JP2011149809A - Cellular mobile phone positioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable high-accuracy measurement of a position of a mobile terminal by mutual communication, using a radio signal of a frequency assigned to a control channel between at least one base station and the mobile terminal, in a cellular mobile phone positioning system. <P>SOLUTION: A cell of the base station 101 is divided into four sectors, and directional antennas 21aa and 21ab are provided in a first sector; while two sets of directional antennas are provided in each remaining sector. In the mobile terminal 103, the phase of a distance-measuring signal transmitted from the base station 101 is measured, and the distance from the base station 101 is calculated; while the phase difference between direction measuring signals corresponding to the plurality of direction antennas 21aa and 21ab of the base station 101 is measured, and the direction where the base station is located is calculated. From the results of the calculation of the distance and the direction, the position of the mobile terminal 103 in any of one to three dimensions is measured with high accuracy. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

According to the present invention, in a cellular mobile phone positioning system, communication is performed between at least one base station and a mobile terminal using a radio signal having a frequency assigned to a control channel. The position can be measured with high accuracy.

Conventionally, a system that performs positioning using a plurality of base stations has been proposed. (For example, see Patent Documents 1 to 3)
JP 2009-066511 JP 2008-139292 A JP 2000-180528 A

FIG. 9 is an example of a conventional “current position positioning calculation method of a mobile communication terminal” described in Patent Document 1.
In FIG. 9, there is provided a method for calculating the current position of a mobile communication terminal that accurately measures the location of a mobile communication terminal such as a PHS terminal or a mobile phone terminal using the electric field strength of a fixed base station. . In a mobile communication terminal position search method for determining a current position of a mobile communication terminal by measuring an electric field intensity generated by a fixed base station equipped with a transceiver, each mobile station can measure radio waves. The position where the difference between the total distance from the mobile communication terminal calculated from the measured electric field strength to each base station and the total distance between the calculated point and each base station is the smallest is the current position. A method for calculating the current position of a mobile communication terminal using the least square method is provided.

  As described above, the conventional “method for calculating the current position of a mobile communication terminal” requires at least four base stations to perform three-dimensional positioning (at least three to perform two-dimensional positioning). In addition, since the electric field strength of the fixed base station is used for the location, there is a problem that it is susceptible to errors due to multipath or fading.

    On the other hand, the conventional “positioning system, program and position determination method for determining the position of a mobile radio station” described in Patent Document 2 realizes a simpler and smaller configuration for determining the position of a mobile radio terminal. To do. The devices (470, 370, 110, 120) for determining the position of the mobile radio stations (260 to 282) are the positions of the first reference radio stations (200 to 242) and the second reference radio stations (200 to 242). The position of the third reference radio station (200 to 242), the first relative angular direction between the mobile radio station and the first reference radio station, the mobile radio station and the second reference Means for determining a position of the mobile radio station from a second relative angular direction between the radio stations and a third relative angular direction between the mobile radio station and the third reference radio station; However, the positioning is performed by measuring only the relative angular directions from the plurality of reference radio stations, and there is a problem that it is difficult to perform positioning with high accuracy.

In addition, in the conventional “moving body positioning method and moving body positioning system” described in Patent Document 3, “the physical constraints of the position measuring device can be reduced, the maintainability is high, and there are no political restrictions. , Constructing a highly accurate and inexpensive LPS mobile positioning system, transmitting position specifying radio waves from one or a plurality of ground base stations A1, A2, A3, .... The relay mobile stations B1, B2, B3... Detect and recognize their own positions, and the position specifying radio waves from at least one relay mobile station B1, B2, B3. Receiving position specifying radio waves transmitted from one or a plurality of ground base stations A1, A2, A3,..., Detecting a relative phase difference, for example, a time difference, of the moving body M, and obtaining current position information of the moving body M To win. The relay mobile stations B1, B2, B3... Use an aircraft, a ship, an automobile or the like equipped with a receiver R, a position calculator P, a transmitter T, and a mobile, and a mobile object as a delay signal based on time data. It is said that it is configured to have an automatic position / time correction function so that it is transmitted to M. ”However, it is necessary to provide a relay mobile station, and only a distance is detected by detecting a relative phase difference, for example, a time difference. There are problems such as measuring.

The present invention relates to a cellular mobile phone system, wherein at least one base station arranged for each cell or each sector and the mobile phone system installed in the mobile body or carried by the mobile body Cellular mobile cellular phone positioning system for highly accurately positioning the position of any one of the one to three dimensions of the mobile terminal by mutual communication using radio signals of frequencies assigned to the control channels Is to realize at low cost.

  The cellular mobile phone positioning system according to the present invention is equipped with a plurality of directional antennas for each cell or sector and periodically switches at least a synchronization signal, an identification signal, and a distance for measuring a distance. A base station that arranges a radio signal including a measurement signal and a direction measurement signal for measuring a direction in each cell or sector and transmits the frequency using a pre-assigned control channel frequency, time slot, or both And a mobile terminal for performing positioning by receiving the radio signal, and the distance measurement signal is an origin signal included in a positioning request signal transmitted from the mobile terminal to the base station, Carrier signals, subcarrier signals, modulated signals, spread spectrum codes, or combinations thereof that are synchronized or orthogonal with accuracy,

  Alternatively, at least radio signals including a system synchronization signal, an identification signal, a distance measurement signal for measuring a distance, and a direction measurement signal for measuring a direction are allocated in advance for each cell or each sector. From a mobile terminal that transmits at a frequency of a control channel, a time slot, or both, and a base station that receives a radio signal and performs positioning while periodically switching by mounting a plurality of directional antennas A carrier signal, a subcarrier signal, a modulation signal, a spectrum, and a carrier signal, subcarrier signal, modulation signal, spectrum A spreading code, or a combination of these,

The distance measurement signal and the starting point signal are synchronized instantaneously and with high accuracy, and after the starting point signal disappears, synchronous oscillation means that can maintain synchronization for a relatively long time, and with high accuracy and real time By using a phase measuring means capable of measuring the phase, and calculating the distance between the at least one base station and the mobile terminal and the direction in which the terminals are located with high accuracy, any one of the one to three dimensions It is configured to measure the position of the dimension with high accuracy.

In the cellular mobile phone positioning system of the present invention, the frequency allocated to the control channel between the base station arranged for each cell or each sector and the mobile terminal installed in the mobile or carried by the mobile By the intercommunication according to the above, there is an advantage that a system for measuring the position of any one of the one to three dimensions of the mobile terminal with high accuracy and in real time can be realized at low cost.

