathloss from the RSM to the bearing target and in addition the max. pathloss that is based on receiver sensitivity calculation. The RX sensitivity based pathloss estimation is very useful in order to estimate if the RSM is able to "see" the target signal with a sufficient SNR or not. [/justify][justify]The selection of the signal parameters like radio frequency, signal bandwidth, CW-power and RSM as well as TX deployment heights are used as input parameters for the Hata Model pathloss calculation. [/justify]The RXPreAmp checkbox is influencing the RX noise floor and thus the sensitivity, which is resulting in a larger distance. For simulation purposes it is possible to switch TXPwr of the unknown signal between 30 (1 W) and 37 dBm (5 W).
Remote Spectrum Monitor (RSM) sensor deployment simulation tool
Background information about radio propagation and RSM sensitivity
[b]Background information about pathloss calculation and receiver sensitivity[/b][br]The Hata Model is a [url=https://en.wikipedia.org/wiki/Radio_propagation_model]radio propagation model[/url] for predicting the [url=https://en.wikipedia.org/wiki/Path_loss]path loss[/url] of cellular transmissions in exterior environments, valid for [url=https://en.wikipedia.org/wiki/Microwave]microwave[/url] frequencies from 150 to 1500 MHz. It is an empirical formulation based on the data from the [url=https://en.wikipedia.org/wiki/Okumura_Model]Okumura Model[/url], and is thus also commonly referred to as the Okumura–Hata model. The model incorporates the graphical information from Okumura model and develops it further to realize the effects of diffraction, reflection and scattering caused by city structures. Additionally, the Hata Model applies corrections for applications in suburban and rural environments. In the scope of our simulation we will use correction equations for [list][*]Open Terrain,[/*][*]Suburban Terrain,[/*][*]Small Cities and[br][/*][*]Large Cities areas[br][/*][/list]The model is usually restricted to the below given parameters:[br][list][*]Frequency: 150 – 1500 MHz[/*][*]Mobile Station Antenna height: 1 – 10 m (in our case the TX height)[/*][*]Base Station Antenna height: 30 – 200 m (in our case the RSM height)[/*][*]Link distance: 1 – 20 km[/*][/list][br][size=150][b]Calculation of max. possible pathloss based on given RX parameters[/b][/size][br][justify]In the following we will re-calculate the maximum possible pathloss between a Remote Spectrum Monitor (RSM) and the transmitter under investigation. The theory behind is based on [url=https://www.researchgate.net/profile/Sourabh_Bharti_3-IIITM/post/How_can_I_find_sensing_range_of_sensor_node_based_on_its_energy/attachment/59d63e39c49f478072ea8f3e/AS:273767446581257@1442282653853/download/path-loss-calculations.pdf]AXONN RF Path Loss & Transmission Distance Caluculations[/url]. But before discussing path loss relevant distances, we need to define the receive sensitivity of a Remote Spectrum Monitor. A seven step process will guide you through the idea [br]behind.[/justify][list=1][*]Estimate or measure signal bandwidth of signal under interest (Bw [kHz])[br][br][/*][*]Calculation of typical RSM noise floor for observed signal[br]E1: P[sub]RXNoise[/sub] = -174 dBm/Hz + 10log[sub]10[/sub](BwSignal [Hz])[br] [u]Example:[/u] A signal with an equivalent noise bandwidth of 25 kHz will result in [br] a -130 dBm RSM channel noise floor[br][br][/*][*]The minimum noise floor of a Remote Spectrum Monitor is equal to E2:[br]E2: RX[sub]min[/sub] = -174 dBm/Hz + 10 log[sub]10[/sub](RBW [Hz]) + NF[sub]RX[/sub] + Cable Loss[br] [u]Example:[/u] For a typical RBW of 3 kHz RXmin = -139 dBm + NFRX + Cable Loss[br]For successful TDOA it is necessary to "see" the signal under interest with some margin above the min. receiver noise floor. In this simulation tool the Signal-To-Noise Ratio (SNR) is set by default to 6 dB .