JPS61196633A - Radio equipment inspecting method - Google Patents

Abstract

PURPOSE:To eliminate the necessity to constitute a special hardware and to execute simply the inspection by displaying the error ratio measured by an error ratio measuring processing part and an output device provided at the output of the radio system output data processing part, and applying and simulating a phasing and a thermal noise with the intermediate frequency of the radio equipment as carrier frequency. CONSTITUTION:An error ratio measuring processing part 14 compares the data generated at a wireless system input data processing part 6 with the data reloaded by a radio system output data processing part 13, and the error ratio is obtained. An output device 15 displays the transmission condition, an error ratio and a constellation based upon the dicision at the error ratio measuring processing part 14. An output device 16 graphs the amplitude and the phase change of the phasing data by the shape of the time function, and an output device 17 graphs the amplitude and the phase change of the thermal noise data, an additional noise in the shape of the time function. Respective can correspond to the error place displayed by the output device 15. An output device 18 is a radio system, displays the appearance of a frequency modulating wave, to which the phasing and thermal noise are applied, in the shape of the time function and can compare with the error condition of the output device 15.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method for inspecting radio equipment, and particularly to a method for evaluating various characteristics of a radio transmission path.

(Prior art) Figure 3 is a block diagram showing a configuration of a conventional error rate evaluation method for data transmission using radio equipment (IEICE 2003).
Collected papers from the National Conference of the Department of Communication - 65'2. "Data transmission over analog mobile communication lines").

This device consists of hardware such as a modem radio for the error vehicle side station, a fading simulator, and an attenuator.The error vehicle side station generator generates PN random data and also records the data before and after transmission. The function is to compare and measure the error rate.The modem is used for data baseband modulation and demodulation, the radio equipment is used for RF band modulation and demodulation, and the fading simulator measures the effect of fading on RF band modulated waves in the wireless propagation path. The effect of fading is quantitatively affected by simulating the BP' band and harmonic amplitude modulation. The purpose was to determine the ratio of thermal noise band-limited by the pass filter, that is, the carrier power to noise power ratio (C/N).

(Problems to be Solved by the Invention) However, with the error rate evaluation method having the above configuration, it is impossible to evaluate the error rate by quantitatively considering the influence of fading on the phase. There was a problem in that the hardware had to be configured.

This invention eliminates the above-mentioned problems in error evaluation and hardware configuration for fading phase changes, and clarifies the cause of errors in order to reduce transmission errors in wireless data communication. The purpose of this invention is to provide a method for inspecting radio equipment.

(Means for Solving the Problems) The present invention provides a method for testing the error rate of wireless data communications, and its features include: is performed by a computer-based simulator, and the simulator includes a simulation information setting section (1), a fading data file (2), a thermal noise data file (3), and a carrier power to noise power (C/N) ratio. A level matching processing section (4), a fading level matching processing section (5), a wireless input data processing section (6), an I-F band modulation processing section (7), and a fading addition processing section (8). , a thermal noise addition processing section (9), a limiter/amplification processing section (10), a bandpass filter processing section), an IF' band demodulation processing section (1), and a wireless system output data processing section (13). displaying the error rate measured by the error vehicle side determination processing section α (a) provided at the output of the wireless system output data processing section (13) and the output device;
The present invention relates to a radio equipment inspection method in which fading and thermal noise are added and simulated using the radio equipment's intermediate frequency as a carrier frequency.

(Function) Since the present invention uses shimmy ration using a computer, it is not necessary to configure special hardware for the test, and the test can be easily performed. can do.

External characteristics such as fading and thermal noise, and characteristics of radio equipment such as modulators and demodulators can also be freely set.

'(Embodiment) FIG. 1 is a block diagram showing an embodiment of the present invention, where l is a simulation information setting section, 2 is a fading data file, 3 is a thermal noise data file, and 4 is a carrier power Noise power (C/N) ratio level matching processing section; 5, fading level matching processing section; 6, wireless system input data processing section; 7, intermediate frequency (IP) band modulation processing section; 8, fading addition a processing section; 9, a thermal noise addition processing section; 10, a limiter amplifier processing section; 1;
1 is a band pass filter processing section, 12 is a 1F band demodulation processing section, 13 is a non-wireless system output data processing section, and 14 is:
The error vehicle side determination processing section 15-1.8 each indicates an output device.

The simulation information setting processing unit 1 sets initial values of information necessary for executing the present invention, such as the number of erroneous vehicle-side constant data, fading frequency, thermal noise generation frequency, IF band carrier frequency, IP band modulation frequency, and number of filter taps. Make settings.

The fading data file 2 is a fading data file created based on information set by the simulation information setting processing section 1, and can be read and written at any time. Similarly, the thermal noise data file 3 can also be read and written at any time. The C/N level matching processing section 4 performs the C/N level matching processing section 4 set by the simulation information setting processing section 1.
The data read from the thermal noise data file 3 is corrected so as to have the value of N, and the C/N level is adjusted. The fading level matching processing unit 5 performs processing on the data read from the fading data file 2.
The fading level is normalized by the median value of the power and further corrected by the C/N level in the C level matching processing section 4. The wireless system input data processing section 6 generates data necessary for determining the error vehicle side, and creates wireless system input data according to an appropriate transmission rate and modulation method.