  The cellular cellular phone positioning system according to the present invention is a cellular cellular phone using the control channel of the cellular phone system as shown in FIGS. 1, 3 and 1 of the first embodiment of the present invention. In the positioning system, the mobile terminal 103 for transmitting or receiving a radio signal having a frequency assigned to the control channel of the mobile phone system while moving, and at least one serving as a position reference arranged for each cell or sector Comprising two base stations 101,

  The portable terminal 103 includes at least an antenna switch 32, a signal generation unit 37, a transmitter 34, a receiver 33, a signal reproduction unit 35, a phase measurement unit 36, and a position calculation unit 38. The antenna switch 32 switches the antenna 31 to either a transmitter or a receiver in a time-sharing manner, and the signal generation means 37 includes a positioning request signal including at least a system synchronization signal, an identification signal, and an origin signal. And generate

  The transmitter 34 transmits a radio signal including the positioning request signal to the base station 101 as a burst signal, the receiver 33 receives a radio signal transmitted from the base station 101, and the signal The reproduction means 35 reproduces the distance measurement signal and the direction measurement signal from the radio signal received by the receiver 33, and the phase measurement means 36 uses the phase of the reproduced distance measurement signal and the direction measurement signal. And the position calculating means 38 measures the position of the own station from the measurement result of the phase,

  The base station 101 includes at least an antenna switch 19, a receiver 18, a signal regeneration unit 16, a synchronous oscillation unit 13, a signal generation unit 15, and a transmitter 17, and the antenna switch 19 However, the directional antennas 21a and 21b are periodically switched or switched to either the transmitter 17 or the receiver 18 in a time-sharing manner, and the positioning request signal transmitted from the portable terminal 103 is received by the receiver 18. Receive radio signals including

  The signal reproducing means 16 reproduces the starting signal included in the positioning request signal from the radio signal received by the receiver 18, and the synchronous oscillating means 13 is highly accurate and in a short time with the reproduced starting signal. The signal generation means 15 for measuring the direction separately from the distance measurement signal synchronized with or orthogonal to the output of the synchronous oscillation means 13 and the distance measurement signal. Direction measurement signal and

  In response to the positioning request signal transmitted from the mobile terminal, the transmitter 17 sends a radio signal including at least the distance measurement signal and the direction measurement signal to a base station arranged for each cell or each sector in advance. A plurality of directional antennas 21a, 21b are periodically switched at the assigned frequency, time slot, or both, and transmitted to the mobile terminal 103, and a starting signal transmitted from the mobile terminal, The distance measurement signal and the direction measurement signal transmitted from the base station are a single carrier or a plurality of carrier waves, subcarrier signals, modulation signals, spread spectrum codes, or combinations thereof that are synchronized or orthogonal,

  In the portable terminal 103, the phase of the distance measurement signal is measured to calculate the distance from the base station, the phase difference of direction measurement signals corresponding to a plurality of directional antennas of the base station is measured, and the base station The direction in which the station 103 is located is calculated, and the position of any one of the first to third dimensions of the mobile terminal 103 is determined with high accuracy from the distance calculation result and the direction calculation result. To do.

  In addition, as shown in FIGS. 1, 4 and 2 of the second embodiment of the present invention, in the cellular mobile phone positioning system using the control channel of the mobile phone system, the control of the mobile phone system is performed. A mobile terminal 103 for transmitting or receiving a radio signal having a frequency assigned to a channel in a time-division manner while moving, and at least one base station 101 that is arranged for each cell or each sector and serves as a position reference And

The base station 101 includes at least an antenna switch 19, a receiver 18, a signal generation unit 37, a transmitter 17, a signal reproduction unit 35, a phase measurement unit 36, and a position calculation unit 38. The antenna switch 19 periodically switches the directional antennas 21a and 21b, or switches to either the transmitter 17 or the receiver 18 in a time-sharing manner.
The signal generation unit 37 generates at least a system synchronization signal, an identification signal, and a positioning request signal including an origin signal, and the transmitter 17 transmits a radio signal including the origin signal to the portable terminal 103. Toward the base station 101 arranged for each cell or sector, and transmitted as a burst signal at a frequency, a time slot, or both pre-assigned,

  The receiver 18 transmits a radio signal transmitted from the portable terminal 103 in response to the positioning request signal to a frequency, a time slot, or the like assigned in advance to the base station 101 arranged for each cell or sector. In both cases, a plurality of directional antennas 21a and 21b are received while being switched periodically, and the signal reproduction means 35 reproduces a distance measurement signal and a direction measurement signal from a radio signal received by the receiver 18. The phase measurement unit 36 measures the phase of the reproduced distance measurement signal and the direction measurement signal, and the position calculation unit 38 measures the position of the mobile terminal 103 from the phase measurement result,

The portable terminal 103 includes at least an antenna switch 32, a receiver 33, a signal generation unit 15, a signal reproduction unit 16, a synchronous oscillation unit 13, and a transmitter 34, and the antenna switch 32 Switches the antenna 31 to either the transmitter 34 or the receiver 33 in a time-sharing manner,
The receiver 33 receives a radio signal transmitted at a frequency, time slot, or both pre-assigned to the base station 103, and the reproduction means 16 is a radio signal received by the receiver 33. From the signal, the starting signal included in the positioning request signal is reproduced, and the synchronous oscillation means 13 establishes synchronization with the reproduced starting signal signal with high accuracy and in a short time, and maintains the synchronization,

  The signal generation means 15 generates a distance measurement signal that is synchronized or orthogonal to the output of the synchronous oscillation means 13 and a direction measurement signal for measuring a direction separately from the distance measurement signal, and the transmitter 34, in response to the positioning request signal transmitted from the base station, a radio signal including at least the distance measurement signal and the direction measurement signal is assigned in advance to the base station 103 arranged for each cell or each sector. Transmit to the base station 103 in frequency, time slot, or both,

  The base station 101 measures the phase of the distance measurement signal to calculate the distance from the mobile terminal, and measures the phase difference of the direction measurement signals corresponding to the plurality of directional antennas of the base station to The direction of the position is calculated, and the position of any one of the first to third dimensions of the mobile terminal is determined with high accuracy from the calculation result of the distance and the calculation result of the direction.

  In addition, as shown in claim 3, the mobile terminal 103 transmits at least a radio signal including a location registration request signal, a call request signal, or an emergency call request signal, and receives the radio signal. Designates the portable terminal 103 and transmits a radio signal including at least a positioning request signal, and the base station 101 increases the position of any one of the one to three dimensions of the portable terminal 103. Position with accuracy.

  In addition, as shown in claim 4, the origin signal transmitted from the mobile terminal or the base station and the distance measurement signal and the direction measurement signal transmitted from the base station or the mobile terminal are single or synchronized, or A plurality of orthogonal carrier signals, subcarrier signals, modulated signals, spread spectrum codes, or combinations thereof.

  Further, as described in claim 5, in the signal reproducing means 16, 35, when the starting signal or measurement signal to be reproduced is a carrier signal or subcarrier signal of a radio signal, a band with less group delay distortion In the case of a modulated signal obtained by passing a pass filter or modulating a radio signal, the band pass filter is demodulated by an analog demodulator with a small delay error or a digital demodulator with a small delay error using a high frequency clock signal. Play through.

  Further, as shown in FIGS. 3, 4 and 6, the synchronous oscillation means 13 of the base station 101 or the portable terminal 103 is set by a reference oscillator 11 or a phase synchronous oscillator 12 or a counter with a reset. Alternatively, it is constituted by a numerically controlled oscillator, and the timing of the rising point, the falling point, or the zero crossing point of the starting signal received by the receiver and demodulated or reproduced by the signal reproducing means 15, 37 is at least detected by the synchronization detecting means 14. By detecting using a clock signal having a frequency of 16 MHz or higher, and setting or resetting the counter or the numerically controlled oscillator at the timing detected by the synchronization detection unit, the synchronous oscillation unit 13 and the starting point signal can be detected in a short time. You can establish synchronization and maintain synchronization.

