JPH0955709A - Measuring instrument for multiplex propagation characteristic - Google Patents

Abstract

PROBLEM TO BE SOLVED: To shorten the required time from reception to a Doppler analysis by processing a signal which is received over spatial movement by complex Fourier transformation and taking a momentary analysis of a Doppler frequency component extended in a delay time. SOLUTION: This instrument is equipped with a receiving means 1 which receives a sent signal after digital modulation based upon a pseudo-random pattern over spatial movement, a complex Fourier transforming means 2 which processes the received signal by complex Fourier transformation, and a Doppler analyzing means 3 which takes the momentary analysis of the Doppler frequency component extended in the delay time. Then a fixed transmission side sends the sent signal after the digital modulation based upon the pseudo-random pattern to a reception side through a multiplex propagation path. On the reception side, the receiving means 1 receives the sent signal while moving. The complex Fourier transforming means 2 processes the received signal by complex Fourier transformation to extended it into a spectrum. Further, the Doppler analyzing means 3 momentarily analyzes the Doppler frequency component extended in the delay time from the extended spectrum components.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multiple propagation characteristic measuring apparatus, and more particularly to a multiple propagation characteristic measuring apparatus for analyzing a Doppler shift developed in delay time.

In recent years, the development of mobile communication has been remarkable, and accordingly, a mobile communication system capable of high-speed data transmission has been demanded. To develop such a system, it is necessary to know the multipath characteristics in advance, and the present invention relates to an apparatus for measuring the multipath characteristics.

[0003]

2. Description of the Related Art Generally, when a mobile station is moved on a road in an urban area, for example, the mobile station traverses a field intensity distributed unevenly on the road, so that the received electric field fluctuates drastically with time. Multipath fading occurs. In a multipath propagation path in which the same transmission wave reaches a reception point through a plurality of paths, frequency dependence characteristics due to multipath fading appear. When a wideband signal is transmitted through such a propagation path, the spectrum of the wideband signal is transformed and the quality of the transmitted signal is deteriorated.

Therefore, in order to perform high-quality, high-speed data transmission in a mobile communication system, it is necessary to measure the multiplex propagation characteristic in advance and reflect it in the system design.

Conventionally, as a method of measuring such multiple propagation characteristics, there has been a method of measuring a delay time of multiple propagation. In this method, the delay profile is measured from the delay amount of the multiple wave propagation and the received power.

In order to know the Doppler shift among the multiple propagation characteristics, the Doppler analysis is performed based on the obtained delay profile.

[0007]

However, in the conventional method leading to the Doppler analysis, it is necessary to perform integration during the measurement of the delay profile to obtain the correlation output. This integration requires several minutes, and there is a problem that measurement takes time.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a multiplex propagation characteristic measuring apparatus capable of performing instantaneous measurement while shortening the time required from reception to Doppler analysis. To aim.

[0009]

In order to achieve the above object, the present invention, as shown in FIG. 1, includes a receiving means 1 for receiving a transmission signal digitally modulated by a pseudo random pattern while spatially moving. On the basis of the complex Fourier transform means 2 for performing a complex Fourier transform on the received signal received by the receiving means 1, and the post-transformation component transformed by the complex Fourier transform means 2, the instantaneous analysis of the Doppler frequency component expanded in the delay time is carried out. And a Doppler analysis means 3 for performing the above.

In the above structure, the fixed transmission side sends the transmission signal digitally modulated by the pseudo random pattern to the reception side via the multiple propagation paths. On the receiving side, the receiving means 1 receives the transmission signal while moving.
Complex Fourier transform means 2 for the received signal
Performs a complex Fourier transform to develop into a spectrum.
The Doppler analysis unit 3 instantaneously analyzes the Doppler frequency component expanded in the delay time from the spectrum component expanded by the complex Fourier transform unit 2.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. First, the principle configuration of the first embodiment will be described with reference to FIG. In the first embodiment,
Mainly, a receiving means 1 for receiving a transmission signal digitally modulated by a pseudo-random pattern while moving in space.
And a complex Fourier transform means 2 for performing a complex Fourier transform on the reception signal received by the receiving means 1, and the instantaneous of the Doppler frequency component expanded in the delay time based on the transformed component converted by the complex Fourier transform means 2. And a Doppler analysis means 3 for performing dynamic analysis.