[br]E3: RX’min = RXmin + 6 dB + Cable Loss = -139 dBm + NFRX + 6 dB + Cable Loss[br] [u]Example:[/u] With SNR 6 dB the above min. noise floor and a Cable Loss of -1 dB[br] RX’min rises up to -132 + NFRX[br][br][/*][*]In a spectrum analyzer (SPA) the min. noise floor is influenced by the input attenuation, the use of a pre-amplifier and the resolution bandwith (RBW) setting. With below given parameters some-body can now conclude on a real figure for RX’min.[br]• RSM RX Sensitivity (DANL) = -150 dBm/Hz[br]• PreAmp Gain = 12 dB (be aware that the PreAmp gain is frequency band dependent)[br] @ 100 MHz 6 dB[br] @ 400 MHz 8 dB[br] @ 800 MHz 9 dB[br] @ 1000 MHz 9 dB[br] @ 1500 MHz 11 dB[br] @ 2000 MHz 13 dB[br] @ 3000 MHz 13 dB[br]• example of typical sensitivity performance with 1 Hz VBW and RMS detector[br] DANL @ 400 MHz [br] - without PreAmp with 10 Hz RBW = 137,5 dBm ↦ 147 dBm/Hz[br] - with PreAmp with 10 Hz RBW = 155,0 dBm ↦ 165,0 dBm/Hz [br] DANL @ 1000 MHz[br] - without PreAmp with 10 Hz RBW = 136 dBm ↦ 146 dBm/Hz[br] - with PreAmp with 10 Hz RBW = 154 dBm ↦ 164 dBm/Hz [br]• From above somebody can estimate the inherent Noise Figure of the RX frontend[br] - RSM Noise Figure without PreAmp = 17 dB[br] - RSM Noise Figure with PreAmp = 9 dB[br][br]• In our above example receiver sensitivity at e.g. 400 MHz, RBW 3 kHz, SNR 6 dB, [br] RX Cable Loss 1 dB and no antenna gains is resulting[br] - without PreAmp in -115 dBm[br] - with PreAmp in -123 dBm[br][br][/*][*]The ideal line of sight based pathloss (L’P) between a receiver (RX) and a transmitter (TX) is based on the TX output power (PT), the total of all antenna gains (G) and cable losses (CL) on both sides and the min. noise floor of the receiver RX’min. In other words, by knowing the receive threshold it is possible to calculate the max. pathloss and to recalculate the corresponding distance.[br][br]E4: L’P = P’T + GTOT – RX'min with[br][br]PT = CW TX power; user can select 0,5 W (27 dBm) or 5 W (37dBm)[br]P’T = PT – 10log10(BwSignal) (as the power goes down with the bandwidth)[br]GTOT = total of all antenna gains, minus total of all cable losses - 1 dB[br] GRSM = 0 dB     RSM cable loss = -1 dB[br] GTX = 0 dB        TX cable loss = 0 dB[br][u]Example:[/u] L’P = 27 dBm – 10log10(25000) + (-1 dB) -(-115 dBm) = 97 dB[br][br]Using E5 it is now possible to recalculate the corresponding distance. In our case 4,4 km.[br][br]E5: L'P Free Space = 32,45 20log10(d [km]) + 20log10(f [MHz])[br][br][/*][*]As the view of point 5. is just based on ideal free space performance, we will now apply the rules of the Hata Model in order to come to a more realistic estimation. Input parameters for the Hata Propagation Model are:[br]• RF = radio Frequency[br]• PTX CW = CW TX output power[br]• GTOT = total of all antenna gains, minus total of all cable losses[br]• hRSM = RSM antenna height above ground [br]• hTX = TX antenna height above ground[br]• RX’min = min. RX sensitivity[br]Now it is possible to[br]• re-calculate the distance d'i [km] that corresponds with the above parameters, and then[br]• calculate the pathlosses di [km] based on given distances between RSMn and TX location [br] that was calculated by the TDOA hyperbola intersections [br][br][/*][*]Comparison of d’i in relation to di is a measure if the max. possible pathloss that is based on the system parameters is violated due to a too large distance between RSM and TX.[br]d > d’ ↦ critical, because the TX location is more far away as allowed by above calculations[br]d < d’ ↦ good use case, resulting SNR might even be higher[/*][/list]