  In addition, as shown in claim 7, the synchronization establishment error between the synchronous oscillation means 13 of the base station 101 or the portable terminal 103 and the demodulated or reproduced starting signal is reduced, and high accuracy and shortness are achieved. In order to establish synchronization in time, a synchronization establishment error function is given to the mobile terminal 103, the base station 101, or both, and the synchronization establishment error function brings the synchronization establishment error as close to zero as possible.

  Further, as shown in FIG. 6 and claim 8, in order to give the synchronization establishment error function to the synchronization detection means 14 of the base station 101 or the portable terminal 103, the clock signal output from the phase-locked oscillator 12 A plurality of sets of phase shifting means 51 for shifting the phase and a timing control means 53 for selecting and outputting a plurality of sets of clock signals shifted to different phases by the plurality of sets of phase shifting means, respectively. And the total amount of phase shift of the phase shift means is set to be larger than the interval of one cycle of the clock signal, thereby improving the distance calculation accuracy.

  Further, as shown in FIGS. 7 and 9, in order to give the synchronization establishment error function to the synchronous oscillation means 13 of the base station 101 or the mobile terminal 103, the synchronous oscillation means 13 includes a plurality of counters or a plurality of counters. A plurality of sets of counters or a plurality of sets of numerically controlled oscillators are switched by switching means at a plurality of timings different from the regenerated starting point signal to establish synchronization. A selection means selects output signals output from the plurality of sets of counters or a plurality of sets of numerically controlled oscillators at a plurality of different timings, and a single or a plurality of distances synchronized or orthogonal to the selected output signals A measurement signal is generated and transmitted to the mobile terminal 103 or the base station 101. In No. processing means, by determining the average value of the distance calculated in correspondence with the plurality of timings, improving distance calculation accuracy.

  Further, as shown in claim 10, in order to add the synchronization establishment error function to an origin signal transmitted from the base station 101 or the mobile terminal 103 or received by the base station or the mobile terminal, at least the base station The origin signal is transmitted while periodically switching a plurality of directional antennas for each cell or sector of the station 101, or by periodically switching a plurality of antennas in the mobile terminal 103 in addition to the base station 101. Or receive and improve the distance calculation accuracy.

  In addition, as shown in claim 11, the receiver 33 of the mobile terminal, the receiver 18 of the base station, or both of them are provided with a plurality of antennas and periodically switched, and the plurality of antennas correspond to the plurality of antennas. The distance measurement result or distance can be obtained by selecting, averaging, performing a load average, or a combination of the distance measurement or calculation results obtained by measuring or calculating a relatively short distance. Correct or supplement the calculation results.

  Further, as shown in claim 12, the phase measuring means 36 of the mobile terminal 103 or the base station 101 includes a product-sum operation unit, and 0, 1, 0, -1, or 1, 1, -1, -1 or an integer multiple of these, and the Cos lookup table is 1, 0, -1, 0, or 1, -1, -1, 1, or The product-sum operation is performed as a repetition of these integer multiples. Note that multiplication with 1 when performing a product-sum operation is the same value as the digital signal, multiplication with -1 is to obtain the complement of the digital signal, and division with 0 is 0. The product-sum calculator can be simplified, and high-speed, real-time calculation is possible.

  Further, as shown in claim 13, the directional antenna of the base station 101 is composed of an array antenna with a reflector, and the directivity direction is inclined diagonally downward or horizontally for each cell or sector. There are 4 sets in total, 2 sets in the horizontal direction, or 2 sets in the horizontal direction and 2 sets in the vertical direction, and the interval between each set ranges from 0.25 wavelength to 2 wavelengths of the carrier frequency of the radio signal. Arranged at intervals.

Further, as shown in claim 14, the receiver of the mobile terminal 103, the receiver of the base station 101, or both of them has a quality detection means for detecting the quality of the propagation path, and the quality detection means The line quality is analyzed from the result of measuring the power or signal-to-noise ratio of the radio signal received at the receiver, and the distance from the result of measuring the phase of the distance measurement signal or the phase difference of the direction measurement signal by the phase measuring means. The measurement accuracy or the direction measurement accuracy is analyzed, or both of these analyzes are performed, and the results of the distance measurement process, the direction measurement process, or both are corrected or supplemented.

(Embodiment 1)
FIG. 3 is a block diagram of the cellular mobile phone positioning system according to the first embodiment of the present invention. In the cellular mobile phone positioning system using the control channel of the mobile phone system shown in FIG. 3, the mobile terminal 103 for transmitting or receiving a radio signal having a frequency assigned to the control channel of the mobile phone system while moving. And at least one base station 101 that is arranged for each cell or sector and serves as a position reference,

  The portable terminal 103 includes at least an antenna switch 32, a signal generation unit 37, a transmitter 34, a receiver 33, a signal reproduction unit 35, a phase measurement unit 36, and a position calculation unit 38. The antenna switch 32 switches the antenna 31 to either a transmitter or a receiver in a time-sharing manner, and the signal generation means 37 includes a positioning request signal including at least a system synchronization signal, an identification signal, and an origin signal. And generate

  The transmitter 34 transmits a radio signal including the positioning request signal to the base station 101 as a burst signal, the receiver 33 receives a radio signal transmitted from the base station 101, and the signal The reproduction means 35 reproduces the distance measurement signal and the direction measurement signal from the radio signal received by the receiver 33, and the phase measurement means 36 uses the phase of the reproduced distance measurement signal and the direction measurement signal. And the position calculating means 38 measures the position of the own station from the measurement result of the phase,

  The base station 101 includes at least an antenna switch 19, a receiver 18, a signal regeneration unit 16, a synchronous oscillation unit 13, a signal generation unit 15, and a transmitter 17, and the antenna switch 19 However, the directional antennas 21a and 21b are periodically switched or switched to either the transmitter 17 or the receiver 18 in a time-sharing manner, and the positioning request signal transmitted from the portable terminal 103 is received by the receiver 18. Receive radio signals including

  The signal reproducing means 16 reproduces the starting signal included in the positioning request signal from the radio signal received by the receiver 18, and the synchronous oscillating means 13 is highly accurate and in a short time with the reproduced starting signal. The signal generation means 15 for measuring the direction separately from the distance measurement signal synchronized with or orthogonal to the output of the synchronous oscillation means 13 and the distance measurement signal. Direction measurement signal and

  In response to the positioning request signal transmitted from the mobile terminal, the transmitter 17 sends a radio signal including at least the distance measurement signal and the direction measurement signal to a base station arranged for each cell or each sector in advance. A plurality of directional antennas 21a, 21b are periodically switched at the assigned frequency, time slot, or both, and transmitted to the mobile terminal 103, and a starting signal transmitted from the mobile terminal, The distance measurement signal and the direction measurement signal transmitted from the base station are a single carrier or a plurality of carrier waves, subcarrier signals, modulation signals, spread spectrum codes, or combinations thereof that are synchronized or orthogonal,

  In the portable terminal 103, the phase of the distance measurement signal is measured to calculate the distance from the base station, the phase difference of direction measurement signals corresponding to a plurality of directional antennas of the base station is measured, and the base station The direction in which the station 103 is located is calculated, and the position of any one of the first to third dimensions of the mobile terminal 103 is determined with high accuracy from the distance calculation result and the direction calculation result. it can.