FIG. 2 is a block diagram showing a detailed configuration of the first embodiment. The receiving means 1 shown in FIG. 1 corresponds to the RF band band limiting section 4, RF / IF converter 5, local oscillating section 6, and IF band amplifying section 7 of FIG. The Doppler analysis means 3 corresponds to the conversion unit 8 and corresponds to the analysis unit 9.

As will be described later with reference to FIG. 3, a transmission signal digitally modulated by a pseudo random pattern is sent from the transmission section to the reception section via multiple propagation paths.
In the receiving unit shown in FIG. 2, the signal received by the antenna 10 is band-limited by the RF band band limiting unit 4,
The RF / IF converter 5 converts the frequency to an intermediate frequency. A local oscillator 6 is connected to the RF / IF converter 5. The received wave that has been frequency-converted to the intermediate frequency is amplified by the IF band amplification unit 7, and then the complex Fourier transform unit 8
Sent to The complex Fourier transform unit 8 performs a complex Fourier transform on the transmitted signal and expands it into a spectrum. The analysis unit 9 is composed of a processor and performs an instantaneous analysis of the Doppler frequency component developed in the delay time based on the I signal and the Q signal output from the complex Fourier transform unit 8. The operation of the analysis unit 3 will be described with reference to FIGS.
Will be described later with reference to. The receiving unit performs reception while moving.

FIG. 3 is a block diagram showing the structure of the transmitting unit. In the transmitting section, the coded signal generating section 11 generates a coded signal of a pseudo random pattern, the band limiting section 12 limits the band of the coded signal, and then sends the coded signal to the digital modulating section 13. The digital modulator 13 performs digital modulation with a coded signal having a pseudo-random pattern, and sends this modulated wave as a transmission wave from the antenna 14.

FIG. 4 shows a spectrum of a signal in each section of the transmitting / receiving section. The transmission signal transmitted from the antenna 14 of the transmitter is a signal discretely distributed over a wide band as shown in (A). When this transmission signal is received by the moving antenna 10 of the receiving section, it becomes a reception signal whose spectrum is spread around the center frequency f ₀ as shown in (B) due to Doppler shift. That is, for example, when the frequency of the transmission signal is 2 GHz (wavelength 0.15 m) and the receiving unit moves at 30 km / h (= about 8.3 m / sec), when the transmission signal arrives from the moving direction, the transmission signal arrives at about 55 Hz ( = 8.3 / 0.15) Shift to a higher frequency. On the contrary, when the transmission signal arrives from the opposite direction to the moving direction, it shifts to a frequency lower by about 55 Hz.

Here, assuming that the in-phase component of the received wave is R _I (t) and the quadrature-phase component of the received wave is R _Q (t), the complex Fourier transform unit 8 has the following equations (1) to (4). A complex Fourier transform is performed according to to obtain the I signal component and the Q signal component.

[0017]

[Equation 1]

[0018]

[Equation 2]

[0019]

(Equation 3)

[0020]

(Equation 4)

Ω ₀ is the angular frequency of the carrier wave on the transmission side,
Δω is the frequency interval of Doppler analysis, and T is the sampling time length. These I and Q signals are shown in FIG.
It can be expressed as (C) and (D).

First, the analysis unit 9 uses the following equations (5) and (6).
The inverse transform of the complex Fourier transform is performed according to.

[0023]

(Equation 5)

[0024]

(Equation 6)

Δω _f = 2πΔf _t, Δf _t = 1
/ T _f , where T _f is the frame length of the coded signal of the pseudo random pattern. Next, the analysis unit 9 obtains a delay profile having the delay time τ as a variable based on the following equations (7) and (8).

[0026]

(Equation 7)

[0027]

(Equation 8)

Here, a (t) indicates a coded signal having a pseudo random pattern. (N · Δω) in these equations is the Doppler shift. FIG. 5 is a graph showing the relationship between the Doppler shift and the delay profile.
Shows the delay profile when the Doppler shift is −n · Δω (when the received wave comes from the direction opposite to the traveling direction of the receiving section), and (B) shows the delay profile when the Doppler shift is 0, ( C) has a Doppler shift of n · Δ
The delay profile at the time of ω (when the received wave comes from the traveling direction of the receiving unit) is shown.