The IP band modulation processing unit 7 applies wireless modulation to the input data generated from the wireless input data processing unit 6 using the carrier frequency as an intermediate frequency. Fading addition processing section 8
Using the fading data whose level has been matched by the fading level matching processing part 5, fading is added by applying orthogonal product modulation to the wireless system input data modulated by the IF band modulation processing part 7. The thermal noise addition processing section 9 modulates the thermal noise whose level has been adjusted by the C level adjustment processing section 4, and modulates it at the IP modulation processing section 7, and adds additive processing to the modulated wave affected by fading at the fading addition processing section 8. Add to. Limiter/amplifier processing section 10
The fading level is determined by adding to the output signal component from the thermal noise addition processing section 9 a value obtained by dividing the thermal noise component of the C level matching processing section 4 by the fading envelope component obtained from the fading addition processing section 8. The level of thermal noise is inversely proportional to the reduction in thermal noise. The bandpass filter processing section 11 is for band limiting of thermal noise. The IF band demodulation processing unit 12 demodulates the frequency modulated wave to which fading and thermal noise are added by frequency discrimination processing. The wireless output data processing unit 13 demodulates the wireless output data according to the modulation performed by the wireless input data processing unit 6, and restores the transmission input data. Wrong vehicle side determination processing unit 14
compares the data generated by the wireless system input data processing section 6 and the data restored by the wireless system output data processing section 13, and calculates the error rate. The output device 15 displays the transmission status, error rate, and constellation based on the determination made by the error vehicle determination processing section 14.

The output device 16 graphs the amplitude and phase fluctuations of the fading data in the form of a time function, and makes it possible to correspond to the location where the error has occurred, which is displayed on the output device 15. Output device 1
7 graphs the amplitude and phase fluctuations of thermal noise data, which is additive noise, in the form of a time function, so that it can correspond to the error location displayed on the output device 15. The output device 18 displays the state of the frequency modulated wave to which fading and thermal noise are added in the wireless system in the form of a time function, so that it can be compared with the error situation of the output device 15.゛Figure 2 is an example of error rate testing of data generated in the wireless system input data processing unit in Figure 1 with a modulation system of 8-phase PSK and a transmission rate of 4800 bps. , I
The F-band carrier frequency is set to ≦, and the error rate is determined using the C/N value as a parameter and displayed on the output device 15. The values indicated by the dotted line in Fig. 2 are the simulation results considering only the influence of thermal noise, and the values indicated by the solid line in Fig. 2 are as follows.
This takes into account fading and thermal noise in the wireless system.

(Effects of the Invention) As described above in detail, the present invention includes a fading amplitude error rate evaluation model logic section, a fading phase error rate evaluation model logic section, and a thermal noise evaluation model logic section, and Since the wireless equipment testing method is characterized by adding fading thermal noise as a carrier frequency, it is possible to evaluate errors in phase changes due to fading, and it is expected that there will be no need for hardware configuration. Furthermore, since the wireless system error causes such as fading and thermal noise are configured with independent model logic sections, an urban noise addition processing section is provided between the thermal noise addition processing section 9 and the limiter/amplification processing section 100, and wireless data communication In order to inspect the influence of urban noise during the process, we also set up a separate wireless transmission line from the IP band modulation processing section 7 to the IF band demodulation processing section 12, and made it consistent with the fading data file created in fading data file 2. By creating another fading data file with a correlation of , and additionally processing it, it can also be applied to examining the effect of diapersity.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a radio device testing device according to the present invention, FIG. 2 is a diagram showing an embodiment of data transmission error rate testing according to the present invention, and FIG. 3 is a diagram showing errors in data transmission using a conventional radio device. FIG. 2 is a block diagram showing an example of rate evaluation. 1; Simulation information processing setting unit, 2; Fading data file, 3; Thermal noise data file, 4; C/N level matching processing unit, 5; Fading level matching processing unit, 6; Wireless system input data processing unit, 7 ; IF band modulation processing unit; 8; Fading addition processing unit; 9; Thermal noise addition processing unit; 10; Limiter/amplification processing unit; 11; Band pass filter processing unit; 12; IF band demodulation processing unit; 13; Wireless System output data processing section, 14; Error vehicle side determination processing section, 15-18; Output device.

Claims (1)

[Claims] In an inspection method for a radio device that can operate with angle modulation and amplitude modulation, the inspection is performed by a computer-based simulator, and the simulator includes a simulation information setting section (1), a fading data file (2), and a thermal noise data file. (3), a carrier power to noise power (C/N) ratio level matching processing section (4), a fading level matching processing section (5), a wireless system input data processing section (6), and an IF band modulation processing section. section (7), fading addition processing section (8), thermal noise addition processing section (9), limiter/amplification processing section (10), bandpass filter processing section (11), and IF band demodulation processing section. (12), and a wireless system output data processing section (13), and an error rate measurement processing section (14) provided in the output of the wireless system output data processing section (13) and an error measured by the output device. 1. A radio equipment inspection method characterized by displaying a frequency and simulating by adding fading and thermal noise using an intermediate frequency of the radio as a carrier frequency.