The origin signal transmitted from the mobile terminal 103 or the base station 101, and the distance measurement signal and the direction measurement signal transmitted from the base station or the mobile terminal are a single carrier or a plurality of carrier waves that are synchronized or orthogonal to each other. A signal, a subcarrier signal, a modulated signal, a spread spectrum code, or a combination thereof.
Further, in the signal reproducing means 16, 35, when the starting signal or measurement signal to be reproduced is a carrier signal or subcarrier signal of a radio signal, it passes through a band pass filter with little group delay distortion, or a radio signal. Is modulated by an analog demodulator with a small delay error or a digital demodulator with a small delay error using a high-frequency clock signal, and is then reproduced through the band-pass filter.

  As shown in FIGS. 3 and 4, the synchronous oscillation means 13 of the base station 101 or mobile terminal 103 is driven by a reference oscillator 11 or a phase-locked oscillator 12 or a counter with a reset or a numerically controlled oscillator. The timing of the rising point, falling point, or zero crossing of the starting signal received by the receiver and demodulated or reproduced by the signal reproducing means 15 and 37 is detected by the synchronization detecting means 14 at a frequency of at least 16 MHz. By detecting the clock signal and setting or resetting the counter or the numerically controlled oscillator at the timing detected by the synchronization detection unit, the synchronous oscillation unit 13 establishes synchronization with the starting point signal in a short time, Can keep synchronization.

  In order to reduce synchronization establishment error between the synchronous oscillation means 13 of the base station 101 or the portable terminal 103 and the demodulated or reproduced starting signal, and to establish synchronization with high accuracy and in a short time The synchronization establishment error function can be added to the mobile terminal 103, the base station 101, or both, and the synchronization establishment error function can bring the synchronization establishment error as close to zero as possible.

  Further, as shown in FIG. 6, in order to give the synchronization establishment error function to the synchronization detecting means 14 of the base station 101 or the portable terminal 103, the phase of the clock signal output from the phase-locked oscillator 12 is shifted. A plurality of sets of phase shifting means 51, and a timing control means 53 for selecting and outputting a plurality of sets of clock signals shifted to different phases by the plurality of sets of phase shifting means, The distance calculation accuracy can be improved by setting the sum of the phase shift amounts of the phase shift means larger than the interval of one cycle of the clock signal.

  Further, as shown in FIG. 7, in order to give the synchronization establishment error function to the synchronous oscillation means 13 of the base station 101 or the portable terminal 103, the synchronous oscillation means 13 has a plurality of sets of counters or a plurality of sets of numerical control. The plurality of sets of counters or the plurality of sets of numerically controlled oscillators are switched by switching means at a plurality of timings different from the reproduced starting signal, and synchronization is established. The output signal output from the counter or multiple sets of numerically controlled oscillators is selected by a selection means at a plurality of different timings, and a single or a plurality of distance measurement signals synchronized or orthogonal to the selected output signal are generated. And transmitted to the mobile terminal 103 or the base station 101, to the signal processing means of the mobile terminal or base station There are, by obtaining an average value of the distance calculated in correspondence with the plurality of timings, improving distance calculation accuracy.

  Further, in order to add the synchronization establishment error function to the origin signal transmitted from the base station 101 or the mobile terminal 103 or received by the base station or the mobile terminal, at least for each cell or sector of the base station 101 The distance calculation is performed by transmitting or receiving the origin signal while periodically switching a plurality of directional antennas or by periodically switching a plurality of antennas to the mobile terminal 103 in addition to the base station 101. Improve accuracy.

  In addition, a result of the receiver 33 of the mobile terminal, the receiver 18 of the base station, or both of which provided a plurality of antennas and periodically switched, and measured or calculated the distance corresponding to the plurality of antennas The distance measurement result or the distance calculation result is corrected or supplemented by selecting, averaging, performing a load average, or performing a combination of these, by measuring a relatively short distance or calculating one. .

  Further, after the phase measuring means 36 of the mobile 103 and the base station 101 has a product-sum calculator, the distance measurement signal and the direction measurement signal are converted into a digital signal by an analog-digital converter of 8 bits or more, for example. The Sin lookup table is 0, 1, 0, -1, or 1, 1, -1, -1, or an integer multiple of these, and the Cos lookup table is 1, 0, -1, 0, Alternatively, the product-sum operation is performed as 1, -1, -1, 1, or an integer multiple of these. Note that multiplication with 1 when performing a product-sum operation is the same value as the digital signal, multiplication with -1 is to obtain the complement of the digital signal, and division with 0 is 0. The product-sum calculator can be simplified, and high-speed, real-time calculation is possible.

Further, since phase measurement, which is a main part of position calculation, can be processed using the product-sum calculator, the processing content required for the position calculation means 38 is not so large, and is configured using a normal microprocessor. Benefits that can be obtained.

The directional antenna of the base station 101 is composed of an array antenna with a reflector, and is installed with the directivity direction obliquely downward or horizontal for each cell or sector, and two sets in the horizontal direction. Alternatively, a total of 4 sets of 2 sets in the horizontal direction and 2 sets in the vertical direction are arranged, and the intervals between the sets are arranged at intervals of 0.25 wavelength to 2 wavelengths of the carrier frequency of the radio signal. The isolation between the array antennas is about 10 dB or more.

  In addition, the receiver of the mobile terminal 103, the receiver of the base station 101, or both of them have quality detection means for detecting the quality of the propagation path, and the quality detection means receives the radio signal received by the receiver. Analyzing the line quality from the result of measuring the signal power or the signal-to-noise ratio, and analyzing the distance measurement accuracy or direction measurement accuracy from the result of measuring the phase of the distance measurement signal or the phase difference of the direction measurement signal by the phase measuring means. Or both of these analyzes are performed to correct or complement the results of the distance measurement process, the direction measurement process, or both.

(Embodiment 2)
FIG. 4 is a block diagram of a cellular mobile phone positioning system according to the second embodiment of the present invention. In the cellular mobile phone positioning system using the control channel of the mobile phone system shown in FIG. 4, a mobile terminal 103 for transmitting or receiving a radio signal having a frequency assigned to the control channel of the mobile phone system while moving. And at least one base station 101 that is arranged for each cell or sector and serves as a position reference,

The base station 101 includes at least an antenna switch 19, a receiver 18, a signal generation unit 37, a transmitter 17, a signal reproduction unit 35, a phase measurement unit 36, and a position calculation unit 38. The antenna switch 19 periodically switches the directional antennas 21a and 21b, or switches to either the transmitter 17 or the receiver 18 in a time-sharing manner.
The signal generation unit 37 generates at least a system synchronization signal, an identification signal, and a positioning request signal including an origin signal, and the transmitter 17 transmits a radio signal including the origin signal to the portable terminal 103. Toward the base station 101 arranged for each cell or sector, and transmitted as a burst signal at a frequency, a time slot, or both pre-assigned,

  The receiver 18 transmits a radio signal transmitted from the portable terminal 103 in response to the positioning request signal to a frequency, a time slot, or the like assigned in advance to the base station 101 arranged for each cell or sector. In both cases, a plurality of directional antennas 21a and 21b are received while being switched periodically, and the signal reproduction means 35 reproduces a distance measurement signal and a direction measurement signal from a radio signal received by the receiver 18. The phase measurement unit 36 measures the phase of the reproduced distance measurement signal and the direction measurement signal, and the position calculation unit 38 measures the position of the mobile terminal 103 from the phase measurement result,

