JP2000028664A - Broadcast electronic wave propagation analysis system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide information regarding the effective electronic wave propagation status for a transmission/relay base location plan at the initial stage of the plan. SOLUTION: A system is provided with an electric field strength calculation means 15 for obtaining the strength of an electric field at each mesh, based on analysis conditions and broadcasting station elements which are inputted from an inputting means 2, a maximum electric field strength calculation means 16 for obtaining the maximum electric field strength at each mesh, based on the strength of the electric field being calculated by the strength calculation means, and an interference calculation means 17 for obtaining the presence or absence of interference at each mesh, based on the strength of electric field being calculated by the strength calculation means. Thus the strength of electric field, the maximum electric field strength, and the presence or absence of interference are stored in a storage means 3 as analysis data, and a map and an analysis result based on map and analysis data are output visually, namely outputting the electronic wave propagation status of a broadcasting station on a mesh map by an electric field strength graph, the maximum electric field strength graph, an interference graph, and the like. The maximum electric field strength graph, the interference graph, and the like are outputted by selecting the combination of broadcasting stations.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of calculating the electric field strength from a broadcasting station in each mesh divided into meshes for each area by inputting broadcasting station data and analyzing the propagation condition of a broadcasting wave of each broadcasting station. The present invention relates to a broadcast wave propagation analysis system.

[0002]

2. Description of the Related Art In order to realize digital terrestrial broadcasting, it is necessary to analyze the state of radio wave propagation in order to transmit television radio waves and to plan the location of a relay base. Conventionally, in the location planning of TV radio transmission and relay bases, base planning is performed so that radio waves of a predetermined output reach a predetermined range by combining transmission and relay bases, but when planning on a desk, actually It is difficult to imagine what combination will reach a predetermined range.

[0003]

For example, in planning a base location, it is necessary to satisfy the following. First,
The fact that the radio wave has reached the planned area by the combination of transmitting and relaying points, taking into account the influence of the same type of transmitting and relaying points around the planning area, the population distributed in the planning area,
That is, a radio wave satisfying a predetermined condition reaches a household or the like. In the location plan for communication and relay bases,
Since the optimal location is planned by simulating the radio wave propagation condition by a theoretical formula using the position and characteristics of the base, the regional topography, etc., an error occurs from the actual propagation condition. In order to minimize this error, correction based on an actually measured value may be performed.

[0004]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and provides information on a radio wave propagation condition which is effective for a transmission / relay base location plan at an initial stage of planning.

[0005] To this end, the present invention provides a broadcast system in which the specifications of a broadcasting station are input, the electric field strength from the broadcasting station in each mesh divided into meshes for each area is calculated, and the propagation condition of the broadcast wave of each broadcasting station is analyzed. A radio wave propagation analysis system,
Map data storage means for storing map data divided into meshes for each region; analysis conditions, broadcast station specifications, input means for selecting analysis conditions and broadcast station specifications, and inputting instructions; The analysis conditions, the electric field intensity calculating means for obtaining the electric field strength in each of the meshes based on the broadcast station specifications, and the maximum electric field strength calculating means for obtaining the maximum electric field intensity in each of the meshes based on the electric field strength calculated by the intensity calculating means. Interference calculation means for determining the presence or absence of interference in each of the meshes based on the electric field strength calculated by the strength calculation means, the electric field strength, the maximum electric field strength,
Analysis data storage means for storing the presence or absence of interference as analysis data; output means for outputting a map and an analysis result based on the map data stored in the map data storage means and the analysis data stored in the analysis data storage means; A broadcast station input by the input unit, controlling each of the calculation units based on the analysis condition, storing the analysis data in the analysis data storage unit, the map data stored in the map data storage unit, and the analysis data Control means for controlling the output of the output means based on the analysis data stored in the storage means.

The electric field strength calculation means performs a circumferential division and a radial calculation division to determine whether there is a view from a broadcasting station based on the division pitch, whether there is a mountain related to mountain diffraction between transmission and reception points, or whether a reflected wave exists. Calculate the electric field strength in the radiation direction in consideration of whether the area is blocked by the mountain, and calculate the intensity of each mesh by interpolating based on the calculated values in the radiation direction at three points in the vicinity of each mesh. The electric field strength calculating means performs the strength calculation by comparing the electric field strengths of the target broadcasting stations to obtain the maximum value, and the interference calculating means sets the broadcasting station which is subject to the interference as the desired station and the same as the desired station. The broadcast station of a channel and an adjacent channel is searched for the interference station as an interference station, interference calculation is performed for a selected interference station among the searched interference stations, and the presence or absence of the interference is determined by the electric field strength of the desired station and The obstruction It is characterized in that the difference in electric field strength of a station is determined by the greater or not than a predetermined interference interference ratio.