As described above, in the first embodiment, the processing from reception to Doppler analysis can be instantaneously performed. Next, a second embodiment will be described.

FIG. 6 is a block diagram of the transmission unit of the second embodiment. Since the configuration of the transmission unit of the second embodiment is basically the same as the configuration of the transmission unit of the first embodiment,
The same portions are denoted by the same reference numerals and description thereof will be omitted.

In the transmitter of the second embodiment, the high stability reference oscillator 15 is newly provided, and the high stability reference oscillator 15 is provided.
Is connected to the encoded signal generator 11 and the digital modulator 13. The high stability reference oscillator 15 stabilizes the frequency of the pseudo random pattern and the frequency of the carrier wave of the digital modulator 13.

FIG. 7 is a block diagram of the receiving section of the second embodiment. Since the configuration of the receiving unit of the second embodiment is basically the same as the configuration of the receiving unit of the first embodiment,
The same portions are denoted by the same reference numerals and description thereof will be omitted.

In the receiver of the second embodiment, the high stability reference oscillator 16 is newly provided, and the high stability reference oscillator 16 is provided.
Is connected to the local oscillator 6 and the complex Fourier transform 8. The high-stable reference oscillator 16 includes the high-stable reference oscillator 15,
16 is a highly accurate stabilized oscillator using cesium or the like. In addition, use a separate line or GPS (Global
(Positioning System) may be used to establish synchronization with the high-stability reference oscillator 15 (which also receives GPS) of the transmitter. The high stability reference oscillation unit 16 synchronizes with the high stability reference oscillation unit 15 on the transmission side and stabilizes the local oscillation frequency of the local oscillation unit 6 and the reference signal frequency of the complex Fourier transform unit 8.

Next, a third embodiment will be described. FIG. 8 is a configuration diagram of the receiving unit according to the third embodiment. The configuration of the receiving unit according to the third embodiment is basically the same as the configuration of the receiving unit according to the first embodiment, and therefore, the same portions will be denoted by the same reference numerals and description thereof will be omitted. The configuration of the transmitter of the third embodiment is exactly the same as that of the transmitter of the first embodiment.

In the third embodiment, based on the output of the high stability reference oscillating unit 18, the timing signal generating unit 19 locally outputs the timing signal at each time interval which is a multiple of the frame length of the pseudo random pattern on the transmitting side. Output to the oscillator 20. The local oscillating unit 20 is a device for generating a local oscillating signal capable of varying the oscillating frequency, and when receiving the timing signal from the timing signal generating unit 19, the local oscillating unit has a frequency higher than the oscillating frequency up to now by a predetermined frequency. The signal is sent to the RF / IF converter 5. This predetermined frequency is
It is set to the frequency interval of the spectrum constituent components of the discrete transmission signal. The operation of the above receiving section will be described with reference to FIG.

FIG. 9 is a diagram showing a signal spectrum of each part of the transmitting / receiving section. As shown in (A), the transmission signal is composed of discrete spectrum components, and the frequency interval between these spectrum components is f1. Timing T _1, T _2, ...
Each interval of T _N is set to a time interval which is a multiple of the frame length of the pseudo random pattern on the transmitting side. Local oscillator 20
Sends a local oscillation signal having a frequency higher by f1 than the frequency oscillating up to now to the RF / IF converter 5 at timings T _1, T _2, ... T _N. The RF / IF converter 5 and the IF band amplification unit 7 perform narrow band processing, and at timing T ₁ , only the spectrum shown in FIG. 9C is frequency-converted and output to the complex Fourier transform unit 8.
At timing T ₂ , only the spectrum shown in FIG. 9D is frequency-converted and output to the complex Fourier transform unit 8. At timing T _N , only the spectrum shown in FIG. Output to the Fourier transform unit 8. Therefore, the complex Fourier transform unit 8 may be a device capable of narrow band processing, and the processing load of the complex Fourier transform unit 8 is reduced. Alternatively, the processing accuracy of such complex Fourier transform is improved, and the accuracy of Doppler analysis is also improved.