The portable terminal 103 includes at least an antenna switch 32, a receiver 33, a signal generation unit 15, a signal reproduction unit 16, a synchronous oscillation unit 13, and a transmitter 34, and the antenna switch 32 Switches the antenna 31 to either the transmitter 34 or the receiver 33 in a time-sharing manner,
The receiver 33 receives a radio signal transmitted at a frequency, time slot, or both pre-assigned to the base station 103, and the reproduction means 16 is a radio signal received by the receiver 33. From the signal, the starting signal included in the positioning request signal is reproduced, and the synchronous oscillation means 13 establishes synchronization with the reproduced starting signal signal with high accuracy and in a short time, and maintains the synchronization,

  The signal generation means 15 generates a distance measurement signal that is synchronized or orthogonal to the output of the synchronous oscillation means 13 and a direction measurement signal for measuring a direction separately from the distance measurement signal, and the transmitter 34, in response to the positioning request signal transmitted from the base station, a radio signal including at least the distance measurement signal and the direction measurement signal is assigned in advance to the base station 103 arranged for each cell or each sector. Transmit to the base station 103 in frequency, time slot, or both,

  The base station 101 measures the phase of the distance measurement signal to calculate the distance from the mobile terminal, and measures the phase difference of the direction measurement signals corresponding to the plurality of directional antennas of the base station to The direction of the position is calculated, and the position of any one of the first to third dimensions of the mobile terminal is determined with high accuracy from the calculation result of the distance and the calculation result of the direction.

The mobile terminal 103 transmits a radio signal including at least a location registration request signal, a call request signal, or an emergency call request signal, and the base station 101 that has received the radio signal designates the mobile terminal 103. Thus, a radio signal including at least a positioning request signal is transmitted, and the base station 101 can determine the position of any one of the one to three dimensions of the portable terminal 103 with high accuracy.

FIG. 1 is a configuration diagram of a cellular mobile phone positioning system according to the present invention. In FIG. 1, 101 is a base station, 102a is an x-axis, 102b is a y-axis, 103a and 103b are mobile terminals, 104a and 104b are distances between the base station and the mobile terminal, and 105a and 105b are base station antennas. The direction of the horizontal plane seen, 21aa to 21db are directional antennas. The cell of the base station 101 is divided into four sectors, the directional antennas 21aa and 21ab are provided in the first sector, and similarly, two sets of directional antennas are provided in the remaining sectors.

  Assuming that the current position of the mobile terminal 103a is within the first sector area, the distance La (m) from the center of the antenna 21aa and the antenna 21ab of the base station 101 to the mobile terminal is 104a, and the antenna 21aa of the base station 101 is And the direction in which the mobile terminal 103 is located when viewed from the center of the antenna 21ab is αa (y), the one-dimensional or two-dimensional position of the mobile terminal 103a is expressed as follows regardless of the inclination angles of the antennas 21aa and 21ab. Can be sought.

Xxa = X0−La * Sin (α (y)) −−−− (1)
Yya = Y0−La * Cos (α (y)) −−−− (2)
Here, when the distance measurement signal is 100 kHz, the distance measurement range is 1.5 km, and the phase of the distance measurement signal is a maximum of 360 °. Therefore, the relative distance is measured with high accuracy by detecting the phase difference. it can.

Note that when the mobile terminal 103a moves to the position of the mobile terminal b, the handover is performed from the control channel of the first sector to the control channel of the second sector, so that the position of the mobile terminal b can be measured in the same manner.
In addition, as will be described with reference to FIG. 2, it is also possible to measure a three-dimensional position by providing four directional antennas for each sector of the base station 101 and switching periodically.

Further, a plurality of directional antennas are connected to the portable terminal 103 at intervals of 0.5 to 2 wavelengths of the direction measurement signal, and distance calculation and direction calculation are performed while periodically switching, or both of these are performed. Alternatively, the effect of multipath can be reduced by moving and averaging the results of multiple positionings.
The one-dimensional position means a distance between the base station and the mobile terminal or a direction in which the mobile terminal is located.

FIG. 2 is an external view of the base station antenna of the present invention. In FIG. 2, 101 is a base station, 201a is a front view of the base station antenna, 201b is a side view of the base station antenna, 21aa and 21ab are two sets of array antennas, 21ba and 21bb are two sets of array antennas, and 21ca and 21cb. Are two sets of array antennas, and 21da and 21db are two sets of array antennas.
The two sets of array antennas are directional antennas with reflectors, for example, linear array antennas in which a plurality of dipole antennas are arranged in series, and the horizontal direction interval of the direction measurement signal is 0.5 to 2 wavelengths. It is arranged with. If the distance between the two sets of array antennas is set at an interval of one wavelength of the direction measurement signal, the coupling loss is about 22 dB, which can be used for measuring the direction.

In addition, when an omnidirectional antenna is used for the communication channel of the mobile phone system, a conventional collinear omnidirectional antenna is required separately from the antenna of FIG.
In addition, if each set of array antennas is divided into two in the vertical direction and arranged at intervals of one wavelength of the direction measurement signal, and two sets of directional antennas are provided in the vertical direction, the total of the two sets in the horizontal direction is combined. There are four sets of directional antennas. By measuring the direction in which the mobile terminal is positioned while periodically switching the four sets of directional antennas, three-dimensional positioning is possible.

  FIG. 5 is a diagram illustrating a configuration example of a radio signal according to the present invention. 5, 61a to 61d are system synchronization signals, 62a to 62d are MAC layers, 63a is a positioning request signal including a starting point signal transmitted from the base station 101, and 63b is a positioning request including a starting point signal received by the mobile terminal. 63c is a distance measurement signal and direction measurement signal transmitted from the mobile terminal, 63d is a plurality of distance measurement signals and direction measurement signals received by the base station 101, 64 is a time axis of the base station 101, 65 Is the time axis of the mobile terminal 103.

The system synchronization signals 61a to 61d are unique words of a plurality of bits, and the control timing between the mobile terminal 103 and the plurality of base stations 101 can be matched with an accuracy of about ± 100 nanoseconds. If the distance is obtained by measuring the time difference with accuracy, there is a problem that the positioning error becomes as large as several tens of meters even at a short distance.
The MAC layers 62a to 62d include at least an identification number, a destination number, a notification signal, or a combination thereof, and are generated as a set with the system synchronization signals 61a to 61d.

The origin signal included in the positioning request signal is a signal for establishing precise synchronization between the base station 101 and the mobile terminal 103, and includes a plurality of carrier signals, sub-carriers, A signal based on a carrier signal, a modulation signal, a spread spectrum code, or any combination thereof is used.
On the other hand, the distance measurement signal and the direction measurement signal are signals for performing accurate distance and direction measurement, and a plurality of carrier signals, subcarrier signals, modulation signals, spread spectrum codes that are single, synchronized, or orthogonal to each other. , Or any combination of these is used.