[0007] The map data has statistical data such as population and the number of households for each of the meshes.
The map data, the statistical data, and the analysis data are superimposed and output to the output means, and the control means classifies the statistical data and the analysis data and outputs them to the output means in different output modes, and outputs the statistical data. The apparatus is characterized in that it comprises means for totalizing the analysis data of each of the meshes and calculating a ratio of the statistical data to a total value in a specified range.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing an embodiment of a broadcast wave propagation analysis system according to the present invention, FIG. 2 is a diagram showing a data configuration example of a map data file, FIG. 3 is a diagram showing a configuration example of map management data, and FIG. FIG. 5 shows an example of a data configuration of a color set setting file, FIG. 6 shows an example of a data configuration of an electric field intensity calculation result file, and FIG. 7 shows a maximum electric field intensity. FIG. 8 is a diagram showing a data configuration example of a calculation result file, and FIG. 8 is a diagram showing a data configuration example of an interference calculation result file.

In FIG. 1, 1 is an output device, 2 is an input device, 3 is a storage device, 4 is an arithmetic processing device, 11 is a map data file, 12 is a setting data file, 13 is an analysis data file, and 14 is input / output. A control unit, 15 is an electric field intensity calculation unit, 16 is a maximum electric field intensity calculation unit, 17 is a radio wave interference calculation unit, and 18 is a calculation result output control unit. The output device 1
When performing broadcast radio wave propagation analysis, from the initial menu screen, system settings, analysis condition settings, data input,
It comprises various output means such as a display, a printer, an XY plotter, etc., for switching various screens for outputting analysis results and the like in accordance with a switching instruction, for displaying and outputting, or for printing out. The input device 2 includes various input means such as a keyboard, a touch panel, and a mouse for inputting instructions, setting information, selection information, and data according to a menu screen of the output device. The storage device 3 includes various data files required for broadcast radio wave propagation analysis, such as a map data file 11 including map data obtained by dividing each region into meshes, statistical data, and the like, a setting data file 12 including setting data such as analysis conditions, and analysis calculations. An analysis data file 13 including the data of the result is stored.

The arithmetic processing unit 4 includes an input / output control unit 14 for controlling input / output between the output device 1, the input device 2, and the storage device 3, and an electric field intensity for calculating an electric field intensity in each mesh as a broadcast radio wave propagation analysis. It has a calculator 15, a maximum electric field strength calculator 16 for calculating the maximum electric field strength, a radio interference calculator 17 for calculating the presence or absence of radio interference, a calculation result output controller 18 for controlling the output of the result of the analysis calculation, and the like.

The map data file 11 stored in the storage device 3 manages, for example, map management data as shown in FIG. 2, map data and statistical data in each mesh obtained by dividing each area into meshes. The map management data has, for example, as shown in FIG. 3, information on the area A1, coordinates of latitude and longitude corresponding to each of the meshes a101, a102,... In the area A1, map data, and statistical data. The map data is composed of, for example, a background map such as an administrative boundary, a contour map, and elevation mesh data, and the statistical data is composed of, for example, data such as a region of the map data, a population corresponding to the mesh, and the number of households.

The setting data file 12 is composed of various setting data necessary for the analysis of the broadcast radio wave propagation. For example, an interference ratio, a service area threshold, a calculation condition, a calculation range, a color set, an electric field for determining the presence or absence of radio interference. It is a file of each data such as curve display, broadcast station specifications, transmission antenna directional characteristics, electric field strength chart, and the like. For example, in the broadcasting station specification file, as shown in FIG. 4, for each broadcasting station name, its transmission point position (latitude / longitude), frequency (MHz), maximum effective radiation power (kW), transmission power (kW), It has information such as transmission antenna height (m), elevation above sea level (m), transmission antenna directional characteristics (reference file), polarization plane (horizontal / vertical), and broadcast system (analog / digital). In the color set setting file, as shown in FIG. 5, the output color assigned to each rank of the electric field strength (dB), the output color assigned to the presence or absence of radio wave interference, and the rank of the household distribution (statistical information) as shown in FIG. , And information on the line width, and information on the line width.