Next, a fourth embodiment will be described. FIG. 10 is a configuration diagram of the receiving unit according to the fourth embodiment. 4th
The configuration of the receiving unit according to the second embodiment is basically the same as the configuration of the receiving unit according to the first embodiment, and therefore, the same portions will be denoted by the same reference numerals and description thereof will be omitted. The configuration of the transmitting unit according to the fourth embodiment is exactly the same as that of the transmitting unit according to the first embodiment.

The receiving section of the fourth embodiment is provided with a reference spectrum storage section 22 for storing the output of the complex Fourier transform section 8. The output of the reference spectrum storage unit 22 is connected to the analysis unit 9. Further, a change-over switch 23 for directly connecting the antenna 10 of the receiving section and the antenna 14 of the transmitting section and selectively outputting any output is provided, and the output is sent to the RF band band limiting section 4. A control unit 24 is connected to the changeover switch 23, the reference spectrum storage unit 22, and the analysis unit 9, and their operations are controlled.

That is, under the control of the control unit 24, first, the changeover switch 23 directly sends the transmission signal from the antenna 14 of the transmission unit to the RF band band limiting unit 4 without passing through the multiple propagation paths. Then, the output of the complex Fourier transform unit 8 at that time is stored in the reference spectrum storage unit 22. Therefore, the stored data is data that is not affected by the multiple propagation paths. Next, the changeover switch 23
Sends the received signal from the antenna 10 of the receiving section to the RF band band limiting section 4. The output of the complex Fourier transform unit 8 at that time is sent to the analysis unit 9. The analysis unit 9 obtains the difference between the data transmitted from the complex Fourier transform unit 8 through the multiple propagation path and the data stored in the reference spectrum storage unit 22, and obtains the multiple propagation characteristics with the influence of the transmission / reception system removed. To analyze.

The analysis unit 9 calculates the phase deviation existing between the data that has passed through the multiple propagation paths and the data stored in the reference spectrum storage unit 22 to remove the influence of the transmission / reception system. You may make it analyze a characteristic.

Next, a fifth embodiment will be described. FIG. 11 is a block diagram of the receiving unit of the fifth embodiment. Fifth
The configuration of the receiving unit according to the second embodiment is basically the same as the configuration of the receiving unit according to the first embodiment, and therefore, the same portions will be denoted by the same reference numerals and description thereof will be omitted. The configuration of the transmitter of the fifth embodiment is exactly the same as that of the transmitter of the first embodiment.

The receiving section of the fifth embodiment is provided with a storage section 26 for continuously storing the output of the IF band amplifying section 7, and the output of the IF band amplifying section 7 is continuously stored at the time of measurement. . Then, later, the complex Fourier transform unit 8 and the analysis unit 9 read the data stored in the storage unit 26, and the complex Fourier transform and analysis processing is performed. The storage unit 26 may be configured by DAT (Digital Audio Tape-recorder), may store an analog signal on a magnetic tape, or may be stored on a hard disk or the like after A / D conversion. May be.

In the fifth embodiment, since the measurement and the analysis are temporally separated, the analysis can be performed with high accuracy. Next, a sixth embodiment will be described.

FIG. 12 is a block diagram of the receiving section of the sixth embodiment. In the receiver of the sixth embodiment, the plurality of antennas 28a to 28n are arranged at equal intervals L along the moving direction. A plurality of receivers (Rx) 29a to 29n are connected to these antennas 28a to 28n, respectively. Each of the receivers 29a to 29n has the same configuration as the RF band band limiting unit 4, the RF / IF converter 5, the local oscillating unit 6, and the IF band amplifying unit 7 which form the receiving unit of the first embodiment. Is equipped with. Further, each of the receivers 29a to 29n has a plurality of complex Fourier transform units (FFT) 30a to 30n.
Is connected. Each of the complex Fourier transform units 30a to 30n has the same configuration as the complex Fourier transform unit 8 constituting the receiving unit of the first embodiment. The analysis unit 31 is connected to the complex Fourier transform units 30a to 30n.