You can find more information about Anritsu Spectrum Monitoring products in the following section
[size=100][b][color=#6aa84f][size=200][size=150]Hardware Platform Overview[/size][/size][/color][/b][br]All hardware platforms are available up to 6 GHz. There is no need for any additional software in order to run spectrum analyzer like basic operations[br][list][*]MS27100A OEM PCB board for system integrators[br][/*][*]MS27101A RSM with 1/2 19" rack, 1 HE form factor with 1 antenna port[/*][*]MS27102A RSM IP 67 sealed for outdoor applications with up to 6 antenna ports[/*][*]MS27103A RSM with 19" rack, 3 HE form factor with 12 or 24 antenna ports[br][/*][/list][br]For RSM operation you need the following accessories (min. requirements):[br][list][*]12 V DC, 11 W PSU or POE[br][/*][*]GPS antenna (autodetect of 3,3 V or 5,5 V DC active antennas)[br][/*][*]receive antenna[br][/*][*]internet access (wired or wireless)[br][/*][/list][br]The following software platforms are optional and allow operation of the given hardware based options:[br][br][list][*][b][color=#6aa84f]MX28001A VISION[/color][/b][/*][/list]  Opt. 400 Data Interface for MX28001A and MX280010A[br]  Opt. 401   PDOA & TDOA multilateration[br]   Opt. 479   AM/FM demodulation with live streaming[br]   Opt. 407   High Speed Port Scanner[br]   Opt. 485   Frequency Occupancy Reports[br]   Opt. 486 Multi frequency radio coverage mapping[br][br][list][*][b][color=#6aa84f]MX28010A SpectraVision[/color][/b][/*][/list]   Opt. 464 TETRA Demodulation & Scanner[br]  Opt. 467   Universal Channel Scanner[br]   Opt. 471   SatCom Demodulation[br]   Opt. 472   Signal Identification Basic[br]   Opt. 473   Signal Identification Advanced[br]   Opt. 474   Channel Power Monitoring[br][br]There are also other products available for typical spectrum monitoring products above 6 GHz:[br][list][*]Spectrum Master MS2726C 9 kHz - 43 GHz (old model)[/*][*]Spectrum Master MS2720T 9 kHz - 43 GHz[/*][*]Spectrum Master MS2760A 9 kHz - 110 GHz[br][/*][/list]The MS2710xA hardware is compatible to the following [color=#6aa84f][b]TSCM software packages[/b][/color] form 3'rd party vendors:[br][list][*][url=https://www.radioinspector.com/]RadioInspector[/url][br][/*][*][url=http://www.inradios.com/csm_csm-desktop.htm]INRADIOS CSM[/url][/*][*][url=http://www.kestreltscm.com/]KESTREL TSCM[/url] (only for MS2726C and MS2720T)[/*][/list][b][size=150][color=#6aa84f][br]Video Pods[/color][/size][/b][br]We recommend to watch the below video podcasts if you are interested in more details about the operation of the MS2710xA RSM hardware or the relevant [color=#6aa84f][b][url=https://www.anritsu.com/en-US/test-measurement/support/downloads?model=MX280001A]MS28001A VISION[/url][/b][/color] software packages[br][list][*][b]Anritsu RSM - Introducution into MS2710xA GUI[/b][br]You will learn how to operate the browser based GUI of MS2710xA including[br]setup definitions and alarm limit line definition[/*][/list]     High resolution video ([url=https://1drv.ms/v/s!Apjrf8bt2qXipllVm_4_yIficbG4]1980 x 1080[/url])[br]      Web video ([url=https://1drv.ms/v/s!Apjrf8bt2qXiploE8p1m0m3qVgwz]720 x 576[/url])[br][list][*][b]Anritsu RSM - Introduction into VISION operation[/b][br]You will learn how to set up a database with VSION in order to scan multiple frequency bands.