The analysis data file 13 is a file of each data such as an electric field intensity calculation result obtained by the electric field intensity calculation, a maximum electric field intensity calculation result obtained by the maximum electric field intensity calculation, and an interference calculation result obtained by the radio wave interference calculation. . For example, as shown in FIG. 6, the electric field strength calculation result file includes an area A1 and meshes a in the area A1.
101, a102,... Each broadcasting station H1, H2,
.., And additional information such as analysis conditions and broadcast station specifications. The maximum electric field strength calculation result file includes, as shown in FIG. 7, a region A1 and meshes a101 and a10 in the region A1.
2. Combinations of broadcast station names (H1, H3,
...), (H2, H3,...),.
Further, it has information such as analysis conditions as the additional information. The interference result file includes the meshes a101, a10 of the desired broadcasting stations H1,... Selected as shown in FIG.
2. Interfering broadcast stations (H5, H8, ...) in ...
(H2, H4,...),..., And additional information such as analysis conditions.

Next, the contents of processing executed by the broadcast wave propagation analysis system according to the present invention will be described in detail. FIG. 9 is a diagram for explaining the flow of the entire analysis process of the broadcast radio wave propagation analysis system and the input / output of files in each process, and FIG. 10 is a diagram for explaining the concept of electric field strength calculation.

As shown in FIG. 9, the flow of the overall analysis processing of the broadcast radio wave propagation analysis system according to the present invention is as follows. Threshold file, calculation condition setting file, calculation range setting file, color set setting file, electric field curve display setting file, transmission antenna directional characteristics file specified by broadcasting station specifications for each selected area, and also determined by the Radio Law An electric field strength chart file describing the correction values is set.

In the interference ratio setting, in each of analog-digital, digital-analog, digital-digital, and analog-analog, the interference protection ratio (dB) of the same channel, the interference protection ratio of the upper adjacent channel, the lower adjacent The interference protection ratio of the channel, that is, the interference protection ratio of the same channel and the upper and lower adjacent channels is set.

In the service area threshold value, the service area threshold value (d
B) Set each service area threshold when the desired station is digital.

In the electric field curve display setting, for example, (0.0
0, Red, 1.5 mm), (-20.00, Orange,
1.5mm), (-20.00, Green, 1.5mm)
DB value to display the electric field curve and the maximum electric field curve,
For the color and the line width, the correspondence between the values of the electric field curve and the maximum electric field curve and the display color is set.

In the directional characteristics of the transmitting antenna, the horizontal angle is-
From 180 ° to 180 °, vertical angle is -90 ° to 90 °
And the gain (dB) is 0 or less, for example, horizontal (-
180 °, -30dB), (-70 °, -30dB),
(−60 °, 0 dB), vertical (−90 °, −30d)
B), the angle and the gain are set for each of the horizontal and vertical directions, such as (−30 °, −30 dB).

In the calculation condition setting, conditions for various calculations performed in the system are set for each region, and the circumference division as to how many times a profile is drawn around a broadcasting station as shown in FIG. Number, calculate the calculation radius from the maximum radiated power of the broadcasting station (the maximum value of the calculation radius is, for example, 200 km), and the profile division pitch which is a point that refers to the elevation value in the profile from the broadcasting station to the calculation radius. (M) is set, and a radial calculation division pitch (m) which is a calculation point within a radial from the broadcasting station to the calculation radius at an integral multiple of the profile division pitch is set, and a mesh size for performing calculation ( For example, 250m, 500m, 1000m,
100m). The commonly used divisions of primary mesh to tertiary mesh are defined as follows. The primary mesh is a section obtained by dividing a nationwide area vertically and horizontally by meridians every one degree and parallels every two-thirds (40 minutes), and is about 80 km square. An approximately 10 km square section obtained by equally dividing the primary mesh vertically and horizontally by 8 is a secondary mesh, and an approximately 1 km square section obtained by equally dividing the secondary mesh vertically and horizontally by 10 is a tertiary mesh.

In the calculation range setting, various calculation ranges to be set in the system are set for each region based on the lower left longitude (second) and latitude (second) and the upper right longitude (second) and latitude (second). The range that can be set as the calculation range is, for example, within the range of 50 m elevation data to be used.