The analysis unit 31 includes a complex Fourier transform unit 30a.
˜30n, the data when a plurality of antennas 28a to 28n are located at the same position are selected, and the instantaneous analysis of the Doppler frequency component developed in the delay time is selected based on the selected data. I do. That is,
As shown in FIG. 13, it is assumed that the antennas 28a to 28n, the receivers 29a to 29n, etc. are moving together at a moving speed v. First, the analysis unit 31 selects the Fourier transform result based on the received signal received by the antenna 28a at time T = 0 [FIG. 13 (A)]. Next, the analysis unit 31 selects the Fourier transform result based on the received signal received by the antenna 28b when the time T = L / v [FIG. 13 (B)].
Similarly, the Fourier transform result based on the received signal received by the antenna 28c at the time T = 2L / v is analyzed by the analysis unit 31.
Is selected [FIG. 13 (C)]. Therefore, time T = 0
At the position where the antenna 28a is located at time T = L
/ V, the antenna 28b is located, and the time T =
The antenna 28c is located at 2 L / v. For this reason, if one antenna is moved and measured, the measurement points will be different data.
In the embodiment, the analysis unit 31 can always perform the Doppler analysis based on the data received at the same position.

The configuration of the transmitting section of the sixth embodiment is exactly the same as that of the transmitting section of the first embodiment. Next, a seventh embodiment will be described.

FIG. 14 is a block diagram of the receiving section of the seventh embodiment. Since the configuration of the receiving unit of the seventh embodiment is basically the same as the configuration of the receiving unit of the first embodiment,
The same parts are designated by the same reference numerals and the description thereof will be omitted. In addition,
The configuration of the transmitter of the seventh embodiment is exactly the same as that of the transmitter of the first embodiment.

In the receiver of the seventh embodiment, a plurality of antennas 33a to 33n are arranged at equal intervals L along the moving direction. The RF band band limiting unit 4 is connected to the antennas 33a to 33n via the switch unit 34. When the plurality of antennas 33a to 33n are located at the same position, the switch unit 34 selects the output of the antenna and sends it to the RF band band limiting unit 4. That is, when the antennas 33a to 33n are integrally moving at the moving speed v, the switch unit 34 causes the antenna 33a to move every time L / v.
.About.33n are sequentially selected.

The complex Fourier transform unit 35 first corrects the phase of each reception spectrum of the reception signal received at the same antenna position. That is, the phase correction value Δθ _n is calculated and corrected according to the following equation (9).

[0050]

Δθ _n = − (ω ₀ + nΔω) Δt (9) where ω ₀ is the carrier frequency, Δω is the frequency interval of Doppler analysis, n is the order of Doppler, and Δt is the antenna switching time ( = L / v).

The reception spectra corrected in this way are combined and then subjected to complex Fourier transform. Next, the 8th
An embodiment will be described.

FIG. 15 is a block diagram of the transmitting section of the eighth embodiment. The configuration of the receiving unit according to the eighth embodiment is the same as the configuration of the receiving unit according to the first embodiment. The transmitter of the eighth embodiment is composed of two transmitters 37 and 38. The internal configuration of each transmitter 37, 38 is basically the same as the configuration of the transmitting unit of the first embodiment. However, it is arranged so that the spectrum component of the transmission signal of the transmitter 37 and the spectrum component of the transmission signal of the transmitter 38 do not overlap.

That is, as shown in FIG.
The spectrum of each transmission signal of 7, 38 is (A), (B)
Are arranged respectively. Therefore, the reception side receives a reception signal having a spectrum as shown in (C). Alternatively, as shown in FIG. 17, the spectrum of each transmission signal of the transmitters 37 and 38 is (A),
They are arranged as shown in FIG. Therefore, the reception side receives a reception signal having a spectrum as shown in (C).

In this way, the transmitter is composed of the two transmitters 37,
With the configuration of 38, it is possible to evaluate the multiple propagation characteristics including the Doppler shift when the transmission unit uses the transmission diversity method.

In the eighth embodiment, the number of transmitters is two.
Although it is configured by one transmitter, it may be configured by three or more transmitters. Next, a ninth embodiment will be described.

FIG. 18 is a block diagram of the receiving section of the ninth embodiment. Since the configuration of the receiving unit of the ninth embodiment is basically the same as the configuration of the receiving unit of the first embodiment,
The same parts are designated by the same reference numerals and the description thereof will be omitted. In addition,
The configuration of the transmitter of the ninth embodiment is the same as the configuration of the transmitter of the first embodiment.

