JPH04123537A - Multi-path fading simulator - Google Patents

Abstract

PURPOSE:To generate fading over a wide frequency range by using an output of a variable frequency oscillator so as to convert a carrier frequency of a multi-path fading signal into a carrier frequency of an input modulation wave. CONSTITUTION:An input signal is converted 14 into a prescribed input frequency of a multi-path fading signal simulator 15 and five paths with different delay time are generated 31 in the multi-path fading signal simulator 15. The output of the multi-path fading signal simulator 15 is converted into a frequency equal to the frequency of the input signal and outputted 16. The frequency of a variable frequency oscillator 18 in which the input signal is converted into the prescribed input frequency of the multi-path fading signal simulator 15 and the output of the multi-path fading signal simulator 15 is converted into the same frequency as that of the input signal, takes two values so as to make the carrier frequency constant and the frequency is displayed on a display means 20. Thus, fading is generated over a wide frequency range.

Description

[Detailed Description of the Invention] [Objective of the Invention] (Industrial Application Field) The present invention relates to a multipath fading simulator that virtually generates multipath fading that occurs in a transmission path in a moving signal indoors. be.

(Prior Art) Conventionally, when signal transmission is performed in mobile radio communication, the level of a received wave fluctuates greatly due to multipath propagation, resulting in a significant deterioration of transmission characteristics. A fading simulator is used to efficiently examine transmission characteristics indoors.

In the fading simulator, the input wave 5(t) is S
(t) = s, cos (ωct)S=CO3(
ωe1) ... If it is expressed as ■, the output wave r(t) is r(t) = a, (t)s+cos
(ω, t)-at(t)szcos(ωct)'°°■
It is converted as follows. However, sl and s2 are the amplitudes of the in-phase and quadrature components of the signal, ω. is the carrier frequency. Also, at(t) and ax(t) are the real part and imaginary part of the fading complex envelope signal z(t), where a
t(t) and a2(t) usually have a Gaussian distribution with an average value of zero. A signal with such a Gaussian distribution is
This is obtained by band-limiting the output PN signal of a PN (pink noise) signal generator, which has a very long period, using a low-pass filter whose bandwidth is sufficiently small compared to the clock frequency of the PN signal. That is, two series of PN signals are generated by two PN signal generation circuits, these PN signals are regarded as white noise, and the spectrum is shaped by a low-pass filter, and the fading complex envelope at(t) and ax(
t) is occurring.

By the way, when the delay time due to multipath propagation becomes larger than the symbol interval of the signal, in an actual propagation path, not only the level fluctuation of the received wave as described above but also the frequency characteristics of the propagation path become a problem. Such a propagation path cannot be approximated by the fading simulator described above. FIG. 3 shows the configuration of a multipath fading simulator that simulates a propagation path with frequency characteristics.

In this multipath fading simulator, a modulated signal is supplied to a power distribution circuit 31 via an input terminal 30, and is divided into five waves by this power distribution circuit 31. Among these five waves, one wave is directly supplied to the quadrature modulator 32, and the remaining four waves are supplied to the delay circuits 3 with different delay times.
3 and then supplied to the quadrature modulator 32. The signals divided into five waves are modulated in a quadrature modulator 32 with signals generated by five independent two-dimensional Gaussian noise ordering circuits 34, synthesized in a synthesis circuit 35, and outputted from an output terminal 36. In this example, it is possible to order five waves with different delay times, that is, five paths.

FIG. 4 shows the configuration of a fading simulator for die-hard reception. This example simulates two-branch diversity, and the signals divided into two by the power distribution circuit 40 are input to two fading simulators 41 and 42, respectively. 2
The configuration of two fading simulators 41 and 42 is
Since the configuration is the same as that of the multipath fading simulator shown in the figure, the same components are given the same reference numerals as in FIG. 3, and their explanation will be omitted. Note that, in general, in a multipath fading simulator with multiple branches, the delay times of corresponding paths are assumed to be equal.

(The secret problem that the invention attempts to solve) However, in the conventional multipath fading simulator shown in FIG.
A surface acoustic wave (surface acoustic wave) filter is used, but based on its principle, the SAW filter has a characteristic that as the delay time increases, the signal passband becomes narrower. Therefore, the conventional multipath fading simulator using a SAW filter as a delay element has the disadvantage that the range of the carrier wave frequency of the input modulated wave cannot be made sufficiently large.