In the electric field intensity chart, the electric field intensity correction value (dB) obtained from the value (m) obtained by subtracting the altitude of the receiving point from the altitude of the transmitting point and the distance (km) on the map between the transmitting and receiving points is based on the radio law. It is determined, and the difference between the transmitting and receiving points above sea level / the distance between transmitting and receiving points /
The correction value is set in the file image. This correction value differs between a case where the distance between the transmitting and receiving points is 4 km or more and 10 km or less and a case where the distance is 10 km or more.

When the above system settings are made, a background map and a contour map are read by region selection and displayed on a screen.
Further, the elevation mesh data is read. Then, the broadcast station settings are used to set the positions of the broadcast stations (transmission and relay bases) on the map, and the specifications of each broadcast station as described above with reference to FIG. 4 are set. Here, as the position (latitude / longitude), a manually input value is reflected on the screen, or a clicked position (latitude / longitude) on the screen is input. The sea level altitude can refer to the sea level altitude of the latitude and longitude input at the transmission point position from, for example, a 50 m altitude file. The calculated height is the height of the transmitting antenna plus the height of the sea.

Various calculations are executed based on the above settings.
In the electric field intensity calculation, the electric field intensity of the selected broadcasting station is calculated in the calculation range according to the calculation range setting file, and the electric field intensity calculation result file, the electric field intensity additional information file,
Save as an electric field strength curve file. In the maximum field strength calculation, the maximum field strength of the selected broadcasting station is calculated in the calculation range according to the calculation range setting file, and is stored as a maximum field strength calculation result file and a maximum field strength additional information file. In the interference calculation, a desired broadcasting station is selected, interference calculation is performed, and the result is stored as an interference result file, an interference D / U file (for each interference station), and an additional interference information file. Here, the selection of the desired broadcasting station is performed by selecting from a list or on the screen, and the interfering broadcasting station searches for the same, adjacent channel from the frequency of the desired broadcasting station, and determines the target from the searched interfering broadcasting station. Is selected as a broadcast station to be subjected to interference calculation and calculation is performed. For the D / U value, D / U value = field strength of desired station−field strength of interfering station.
The same processing is performed for both analogs, and the presence / absence of interference is distinguished by a threshold for determination for each digital / analog combination. Note that, in order to execute the interference calculation, the electric field strength calculation must be performed.

When various calculations are completed, for example, by selecting a desired broadcast station as a display setting, the calculation results are displayed on an electric field intensity mesh diagram, a maximum electric field intensity mesh diagram, an interference mesh portion, an electric field curve line diagram, a statistical distribution diagram. It is displayed and output in various figures such as a perspective view. In this case, a background map, a broadcast station name, and contour lines are appropriately selected as a background, and at the same time, a mesh diagram and an electric field curve of a broadcast station desired to be displayed are selected. In addition, as a profile, a perspective view is displayed based on designation of a point on a map, designation of a broadcasting station, and designation of two points by latitude and longitude. The parameters for this calculation are
Longitude, altitude (elevation above sea level + antenna height). In addition, parameters (broadcast station specifications) of the displayed mesh diagram are displayed as additional information. For example, if the displayed mesh diagram is the field strength result, the field strength result additional information is displayed.If it is the maximum field strength result, the maximum field strength result additional information is displayed. Displays the interference result additional information.

Next, various calculation processes will be described. 11 and 12 are diagrams for explaining the electric field intensity calculation process, FIG. 13 is a diagram for explaining an interpolation process for expanding the electric field intensity calculation result into a mesh, and FIGS. 14 and 15 are diagrams illustrating a subroutine process. FIG. 16 is a diagram showing an example in which there is a mountain related to mountain diffraction between transmission and reception points.

In the processing for calculating the electric field strength, first, as shown in FIG. 11, the number of circumferential divisions and the number of radial calculation divisions for dividing radiation are read based on the broadcasting station specification file and calculation condition setting file (step S11). , 12), the points within the calculation range are extracted (step S13), and whether each calculation point has a view from the broadcasting station, whether there is a mountain related to mountain diffraction between the transmission and reception points, and reflection. It is determined whether the wave is blocked by the mountain (steps S14 to S16). According to these determinations, if there is a prospect from the broadcast station and there is a mountain related to mountain diffraction, the process A is executed.
If there is a prospect from the broadcast station, there is no mountain related to mountain diffraction, and the reflected wave is blocked by the mountain, the process B is executed. Further, when there is a view from the broadcasting station, there is no mountain related to mountain diffraction, and when the reflected wave is not blocked by the mountain, the processing C is executed. When there is no view from the broadcasting station, the processing D is performed. By executing, the electric field strength in each radiation direction is obtained, and the electric field strength is stored in the calculation result file.