[br]Beside you will be informed about the overall featurse settings that MS28001A offeres.[/*][/list]     High resolution video (coming soon)[br]     Web video (coming soon)[br][list][*][b]Anritsu RSM - MX28001A VISION based PDOA and TDOA geolocation[/b][br]You will learn the operation and difference between VISION database born Power [br]Difference On Arrival (PDOA) and online Time Difference On Arrival (TDOA) geolocation[/*][/list]      High resolution video (coming soon)[br]     Web video (coming soon) [br][list][*][b]Anritsu RSM - TDOA back to basics[/b][br]You will learn the fundamental principles of TDOA and its accuracy influencing parameters.[/*][/list]      High resolution video (coming soon)[br]     Web video (coming soon)[br][list][*][b]Anritsu RSM - RSM deployment scenarios[/b][br]You will learn the fundamental principles of radio propagation and why receiver sensitivity and radio path loss are setting the boundary conditions for signal interception. [/*][/list]      High resolution video (coming soon)[br]     Web video (coming soon)[br][list][*][b]Anritsu RSM - Drone detection and tracking systems[/b][br]You will learn how to configure MX28001A for drone detection and tracking.[/*][/list]      High resolution video (coming soon)[br]     Web video (coming soon)[br][br]Beside MX28001A there is another software avaialble that provides simple monitoring features, but sophisticated measurements and demodulation features. Similar to VISION, the basic software package of [color=#6aa84f][b][url=https://www.anritsu.com/en-US/test-measurement/support/downloads?model=MX280010A]SpectraVision MX28010A[/url][/b][/color] is free of charge. Please have a look into the below video podcasts if you are interested in more details about the operation and application of SpectraVision.[br][list][*][b]SpectraVision Opt. 467 Channel Scanner[/b][br]This video is showing the configuration of the SpectraVision Channel Scanner parameters.[/*][/list]     Web video ([url=https://1drv.ms/v/s!Apjrf8bt2qXiplvE2ApyF52HoLUp]1920 x 1080[/url])[br][list][*][b]SpectraVision Opt. 474 Channel Power Monitoring[/b][br]This video is showing the configuration of the SpectraVision Channel Power parameters.[/*][/list]     Web video ([url=https://1drv.ms/v/s!Apjrf8bt2qXiplyVsEYsMpsKRyEi]1920 x 1080[/url])[br][br][/size]
You can find more information about Anritsu Spectrum Monitoring products in the following section
[size=100]All hardware platforms are available up to 6 GHz. There is no need for any additional software in order to run spectrum analyzer like basic operations[br][list][*]MS27100A OEM PCB board for system integrators[br][/*][*]MS27101A RSM with 1/2 19" rack, 1 HE form factor with 1 antenna port[/*][*]MS27102A RSM IP 67 sealed for outdoor applications with up to 6 antenna ports[/*][*]MS27103A RSM with 19" rack, 3 HE form factor with 12 or 24 antenna ports[br][/*][/list][br]For RSM operation you need the following accessories (min. requirements):[br][br]12 V DC, 11 W PSU or POE[br]GPS antenna (autodetect of 3,3 V or 5,5 V DC active antennas)[br]receive antenna[br]internet access (wired or wireless)[br][br]The following software platforms are optional and allow operation of the given hardware based options:[br][br][list][*]MX28001A VISION[/*][/list]  Opt. 400 Data Interface for MX28001A and MX280010A[br] Opt. 401   PDOA & TDOA multilateration[br]  