Further, if the duration of the MAC layer 62c is about 0.5 ms and the duration of the distance measurement signal and the direction measurement signals 63b and 63c is about 0.5 ms, respectively, the duration of the system synchronization signal is ignored, Since the total duration is about 1 ms, assuming that the frequency deviation of the reference oscillator mounted on the base station and the portable terminal is ± 1 ppm, the change in frequency between 1 ms is that the frequency of the starting signal is 0.1 MHz. , ± 1 × (1/1000) Hz, the synchronization holding error of the synchronous oscillator is ± 360 ° × (1/1000) = ± 1 °, and the distance measurement error is ± 1.5 km × (1 ° / 360 °) = ± 4.2 m.

  FIG. 6 is a timing chart of the present invention. In FIG. 6, 71 a is an origin signal transmitted from the base station 101, 71 b is an origin signal reproduced by the mobile terminal 103, 72 is a propagation path through which the origin signal propagates toward the mobile terminal 103, and 73 a is the mobile terminal 103 is a distance measurement signal generated in synchronization with the origin signal reproduced by 103, 73b is a distance measurement signal from the portable terminal 103 reproduced by the base station 101, and 74 is a propagation through which the distance measurement signal is propagated from the portable terminal 103. Route,

  75 is a time-division time interval, 76 is a phase difference between the origin signal generated by the base station 101 and the distance measurement signal transmitted from the mobile terminal 103, 81a is a time axis of the transmitter of the base station 103, and 81b is The time axis of the receiver of the base station 101, 82a is the time axis of the transmitter of the previous mobile terminal 103, and 82b is the time axis of the receiver of the previous mobile terminal 103.

Assuming that the starting signal 71a transmitted from the base station 101 is ASin (2πf1t), the starting signal 71a propagates through the propagation path 72 of the distance La (m) and is received by the portable terminal 103, and the starting signal 71b Is reproduced as BSin {2πf1t + 2πLa (f1 / C)}.
When the distance measurement signal 73a synchronized with the reproduced origin signal 71b and the synchronization establishment error is zero, the generated distance measurement signal 73a is similarly expressed by BSin {2πf1t + 2πLa (f1 / C)}.

After the time division interval 75, the generated distance measurement signal 73a is transmitted from the mobile terminal 103, propagates again through the propagation path 74 of the distance La (m), and is reproduced by the base station 101. The measurement signal 73b is represented by CSin {2πf1t + 4πLa (f1 / C)}. Here, C is the speed of light.
Therefore, when the phase of the reproduced distance measurement signal 73b is measured using a clock signal that is synchronized with or orthogonal to the starting signal 71a that is first generated by the base station 101 and whose frequency is an integral multiple of the starting signal, Since the phase difference 76 between the origin signal 71a first generated by the base station 101 and the distance measurement signal 73b reproduced by the base station 101 is measured and ΔΦ = {4πLa (f1 / C)}, The distance La (m) can be calculated from La = {CΔΦ / 4πf1}.

FIG. 7 is a block diagram of the synchronization establishment error function generation means of the present invention. 7, 11 is a reference oscillator, 12 is a phase-locked oscillator, 27 is an error function generating means, 51 is a phase shifting means, 52a to 52n are switching taps of the phase shifting means 51, 53 is a switching control means, 54, 55, Reference numeral 56 denotes a connection terminal.
The output signal of the reference oscillator 11 at the previous stage is converted into a high frequency by the phase-locked oscillator 12 and input to the phase means 51 via the connection terminal 54. The phase shift means 51 is constituted by a plurality of stages of shift registers, a plurality of stages of delay elements, or a plurality of stages of delay circuits, and the signal output of each stage is drawn out by the switching taps 52a to 52n. The signals are sequentially switched and output as a clock signal from the connection terminal 56 to the outside.

  The amount of phase shift at each stage of the phase shift means 51 is desirably as small as possible, and the total of the phase shift amounts needs to be one period or more of the clock signal. For example, if the frequency of the clock signal is 256 MHz, the phase shift amount of each stage of the phase shift means 51 is 4 nanoseconds or less (for example, 0.4 nanosecond), and the total phase shift amount is It is necessary to set it to 4 nanoseconds or more (for example, 6.4 nanoseconds).

  In the absence of the phase shift means 51, the synchronization establishment accuracy of the synchronous oscillation means 13 is ± 2 nanoseconds. If the frequency of the origin signal is 1 MHz, the distance measurement accuracy is relative to 150 m of the positioning range. However, ± 30 cm is the limit, but when the above-mentioned phase shift means 51 is provided, the phase shift amount assigned to each stage is 0.4 nanoseconds, and the average value of the calculated distance is obtained, the positioning accuracy is ± 15 cm. Can be improved.

The phase shifting means 51 gives a synchronization establishment error function to the synchronous oscillation means 13, and the sum of synchronization establishment errors generated in each stage of the plurality of stages of taps 52a to 52n is calculated as the synchronization establishment error function. In other words, the synchronization establishment error function can be expressed by a polynomial, and the polynomial converges to 0 or a constant value.

FIG. 8 is another configuration diagram of the synchronization establishment error function generation means of the present invention. In FIG. 8, 91 and 93 are changeover switches, 92a to 92n are a plurality of sets of counters or a plurality of sets of numerically controlled oscillators, and 94 to 96 are connection terminals.
The set or reset signal detected from the rising point, falling point, or zero crossing timing of the starting signal supplied to the connection terminal 94 is sequentially switched by the changeover switch 91, and the plurality of sets of counters or the plurality of sets of The numerically controlled oscillators 92a to 92n are sequentially set or reset.

On the other hand, the connection terminal 96 is supplied with a clock signal from a phase-locked oscillator 12 (not shown), and is synchronized with the set or reset timing by the reset signal by the plural sets of counters 92a to 92n. Count down to a lower frequency.
The output signals generated by the plurality of sets of counters or the plurality of sets of numerically controlled oscillators 92 a to 92 n are sequentially switched by a changeover switch 93 and supplied to the signal generation means 15 via a connection terminal 95.

  Here, the frequency or phase of the clock signal supplied from the phase-locked oscillator 12 to the synchronization detecting means 14 and the frequency or phase of the reproduced starting signal are uncorrelated and / or the frequency or phase between them. The correlation coefficient between the synchronization establishment errors of the plurality of sets of counters or the plurality of sets of numerically controlled oscillators 92a to 92n can be kept low. Therefore, by obtaining the average value from the result of calculating the distance by measuring the phase of the distance measurement signal, a merit that the distance measurement accuracy can be improved can be obtained.

  In other words, the detection timing of the set or reset signal detected by the synchronization detecting means 14 is changed corresponding to each of the plurality of sets of counters or the plurality of sets of numerically controlled oscillators 92a to 92n, and the phase-locked oscillator 12 As a whole, the average value of synchronization establishment errors converges to 0 or a constant value if it can be set or reset at different timings within the time interval of a plurality of bits of the clock signal supplied from Therefore, by providing the plurality of sets of counters or the plurality of sets of numerically controlled oscillators 92a to 92n, it is possible to perform highly accurate positioning even if the frequency of the clock signal supplied to the synchronization detecting means 14 is kept relatively low. Become.

Note that the switching timings of the changeover switches 91 and 93 are not the same, and it is necessary to match at least the timing of transmission and reception at the time division interval.
Further, when the plurality of sets of counters are used, it is possible to use about 8 or less counters per set. Therefore, even if 8 sets of counters are provided, it is possible to use about 64 counters, which is an economical scale.
Further, if the total synchronization establishment error generated for each set of the plurality of sets of counters or the plurality of sets of numerically controlled oscillators 92a to 92n is expressed as a synchronization establishment error function, the synchronization establishment error function can be expressed by a polynomial. The polynomial will converge to 0 or a constant value.