Next, based on the radiation direction calculation result file, calculation condition setting file, and broadcasting station specification file, FIG.
As shown in FIG. 2, the number of meshes in the Y direction and the number of meshes in the X direction are read (steps S17 and S18), meshes within the calculation range are extracted (step S19), and calculated for each profile as shown in FIG. Based on the obtained electric field strength in the radiation direction, the electric field strength of each mesh is calculated by linear interpolation of three points in the vicinity of the mesh to be obtained, and is stored in the electric field strength calculation result file and the electric field strength additional information file (step S20).

The processing A is performed by directing the directivity D1 (horizontal directivity of the transmitting antenna) of the position (horizontal angle, vertical angle) of the calculation point viewed from the transmitting point with reference to the transmitting antenna directivity file as shown in FIG. ), D2 (vertical directivity characteristics of the transmitting antenna) is calculated (step S21), the correction value E of the transmitting antenna height is calculated with reference to the electric field intensity chart file (step S22), and the electric field intensity chart file is referred to. An attenuation value C 'is calculated (step S23). Here, the attenuation value C ′ is set to 0 when the frequency is 300 MHz or less with reference to the clutter coefficient (building density) Γ and the elevation angle φ (rad).
The calculation is performed for a case where the reception point is not located in an urban area and a case where the receiving point is located in an urban area for frequencies exceeding 00 MHz. The clutter coefficient Γ is a percentage (%) of the horizontal cross-sectional area of the building structure within the 1 km square from the average height of 1 km square to the 1 km square at the height of 10 m from the receiving point.
And an urban area means a case where の = 1 (%) or more.
The elevation angle φ is an elevation angle at which the radiation center of the transmitting antenna is viewed from the receiving point (when there are n peaks related to mountain diffraction, the peak is the n-th peak). Then, after calculating the mountainous diffraction loss S _n by the processing E (step S24), and calculates the electric field intensity by the following equation (1) (step S2
5).

[0030]

## EQU1 ## 20 log (222√P / d) + D1 + D2 + A ₁
+ A _{n + 1} + S ₁ + S ₂ +... + S _n + C ′ + E where n = mountain diffraction number, P = effective radiation power (ER
P), in the calculation of mountainous diffraction losses S _n of d = reception distance above processing E, first, as shown in FIG. 15, calculates the propagation loss A ₁ to the first mountain with reference to electric field intensity nomogram file (Step S26). Here, if the reflected wave is not blocked between the transmission point and the first mountain, the propagation loss is set to A ₁ = 0. If the reflected wave is blocked, h1 is changed from the sea level at the transmitting antenna position to the radio wave reflection point. Electric field strength from a value obtained by subtracting the sea level altitude, h2 is a value obtained by subtracting the sea level altitude of the radio wave reflection point from the sea level altitude at the top of the first mountain, and d is a distance between the transmitting point and the summit of the first mountain. with reference to the drawings files, frequency 300MHz below to calculate the propagation loss a ₁ when exceeding 300MHz.

Next, the propagation loss _{An + 1} to the n-th peak is calculated (step S27). Here, if the reflected wave is blocked between the n-th mountain and the receiving point, the propagation loss A
_{Assuming that n + 1} = 0, h1 is a value obtained by subtracting the altitude of the radio wave reflection point from the top of the n-th mountain, and h2 is a value obtained by subtracting the altitude of the radio wave reflection point from the altitude of the receiving antenna. The propagation loss A _{n + 1} when the frequency is 300 MHz or less and exceeds 300 MHz is calculated by referring to the electric field intensity chart file from the parameter that sets the value, d, as the distance between the top of the n-th mountain and the receiving point.