The receiver of the ninth embodiment includes antennas 40a to 40n arranged spatially apart from each other and receivers (Rx) 41a to 41n connected to them. Each of the receivers 41a to 41n includes an RF band band limiting unit 4 and an RF / IF, which form the receiving unit of the first embodiment.
The converter 5, the local oscillator 6, and the IF band amplifier 7 have the same configurations. However, each local oscillator outputs local oscillation signals of different frequencies. Therefore, the IF output from each of the receivers 41a to 41n
The signal spectrum is slightly shifted as shown in FIGS. 19 (A) to 19 (C). The combining unit 42 combines the IF signals output from the receivers 41a to 41n and outputs a signal having a spectrum as shown in FIG. 19D to the complex Fourier transform unit 8.

As described above, by providing the plurality of antennas 40a to 40n arranged at spatially separated positions and the plurality of receivers 41a to 41n connected to the antennas 40a to 40n, the receiving section adopts the space diversity system. It is possible to evaluate the multiple propagation characteristics including the Doppler shift in the case of taking.

In the receiver of the ninth embodiment, the plurality of antennas 40a to 40n are arranged at spatially separated positions. Instead of this, a plurality of directional antennas are arranged radially. You may do it. In this case, it becomes possible to evaluate the multiple propagation characteristics including the Doppler shift when the receiving unit adopts the angle diversity method.

Further, in the ninth embodiment, the transmitting section may be configured by the transmitting section of the eighth embodiment. Next, a tenth embodiment will be described.

FIG. 20 is a block diagram of the receiving section of the tenth embodiment. The configuration of the transmission unit of the tenth embodiment is the same as the configuration of the transmission unit of the first embodiment. First
In the receiving unit of the 0th embodiment, the receiver 44 includes the RF band band limiting unit 4 and the RF band limiting unit 4 which constitute the receiving unit of the first embodiment.
The IF / IF converter 5, the local oscillator 6, and the IF band amplifier 7 have the same configurations. The branch part 45 is shown in FIG.
The output from the IF band amplifying unit 7 as shown in (A) is branched and sent to the complex Fourier transform units 46a to 46n. The complex Fourier transform units 46a to 46n are each composed of a complex Fourier transform device having different frequency ranges capable of performing complex Fourier transform. That is, the complex Fourier transform unit 46a selects from among the signals having the spectrum as shown in FIG.
A complex Fourier transform is performed only on the spectrum as shown in FIG. Similarly, the complex Fourier transform unit 46b performs a complex Fourier transform on only the spectrum as shown in FIG. 21C and outputs it to the analysis unit 48, and the complex Fourier transform unit 46n as shown in FIG. 21D. A complex Fourier transform is performed only on the spectrum and output to the analysis unit 48. The complex Fourier transform unit 46
The operations a to 46n are performed based on the sync signal from the sync signal generator 47. The analysis unit 48 also performs the same operation as the analysis unit 9 of the reception unit of the first embodiment based on the synchronization signal from the synchronization signal generation unit 47.

As described above, in the tenth embodiment, each of the complex Fourier transform units 46a to 46n may be a device having a narrow frequency range capable of performing the complex Fourier transform. Also, since the complex Fourier transform is performed in a narrow frequency range, the accuracy of Doppler analysis is improved.

[0063]

As described above, in the present invention, the transmission signal digitally modulated by the pseudo-random pattern is received while performing spatial movement, and the received signal received is subjected to the complex Fourier transform. Then, the Doppler frequency component expanded in the delay time is instantaneously analyzed on the basis of the transformed component subjected to the complex Fourier transform.

Therefore, the time required from reception to Doppler analysis is instantaneous, which is much shorter than in the conventional case.

[Brief description of drawings]

FIG. 1 is a diagram illustrating the principle of the present invention.

FIG. 2 is a configuration diagram of a receiving unit according to the first embodiment.

FIG. 3 is a configuration diagram of a transmission unit according to the first embodiment.

FIG. 4 is a diagram showing a spectrum of each transmission / reception unit.

FIG. 5 is a diagram showing a delay profile according to a Doppler shift amount.