Opt. 479   AM/FM demodulation with live streaming[br] Opt. 407   High Speed Port Scanner[br] Opt. 485   Frequency Occupancy Reports[br] Opt. 486 Multi frequency radio coverage mapping[br][br][list][*]MX28010A SpectraVision[/*][/list]  Opt. 464 TETRA Demodulation & Scanner[br] Opt. 467   Universal Channel Scanner[br]  Opt. 471   SatCom Demodulation[br]  Opt. 472   Signal Identification Basic[br]  Opt. 473   Signal Identification Advanced[br] Opt. 474   Channel Power Monitoring[br][br]There are also other products available for typical spectrum monitoring products above 6 GHz:[br][list][*]Spectrum Master MS2726C 9 kHz - 43 GHz (old model)[/*][*]Spectrum Master MS2720T 9 kHz - 43 GHz[/*][*]Spectrum Master MS2760A 9 kHz - 110 GHz[br][/*][/list]The MS2710xA hardware is compatible to the following TSCM software packages form 3'rd party vendors:[br][list][*][url=https://www.radioinspector.com/]RadioInspector[/url][br][/*][*][url=http://www.inradios.com/csm_csm-desktop.htm]INRADIOS CSM[/url][/*][*][url=http://www.kestreltscm.com/]KESTREL TSCM[/url] (only for MS2726C and MS2720T)[/*][/list][br]videos[br][br][list][*]ADSad[br][/*][*]dADd[br][/*][/list][br][/size]
You can find more information about Anritsu Spectrum Monitoring products in the following section
[size=100]All hardware platforms are available up to 6 GHz. There is no need for any additional software in order to run spectrum analyzer like basic operations[br][list][*]MS27100A OEM PCB board for system integrators[br][/*][*]MS27101A RSM with 1/2 19" rack, 1 HE form factor with 1 antenna port[/*][*]MS27102A RSM IP 67 sealed for outdoor applications with up to 6 antenna ports[/*][*]MS27103A RSM with 19" rack, 3 HE form factor with 12 or 24 antenna ports[br][/*][/list][br]For RSM operation you need the following accessories (min. requirements):[br][br]12 V DC, 11 W PSU or POE[br]GPS antenna (autodetect of 3,3 V or 5,5 V DC active antennas)[br]receive antenna[br]internet access (wired or wireless)[br][br]The following software platforms are optional and allow operation of the given hardware based options:[br][br][list][*]MX28001A VISION[/*][/list]  Opt. 400 Data Interface for MX28001A and MX280010A[br] Opt. 401   PDOA & TDOA multilateration[br]  Opt. 479   AM/FM demodulation with live streaming[br] Opt. 407   High Speed Port Scanner[br] Opt. 485   Frequency Occupancy Reports[br] Opt. 486 Multi frequency radio coverage mapping[br][br][list][*]MX28010A SpectraVision[/*][/list]  Opt. 464 TETRA Demodulation & Scanner[br] Opt. 467   Universal Channel Scanner[br]  Opt. 471   SatCom Demodulation[br]  Opt. 472   Signal Identification Basic[br]  Opt. 473   Signal Identification Advanced[br] Opt. 474   Channel Power Monitoring[br][br]There are also other products available for typical spectrum monitoring products above 6 GHz:[br][list][*]Spectrum Master MS2726C 9 kHz - 43 GHz (old model)[/*][*]Spectrum Master MS2720T 9 kHz - 43 GHz[/*][*]Spectrum Master MS2760A 9 kHz - 110 GHz[br][/*][/list]The MS2710xA hardware is compatible to the following TSCM software packages form 3'rd party vendors:[br][list][*][url=https://www.radioinspector.com/]RadioInspector[/url][br][/*][*][url=http://www.inradios.com/csm_csm-desktop.htm]INRADIOS CSM[/url][/*][*][url=http://www.kestreltscm.com/]KESTREL TSCM[/url] (only for MS2726C and MS2720T)[/*][/list][br]videos[br][br][list][*]ADSad[br][/*][*]dADd[br][/*][/list][br][/size]
You can find more information about Anritsu Spectrum Monitoring products in the following section