On the other hand, when an analog or digital delay means is provided as in the conventional case, for example, when the interval for receiving and transmitting in time division is 2 milliseconds, and the duration is 1 millisecond Even if the frequency of the starting signal is about 1 MHz, especially in the case of a digital delay means, it is necessary to set the frequency of the clock signal to 100 MHz to 1000 MHz or more, so a large delay element is required. It becomes.
However, a change-over switch is provided between the input terminal and output terminal of the delay means, and the change-over switch is disconnected when reading the origin signal, connected in a ring shape after reading, and disconnected when reading. Thus, there is an advantage that the delay time required for the interval of 2 milliseconds at least for receiving and transmitting in time division can be saved.

  In the above description, the case where radio waves are used as radio signals has been described. However, ultrasonic signals, high-frequency signals, or optical signals can be included as radio signals. In the case of an ultrasonic signal or an optical signal, a transmitter / receiver is used instead of an antenna, and in the case of an optical signal, a relatively high frequency subcarrier signal or a high chip rate spreading code is used. And

Further, the receiver of the mobile terminal, the receiver of the base station, or both of them are provided with a plurality of antennas and periodically switched, and the quality detection means measures distances corresponding to the plurality of antennas. Or, select or average the calculated results and calculate the distance, average the weights, or perform a combination of these to correct or complement the distance measurement results or distance calculation results. can do.
In addition, the base station has a single antenna, and the mobile terminal is equipped with a plurality of directional antennas and receives signals while switching periodically. The position of any dimension can be measured.

Since the present invention is configured as described above, a frequency of a control channel assigned to a cellular mobile phone system or a frequency in the vicinity thereof is assigned as the frequency of the radio signal, and is assigned to each cell, each sector, or The position of any one of the one-dimensional to three-dimensional positions of the mobile phone terminal is highly accurate by time-division communication at the same frequency between a plurality of base stations arranged for both of them and the mobile phone terminal. You can measure with.
In particular, since the cellular phone can be shared with the positioning system, the convenience of the cellular phone subscriber is achieved.

In addition, a high-accuracy cellular pseudo-satellite positioning system that seamlessly connects GPS outdoors and indoors using the base station as a pseudo-satellite station can be realized in an economical manner.
Further, when the base station is discretely arranged regardless of whether it is outdoors or indoors, it can be applied to an autonomous movement support system for pedestrians, a pedestrian navigation system, an evacuation / guidance system at the time of a fire or disaster, and the like.
In addition, the high-precision positioning technology of the present invention is a basic technology and can be expected to be used in many other fields.

Configuration of cellular cellular phone positioning system of the present invention External view of base station antenna of the present invention Configuration diagram of cellular mobile phone positioning system according to Embodiment 1 of the present invention Configuration diagram of cellular mobile phone positioning system according to Embodiment 2 of the present invention The figure which shows the structure of the radio signal of this invention Timing chart of the present invention Configuration diagram of synchronization establishment error function generation means of the present invention Another configuration diagram of synchronization establishment error function generation means of the present invention Configuration diagram showing a conventional example

101 Base stations 21aa to 21db arranged for each cell or sector A plurality of directional antennas 103 installed in a base station 103 Mobile terminals 104a and 104b A distance between a plurality of base stations and a mobile terminal 105a and 105b A plurality of bases Direction of mobile terminal viewed from the station

Claims (14)