Furthermore, in the conventional multipath fading simulator for diversity shown in FIG. 4, two branches (fading simulator 41.
2) There is a drawback that correlation cannot be given to the two-dimensional Gaussian noise between.

The present invention aims to eliminate the drawbacks of the prior art described above, and its purpose is to be able to generate fading over a wide frequency range and to reduce the correlation between branches, which is necessary when simulating diversity reception. An object of the present invention is to provide a multipath fading simulator that can be realized with a very simple circuit configuration by limiting the delay time to only paths with the same delay time.

[Structure of the Invention] (Means for Solving the Problems) A multipath fading simulator of the first form of the present invention that achieves the above object uses the output of a variable frequency oscillator to change the carrier frequency of an input modulated wave to a constant frequency. means for converting the carrier frequency of the multipath fading signal into the carrier wave of the input modulated wave using the output of the variable frequency oscillator; The present invention is characterized by comprising means for converting the frequency into a frequency, and display means for changing the display value of the input modulated wave frequency depending on the relative relationship between the output of the variable frequency oscillator and the frequency of the input modulated wave.

Furthermore, the multipath fading simulator of the second form sets the delay profiles of the multipath fading generation circuits of multiple branches and each multipath fading generation circuit to be the same, and generates fading complex envelope signals on buses having the same delay time. It is characterized by having a multipath control circuit that inserts a predetermined correlation only between the two.

(Operation) According to the multipath fading simulator of the first form of the present invention, an input signal is converted to a constant input frequency of the multipath fading simulator, and in this multipath fading simulator, five paths having different delay times are occurs. The output of the multipath fading simulator is converted to the same frequency as the input signal and output. Here, the frequency of the variable frequency oscillator that converts the input signal to a constant input frequency of the multipath fading simulator and the output of the multipath fading simulator to the same frequency as the input signal is set so that the carrier frequency is constant. It can take two values and its frequency will be displayed.

According to the multipath fading simulator of the second aspect of the present invention, the delay profiles of each circuit of the multipath fading generation circuit of multiple branches are set to be the same, and between fading complex envelope signals on paths having the same delay time. A defined correlation is entered only in the

(Example) Hereinafter, the present invention will be described in detail by way of an example with reference to the drawings.

A first embodiment of the present invention is shown in FIG. 1, and the same members as in the prior art are given the same reference numerals and will be explained. The input signal applied to the input terminal 11 is input to a first frequency conversion circuit 14 consisting of a mixer 12 and a bandpass filter 13,
It is converted to a constant frequency, that is, the input frequency of the multipath fading simulator 15.

This multipath fading simulator 15 has a third
The configuration is the same as that explained in the figure, and when the modulated signal is supplied to the power distribution circuit 31, the modulated signal is supplied to the power distribution circuit 31.
It is divided into 5 waves by 1. Among these five waves, one wave is directly supplied to the quadrature modulator 32, and the remaining four waves are supplied to the quadrature modulator 32 after passing through delay circuits 33 having different delay times. The signal divided into five waves is modulated in the quadrature modulator 32 with the signals generated by five independent two-dimensional Gaussian noise generation circuits 34, synthesized in the synthesis circuit 35, and output from the output terminal 36. different 5
Two waves, or five buses, are generated.

The output of the multipath fading simulator 15 is input to a second frequency conversion circuit 16 consisting of a mixer, converted to the same frequency as the input signal, and outputted from an output terminal 17. Control circuit 19 also sends a control I voltage to variable frequency oscillator 18, which generates a frequency that converts the carrier frequency of the input modulated wave to a constant frequency and sends it to mixer 12.16. Further, the control circuit 19 sends information on the oscillation frequency to the frequency display circuit 20 to display the carrier frequency of the input modulated wave.