FIG. 6 is a configuration diagram of a transmission unit according to a second embodiment.

FIG. 7 is a configuration diagram of a receiving unit according to the second embodiment.

FIG. 8 is a configuration diagram of a receiving unit according to a third embodiment.

FIG. 9 is a diagram showing a signal spectrum.

FIG. 10 is a configuration diagram of a receiving unit according to a fourth embodiment.

FIG. 11 is a configuration diagram of a receiving unit according to a fifth embodiment.

FIG. 12 is a configuration diagram of a receiving unit according to a sixth embodiment.

FIG. 13 is a diagram showing a processing timing.

FIG. 14 is a configuration diagram of a receiving unit according to a seventh embodiment.

FIG. 15 is a configuration diagram of a transmission unit according to an eighth embodiment.

FIG. 16 is a diagram showing a spectrum of transmission and reception.

FIG. 17 is a diagram showing another spectrum of transmission and reception.

FIG. 18 is a configuration diagram of a receiving unit according to a ninth embodiment.

FIG. 19 is a diagram showing a spectrum of each receiving unit.

FIG. 20 is a configuration diagram of a receiving unit according to the tenth embodiment.

FIG. 21 is a diagram showing a spectrum of each receiving unit.

[Explanation of symbols]

 1 receiving means 2 complex Fourier transforming means 3 Doppler analysis means

Claims (14)