In the cellular mobile phone positioning system that uses the control channel of the mobile phone system,
A mobile terminal for transmitting or receiving a radio signal having a frequency assigned to a control channel of the mobile phone system in a time-division manner while moving, and at least one base that is arranged for each cell or sector and serves as a reference for a position Station and
The portable terminal has at least an antenna switch, a signal generation unit, a transmitter, a receiver, a signal reproduction unit, a phase measurement unit, and a position calculation unit,
The antenna switcher switches the antenna to either a transmitter or a receiver in a time division manner,
The signal generating means generates at least a system synchronization signal, an identification signal, and a positioning request signal including a starting point signal;
The transmitter transmits a radio signal including the positioning request signal to the base station;
The receiver receives a radio signal transmitted from the base station;
The signal reproduction means reproduces a distance measurement signal and a direction measurement signal from a radio signal received by the receiver;
The phase measurement means measures the phase of the reproduced distance measurement signal and the direction measurement signal;
The position calculating means measures the position of the own station from the measurement result of the phase,
The base station has at least an antenna switch, a receiver, a signal regeneration means, a synchronous oscillation means, a signal generation means, and a transmitter;
The antenna switch periodically switches a plurality of directional antennas, or switches in time division to either a transmitter or a receiver,
The receiver receives a radio signal including a positioning request signal transmitted from the mobile terminal;
The signal reproducing means reproduces a starting signal included in the positioning request signal from a radio signal received by the receiver;
The synchronous oscillating means establishes synchronization in a short time with high accuracy with the reproduced starting signal, and holds the synchronization;
The signal generation means generates a distance measurement signal that is synchronized with or orthogonal to the output of the synchronous oscillation means, and a direction measurement signal for measuring a direction separately from the distance measurement signal,
In response to the positioning request signal transmitted from the mobile terminal, the transmitter preallocates a radio signal including at least the distance measurement signal and the direction measurement signal to a base station arranged for each cell or sector. Transmitted to the mobile terminal while periodically switching a plurality of directional antennas at a given frequency, time slot, or both,
In the portable terminal, the phase of the distance measurement signal is measured to calculate the distance from the base station, the phase difference of direction measurement signals corresponding to a plurality of directional antennas of the base station is measured, and the base station Calculate the direction in which
A cellular cellular phone positioning system characterized in that the position of any one of the first to third dimensions of the own station is determined with high accuracy from the distance calculation result and the direction calculation result.
In the cellular mobile phone positioning system that uses the control channel of the mobile phone system,
A mobile terminal for transmitting or receiving a radio signal having a frequency assigned to a control channel of the mobile phone system in a time-division manner while moving, and at least one base that is arranged for each cell or sector and serves as a reference for a position Station and
The base station has at least an antenna switch, a receiver, a signal generation unit, a transmitter, a signal reproduction unit, a phase measurement unit, and a position calculation unit,
The antenna switch periodically switches a plurality of directional antennas, or switches in time division to either a transmitter or a receiver,
The signal generating means generates at least a system synchronization signal, an identification signal, and a positioning request signal including a starting point signal;
The transmitter transmits a radio signal including the origin signal to the mobile terminal at a frequency, a time slot, or both pre-assigned to a base station arranged for each cell or each sector. Send as
The receiver transmits a radio signal transmitted from the mobile terminal in response to the positioning request signal at a frequency, time slot, or both pre-assigned to a base station arranged for each cell or sector. , Receive while switching multiple directional antennas periodically,
The signal reproduction means reproduces a distance measurement signal and a direction measurement signal from a radio signal received by the receiver;
The phase measurement means measures the phase of the reproduced distance measurement signal and the direction measurement signal;
The position calculating means measures the position of the mobile terminal from the measurement result of the phase,
The portable terminal has at least an antenna switch, a receiver, a signal reproduction means, a synchronous oscillation means, a signal generation means, and a transmitter,
The antenna switcher switches the antenna to either a transmitter or a receiver in a time division manner,
The receiver receives a radio signal transmitted at a frequency, time slot, or both pre-assigned to the base station;
The signal reproducing means reproduces a starting point signal included in the positioning request signal from a radio signal received by the receiver;
The synchronous oscillating means establishes synchronization in a short time with high accuracy with the reproduced starting signal, and holds the synchronization;
The signal generation means generates a distance measurement signal that is synchronized with or orthogonal to the output of the synchronous oscillation means, and a direction measurement signal for measuring a direction separately from the distance measurement signal,
In response to the positioning request signal transmitted from the base station, the transmitter preallocates a radio signal including at least the distance measurement signal and the direction measurement signal to a base station arranged for each cell or each sector. Transmit to the base station on a given frequency, time slot, or both,
In the base station, the distance from the mobile terminal is calculated by measuring the phase of the distance measurement signal, and the mobile terminal is positioned by measuring the phase difference of the direction measurement signals corresponding to the plurality of directional antennas of the base station. Calculate the direction to
A cellular mobile phone positioning system characterized in that the position of any one of the first to third dimensions of the mobile terminal is measured with high accuracy from the distance calculation result and the direction calculation result.
The mobile terminal transmits a radio signal including at least a location registration request signal, a call request signal, or an emergency call request signal, and a base station that receives the radio signal designates the mobile terminal and performs at least positioning. The wireless signal including a request signal is transmitted, and the base station measures the position of any one of the one to three dimensions of the mobile terminal with high accuracy. The cellular cellular phone positioning system described.
The origin signal transmitted from the mobile terminal or the base station, and the distance measurement signal and the direction measurement signal transmitted from the base station or the mobile terminal are single, or a plurality of carrier signals and subcarriers that are synchronized or orthogonal to each other. The cellular mobile phone positioning system according to claim 1 or 2, wherein the cellular mobile phone positioning system is a signal, a modulated signal, a spread spectrum code, or a combination thereof.
In the signal reproduction means, when the starting signal or measurement signal to be reproduced is a carrier signal or subcarrier signal of a radio signal, a modulated signal obtained by passing a band pass filter with little group delay distortion or modulating the radio signal In this case, the signal is demodulated by an analog demodulator with a small delay error or a digital demodulator with a small delay error using a high-frequency clock signal, and is then reproduced through the band-pass filter. Alternatively, the cellular mobile phone positioning system according to item 2.
The synchronous oscillation means of the base station or mobile terminal is constituted by a counter or numerically controlled oscillator driven by a reference oscillator or a phase synchronous oscillator, and received by the receiver and demodulated or reproduced by a signal reproduction means The timing of the rising point, falling point, or zero crossing of the generated starting point signal is detected by using a clock signal having a frequency of at least 16 MHz by the synchronization detecting means, and at the timing detected by the synchronization detecting means, the counter or 3. The cellular system according to claim 1, wherein the synchronous oscillation means can establish synchronization with a starting point signal in a short time by setting or resetting a numerically controlled oscillator, and can maintain the synchronization. Mobile phone positioning system.
In order to reduce synchronization establishment error between the synchronous oscillation means of the base station or the portable terminal and the demodulated or reproduced starting signal, and to establish the synchronization with high accuracy and in a short time, the portable terminal, 3. The synchronization establishment error function is given to the base station or both of them, and the synchronization establishment error function has a characteristic of making the synchronization establishment error as close to zero as possible. Cellular mobile phone positioning system described in 1.
A plurality of sets of phase shifting means for shifting the phase of the clock signal output from the phase-locked oscillator to give the synchronization establishment error function to the synchronization detection means of the base station or mobile terminal; Timing control means for selecting and outputting to the outside a plurality of sets of clock signals each shifted to a different phase by the phase shift means, the total amount of phase shift of the phase shift means is the clock signal The cellular mobile phone positioning system according to claim 7, wherein the distance calculation accuracy is improved by setting the interval larger than one cycle interval.
In order to give the synchronization establishment error function to the synchronous oscillation means of the base station or portable terminal, the synchronous oscillation means has a plurality of sets of counters or a plurality of sets of numerically controlled oscillators, and the plurality of sets of counters or a plurality of sets The numerically controlled oscillators are switched by switching means at a plurality of timings different from the reproduced starting point signals to establish synchronization, and output signals output from the plurality of sets of counters or the plurality of sets of numerically controlled oscillators Select by a selection means at a plurality of different timings, generate a single or a plurality of distance measurement signals that are synchronized with or orthogonal to the selected output signal, and transmit the signals to the mobile terminal or base station. In a signal processing means of a terminal or a base station, obtaining an average value of distances calculated corresponding to the plurality of timings Therefore, cellular mobile phone positioning system according to claim 7, wherein, characterized in that to improve the distance calculation accuracy.
Periodically switching at least a plurality of directional antennas of the base station in order to give the synchronization establishment error function to an origin signal transmitted from the base station or mobile terminal or received by the base station or mobile terminal Or the base station is provided with a plurality of antennas in a mobile terminal, and the origin signal is transmitted or received while periodically switching to improve the distance calculation accuracy. The cellular mobile phone positioning system according to item.
The mobile terminal receiver, the base station receiver, or both of them are provided with a plurality of antennas and periodically switched, and a distance is measured or calculated according to the plurality of antennas. The distance measurement result or the distance calculation result is corrected or supplemented by selecting, averaging, performing a weighted average, or a combination thereof, by selecting a relatively short measured or calculated value. The cellular mobile phone positioning system according to claim 10.
The portable terminal or base station phase measurement means has a product-sum calculator, and 0, 1, 0, -1 or 1, 1, -1, -1 as a Sin lookup table of the product-sum calculator Or a multiplication of these integral multiples, and a Cos lookup table of 1, 0, −1, 0, or 1, −1, −1, 1, or repetitions of these integral multiples. Note that multiplication with 1 when performing a product-sum operation is the same value as the digital signal, multiplication with -1 is to obtain the complement of the digital signal, and division with 0 is 0. The cellular mobile phone positioning system according to claim 1 or 2, characterized in that the product-sum calculator can be simplified, and real-time calculation can be performed at high speed.
The directional antenna of the base station is composed of an array antenna with a reflector, and is installed with the directivity direction obliquely downward or horizontal for each cell or sector, and two sets in the horizontal direction or horizontal 4. A total of four sets of two sets in the direction and two sets in the vertical direction are arranged, and the interval of each set is arranged at an interval of 0.25 wavelength to 2 wavelengths of the carrier frequency of the radio signal. Item 3. A cellular mobile phone positioning system according to item 1 or item 2.
  The receiver of the mobile terminal, the receiver of the base station, or both of them have quality detection means for detecting the quality of the propagation path, and the quality detection means is the power of the radio signal received by the receiver or Analyzing the line quality from the result of measuring the signal-to-noise ratio, and analyzing the distance measurement accuracy or the direction measurement accuracy from the result of measuring the phase difference of the distance measurement signal or the phase measurement signal by the phase measuring means, or these 14. The cellular system according to claim 1, wherein both of the above-described analysis are performed, and the results of the distance measurement process, the direction measurement process, or both of these are corrected or complemented. Mobile phone positioning system.

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