[size=100]All hardware platforms are available up to 6 GHz. There is no need for any additional software in order to run spectrum analyzer like basic operations[br][list][*]MS27100A OEM PCB board for system integrators[br][/*][*]MS27101A RSM with 1/2 19" rack, 1 HE form factor with 1 antenna port[/*][*]MS27102A RSM IP 67 sealed for outdoor applications with up to 6 antenna ports[/*][*]MS27103A RSM with 19" rack, 3 HE form factor with 12 or 24 antenna ports[br][/*][/list][br]For RSM operation you need the following accessories (min. requirements):[br][br]12 V DC, 11 W PSU or POE[br]GPS antenna (autodetect of 3,3 V or 5,5 V DC active antennas)[br]receive antenna[br]internet access (wired or wireless)[br][br]The following software platforms are optional and allow operation of the given hardware based options:[br][br][list][*]MX28001A VISION[/*][/list]  Opt. 400 Data Interface for MX28001A and MX280010A[br] Opt. 401   PDOA & TDOA multilateration[br]  Opt. 479   AM/FM demodulation with live streaming[br] Opt. 407   High Speed Port Scanner[br] Opt. 485   Frequency Occupancy Reports[br] Opt. 486 Multi frequency radio coverage mapping[br][br][list][*]MX28010A SpectraVision[/*][/list]  Opt. 464 TETRA Demodulation & Scanner[br] Opt. 467   Universal Channel Scanner[br]  Opt. 471   SatCom Demodulation[br]  Opt. 472   Signal Identification Basic[br]  Opt. 473   Signal Identification Advanced[br] Opt. 474   Channel Power Monitoring[br][br]There are also other products available for typical spectrum monitoring products above 6 GHz:[br][list][*]Spectrum Master MS2726C 9 kHz - 43 GHz (old model)[/*][*]Spectrum Master MS2720T 9 kHz - 43 GHz[/*][*]Spectrum Master MS2760A 9 kHz - 110 GHz[br][/*][/list]The MS2710xA hardware is compatible to the following TSCM software packages form 3'rd party vendors:[br][list][*][url=https://www.radioinspector.com/]RadioInspector[/url][br][/*][*][url=http://www.inradios.com/csm_csm-desktop.htm]INRADIOS CSM[/url][/*][*][url=http://www.kestreltscm.com/]KESTREL TSCM[/url] (only for MS2726C and MS2720T)[/*][/list][br]We recommend to watch the below video podcasts if you are interested in more details about the operation of the RSM hardware or the relevant software packages[br][list][*]Anritsu RSM - Introducution into MS2710xA GUI[br]You will learn how to operate the browser based GUI of MS2710xA including[br]setup definitions and alarm limit line definition[/*][/list]     High resolution video ([url=https://1drv.ms/v/s!Apjrf8bt2qXipllVm_4_yIficbG4]1980 x 1080[/url])[br]      Web video ([url=https://1drv.ms/v/s!Apjrf8bt2qXiploE8p1m0m3qVgwz]720 x 576[/url])[br][list][*]Anritsu RSM - Introduction into VISION operation[br]You will learn how to set up a database with VSION in order to scan multiple frequency bands.[br]Beside you will be informed about the overall featurse settings that MS28001A offeres.[/*][/list]     High resolution video (coming soon)[br]     Web video (coming soon)[br][list][*]Anritsu RSM - MX28001A VISION based PDOA and TDOA geolocation[br]You will learn the operation and difference between VISION database born Power [br]Difference On Arrival (PDOA) and online Time Difference On Arrival (TDOA) geolocation[/*][/list]      a[br]     b [br][list][*]Anritsu RSM - TDOA back to basics[br]you will learn[/*][/list]      a[br]      b[br][list][*]Anritsu RSM - RSM deployment scenarios[br]You will learn[/*][/list]      a[br]      b[br][list][*]Anritsu RSM - Drone detection and tracking systems[br]You will learn[/*][/list]      a[br]      b[br][br][/size]

Information: Anritsu TDOA simulation tool (Vers. 0.9)