[Claims] 1. A multi-propagation characteristic measuring apparatus for measuring multi-propagation characteristics in mobile communication, comprising: receiving means for receiving a transmission signal digitally modulated by a pseudo-random pattern while spatially moving; and receiving means received by the receiving means. A complex Fourier transform means for performing a complex Fourier transform on the received signal, and a Doppler analysis means for performing an instantaneous analysis of the Doppler frequency component expanded in the delay time, based on the transformed component converted by the complex Fourier transform means, A multi-propagation characteristic measuring device having. 2. The multiplex propagation characteristic measuring apparatus according to claim 1, wherein the receiving means includes an RF band band limiting means, an RF / IF frequency converting means, and an IF band amplifying means. 3. The local oscillation frequency of the RF / IF frequency conversion means and the reference signal frequency of the complex Fourier transformation means are stabilized, and the local oscillation frequency and the reference signal frequency are set in a pseudo random pattern on the transmission side. The multi-propagation characteristic measuring device according to claim 2, further comprising a highly stable synchronizing means for synchronizing the frequency and the frequency of a carrier wave of digital modulation. 4. A coded signal generating means, which is provided on the transmitting side and generates a coded signal of a pseudo random pattern, and a digital signal modulated by the coded signal, which is provided on the transmitting side and generated by the coded signal generating means. 2. The multi-propagation characteristic measuring device according to claim 1, further comprising a digital modulation means for performing. 5. The receiving means includes a local oscillating means capable of varying an oscillation frequency of a local oscillating signal, and an RF / IF frequency converting means for performing an RF / IF frequency conversion based on the local oscillating signal output from the local oscillating means. And, the multiplex propagation characteristic measuring device further comprises a timing signal output means for outputting a timing signal at each time interval of a plurality of times the frame length of the pseudo random pattern on the transmission side, the local oscillating means, Each time the timing signal is received from the timing signal output means, means for outputting to the RF / IF frequency conversion means a local oscillation signal whose oscillation frequency is higher than the previous frequency by the frequency interval of the spectrum constituent components of the discrete transmission signal is included. The multi-propagation characteristic measuring device according to claim 1. 6. The multi-propagation characteristic measuring device directly transmits a transmission signal from a transmission side without passing through a multi-propagation path.
Further comprising direct transmission means for sending to the receiving means, and storage means for storing data subjected to complex Fourier transform by the complex Fourier transform means on the basis of a reception signal received by the receiving means by the direct transmit means, The Doppler analysis means calculates the difference between the data stored in the storage means and the data subjected to the complex Fourier transform by the complex Fourier transform means based on the received signal received from the transmission side via the multiple propagation paths. 2. The multi-propagation characteristic measuring device according to claim 1, further comprising a determining unit. 7. The multiplex propagation characteristic measuring apparatus according to claim 1, further comprising a storage unit that continuously stores the output of the receiving unit. 8. A plurality of coded signal generating means, each of which is provided on the transmitting side and generates a coded signal of a pseudo-random pattern, and a corresponding coded signal generation connected to each of the plurality of coded signal generating means. 2. The multiple propagation characteristic measuring apparatus according to claim 1, further comprising a plurality of digital modulating means for digitally modulating the coded signals from the means and for preventing transmission signal spectra from overlapping each other. 9. A multi-propagation characteristic measuring apparatus for measuring multi-propagation characteristics in mobile communication, comprising: a plurality of antennas arranged in series in a movement direction and integrally moving; and a plurality of antennas respectively connected to the plurality of antennas, and a pseudo random pattern. A plurality of receiving means for receiving the transmission signal digitally modulated by the above while performing spatial movement, and a plurality of complex Fourier transforms for performing a complex Fourier transform on the reception signals received by the corresponding receiving means, respectively. The data when the plurality of antennas are respectively located at the same position is selected from the transforming means and the respective transformed components respectively transformed by the plurality of complex Fourier transforming means, and the Doppler spread in the delay time is selected. Doppler analysis means for performing instantaneous analysis of frequency components, and Apparatus. 10. A multi-propagation characteristic measuring apparatus for measuring multi-propagation characteristics in mobile communication, wherein a plurality of antennas arranged in series in a movement direction and moving integrally, and the plurality of antennas are located at the same position, respectively. At this time, a selection switch means for selecting the output of the antenna, a transmission signal digitally modulated by a pseudo-random pattern is respectively received from the selection switch means, and a reception means for performing reception processing, and reception at the same antenna position, After phase-correcting each reception spectrum of the reception signal respectively received by the receiving means and synthesizing each corrected reception spectrum,
A complex Fourier transform means for performing a complex Fourier transform; and a Doppler analysis means for performing an instantaneous analysis of the Doppler frequency component expanded in the delay time, based on the transformed components respectively transformed by the complex Fourier transform means, A multi-propagation characteristic measuring device characterized by. 11. A multi-propagation characteristic measuring apparatus for measuring multi-propagation characteristics in mobile communication, comprising: a plurality of antennas arranged at spatially different positions and moving integrally; A plurality of receiving means for receiving a transmission signal digitally modulated by a pattern while spatially moving, and for respectively shifting the frequencies by different frequencies, a combining means for combining the outputs of the plurality of receiving means, and the combining means. A complex Fourier transform means for performing a complex Fourier transform on the output of, and a Doppler analysis means for performing an instantaneous analysis of the Doppler frequency component expanded in the delay time, based on the transformed component converted by the complex Fourier transform means, A multi-propagation characteristic measuring device having. 12. A multi-propagation characteristic measuring apparatus for measuring multi-propagation characteristics in mobile communication, comprising: a plurality of directional antennas arranged in a radial pattern and moving integrally; A plurality of receiving means for receiving a transmission signal digitally modulated by a pattern while spatially moving, and for respectively shifting the frequencies by different frequencies, a combining means for combining the outputs of the plurality of receiving means, and the combining means. A complex Fourier transform means for performing a complex Fourier transform on the output of, and a Doppler analysis means for performing an instantaneous analysis of the Doppler frequency component expanded in the delay time, based on the transformed component converted by the complex Fourier transform means, A multi-propagation characteristic measuring device having. 13. A multi-propagation characteristic measuring apparatus for measuring multi-propagation characteristics in mobile communication, comprising: receiving means for receiving a transmission signal digitally modulated by a pseudo-random pattern while spatially moving; and receiving means received by the receiving means. A branching unit for branching the received signal into a plurality of outputs and a complex Fourier transform of each output from the branching unit; a plurality of complex Fourier transform units having different frequency ranges capable of complex Fourier transform; and a plurality of the complex Fourier transforms A multi-propagation characteristic measuring device comprising: a Doppler analyzing unit for instantaneously analyzing a Doppler frequency component developed in a delay time based on the transformed components respectively transformed by the means. 14. The multiplex propagation characteristic measuring apparatus according to claim 13, further comprising a synchronization signal generation means for transmitting a synchronization signal to the plurality of complex Fourier transform means and the Doppler analysis means.