Now, if the carrier wave frequency of the input signal and output signal is fc, the input/output frequency of the fading simulator 15 is fi, and the frequency of the variable frequency oscillator is fo, fc= f, +fi...■ fc= f, -f, ・...■ Two cases occur. (2) is a case where the frequency f2 of the variable frequency oscillator is used as a local oscillation frequency (Lower Local) lower than the frequency f3 of the carrier wave frequency, and (2) is a case where the frequency f of the variable frequency oscillator is used as a local oscillation frequency (Lower Local) higher than the frequency fC of the carrier wave frequency. Oscillation frequency (Llpper
This is the case where the output of the mixer 16 is not inserted with a bandpass filter.
It can be used in two different cases. By using such a method, the usable frequency band of the multipath fading simulator can be further expanded than the frequency variable range of the variable frequency 18. Further, at this time, the frequency display circuit 20 may select and display one of the two frequencies. In this case, it is necessary to attach a bandpass filter for removing the image frequency output from the mixer 16 to the side of the circuit under test using this fading simulator.

A second embodiment of the present invention is shown in FIG. 2, which shows the configuration of a fading simulator for diversity reception. This example simulates a two-branch die-hard circuit, and the signals divided into two by the power distribution circuit 40 are input to two fading simulators 41 and 42, respectively. The configurations of the two fading simulators 41 and 42 are the same as the configuration of the multipath fading simulator shown in FIG. 3 except for the configuration of the two-dimensional Gaussian noise generation circuit 34, so the same components are designated by the same reference numerals as in FIG. , and the explanation thereof will be omitted. In this example, two fading simulators 4
The corresponding quadrature modulator 32 of 1.42 is connected to an independent two-dimensional Gaussian noise generation circuit 22 via a correlation addition circuit B21 provided outside the fading simulator 41.420.
is modulated by the generated signal.

In a multipath fading simulator with multiple branches at -1, the delay times of corresponding paths are equal, so paths with matching delay times of delay profiles are selected. Here, it is assumed that the Mth path PIN of branch 1 and the Nth path P2N of branch 2 have the same delay time.

Fading complex envelope ZIM and Z2 of PIN and P2N
N can be generated by forming a circuit expressed by the following equation.

Z IN=χ】M Zzy= 9 X rpt+J7 x, NHowever,
XIM and XZN are mutually independent complex Gaussian signals obtained by connecting a PN signal generator and a low-pass filter. At this time, <XIM ” >=<
XZN” ＞=(F”, then <Z, H” ＞=< l ZzH” ＞= 6”<
Z IN Z ``zu>=96'', and a signal having a correlation of ρ between the complex Gaussian signals ZIM and ZZU is obtained.

In this way, by adding correlation only to paths with the same delay time, a signal having correlation can be obtained, and the scale of the apparatus can be made much smaller than when all correlations are added.

〔Effect of the invention〕

According to this invention, fading can be generated over a wide frequency range, and the correlation between branches, which is necessary when simulating diversity reception, is limited to only paths with the same delay time, thereby creating a very simple circuit. This has the effect of being able to be achieved through configuration.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram of a multipath fading simulator with a frequency conversion circuit according to a first embodiment of the present invention, and FIG. 2 is a two-branch type that can add correlation between branches according to a second embodiment of the present invention. FIG. 3 is a block diagram of a conventional multipath fading simulator. FIG. 4 is a block diagram of a conventional two-branch multipath fading simulator. 11... Input terminal work 2... Mixer, 13... Band pass filter, 14... Frequency conversion circuit, 15... Multipath fading simulator, 16
...Mixer, 17...Output terminal, 18...Variable frequency oscillator, 19...Control circuit, 20...Display circuit, 21...Correlation addition circuit, 2234...Two-dimensional Gaussian noise Generation circuit, 31.40
...Power distribution circuit, 32... Quadrature modulator, 33... Delay circuit, 35... Synthesizing circuit.

Claims (2)

[Claims] (1) means for converting the carrier frequency of the input modulated wave into a constant frequency using the output of the variable frequency oscillator; and delay processing;
means for performing fading modulation processing and synthesis processing to generate a multipath fading signal; means for converting a carrier frequency of the multipath fading signal to a carrier frequency of an input modulated wave using the output of the variable frequency oscillator; A multipath fading simulator comprising display means that can change the display value of the input modulated wave frequency depending on the relative relationship between the frequency oscillator output and the frequency of the input modulated wave. (2) Set the delay profiles of the multipath fading generation circuits of multiple branches and each multipath fading generation circuit to be the same, and insert a determined correlation only between fading complex envelope signals on paths with the same delay time. A multipath fading simulator comprising a multipath control circuit.