Then, the mountain diffraction number n is read (step S28), and the mountain diffraction loss _Sn is calculated (step S28).
29). Here, d1 is the distance to the first mountain, H1
Is the value obtained by subtracting the altitude at the intersection of the straight line connecting the transmission point and the summit of the second mountain from the vertical line passing through the summit of the first mountain from the altitude of the first mountain, and di is the (i-1) th And the distance from the vertical line passing through the top of the i-th mountain to the height of the i-th mountain, where Hi is the distance from the i-th mountain to the height of the i-th mountain. Value subtracted from high,
Hn + 1 is the sea level at the receiving point, Di = Ｄ (d1 + d2 + ...
... + di) di + 1} / (d1 + d2 + ...... + di + 1) refers to the electric field intensity chart file from the parameter to a frequency of 300MHz or less, to calculate the mountain diffraction loss S _n when exceeding 300MHz. FIG. 16 shows a corresponding example of the propagation loss, the diffraction loss, and the sea level when there is a mountain related to mountain diffraction between the transmitting and receiving points.

The process B is performed in the same manner as the process A in step S
After executing the processes 21 to 23, the electric field strength is calculated by the following [Equation 2].

[0034]

20 log (222√P / d) + D1 + D2 + C ′ + E Here, P = effective radiated power (ERP), d = transmission / reception distance In the process C, the processes in steps S21 to S23 are executed in the same manner as the process A. Then, h1 is a value obtained by subtracting the sea level at the radio wave reflection point from the sea level at the transmitting antenna position, h2 is a value obtained by subtracting the sea level height at the radio wave reflection point from the sea level at the calculation point, and d is the electric field from the parameter of the transmission / reception distance. Refer to the strength chart file,
The propagation loss A ₀ when the frequency is 300 MHz or less and exceeds 300 MHz is calculated, and the electric field strength is calculated by the following [Equation 3].

[0035]

## EQU3 ## 20 log (222√P / d) + D1 + D2 + A ₀
+ C ′ + E Here, P = effective radiated power (ERP), d = transmission / reception distance In the process D, after performing the processes of steps S21 to S23 in the same manner as the process A, h1 is the altitude of the transmitting antenna position above sea level,
Referring to the electric field intensity chart file from the parameters where h2 is the altitude of the calculation point above sea level and d is the transmission / reception distance, the frequency is 300
MHz or less, the propagation loss when exceeding 300 MHz A ₀₀
Is calculated, and the electric field strength is calculated by the following [Equation 4].

[0036]

[Number 4] 20log (222√P / d) + D1 + D2 + A 00
+ C ′ + E Here, P = effective radiated power (ERP), d = transmission / reception distance FIG. 17 is a diagram for explaining a process of calculating the maximum electric field strength.
FIG. 18 is a diagram for explaining the process of interference calculation, and FIG. 19 is a diagram showing an example of a display screen of the same / adjacent broadcast station list.
As shown in FIG. 17, the maximum electric field strength calculation process reads the electric field strength calculation result file of the target broadcasting station (step S31) and reads the number of meshes in the Y direction of the calculation range from the calculation condition setting file, X The number of meshes in the direction is read (steps S32 and S33). Then, the electric field strengths of the target broadcasting stations are compared, the maximum value is written to a file, and the maximum electric field strength calculation result file and the maximum electric field strength additional information file are stored (step S34).

The processing of the interference calculation is performed by displaying the broadcasting station on the screen with reference to the broadcasting station specification file as shown in FIG. 18 and selecting the broadcasting station (desired station) to be subjected to the interference from the screen. Step S41) Search for an adjacent channel (interfering station) that is the same as the selected desired station (step S41).
42). Then, by displaying the searched interfering station on the screen as shown in FIG. 19, the interfering station is selected from the screen (step S43). Next, the number of meshes in the Y direction and the number of meshes in the X direction in the calculation range are read with reference to the electric field strength calculation result file service area threshold file and the interference ratio data file (steps S44 and S45). It is determined whether or not D / U result <interference / interference ratio for meshes satisfying desired station value ≧ threshold (step S47). And D /
If U result <interference / interference ratio, there is interference (step S4)
8) If the D / U result is not less than the interference ratio, there is no interference (step S49), and the result is written to a file and saved in the interference result file, the interference D / U file, and the additional interference information file (step S50). .

FIG. 20 is a diagram showing a configuration example of a calculation result output control circuit, and FIG. 21 is a diagram showing an example of a calculation result output diagram.
For example, field strength data from a field strength calculation result file as analysis data a, background map data from a background map data file as map data c, and statistical data b
When the household distribution data is read from the statistical data file and the electric field strength mesh diagram is output on the background map and the household distribution is also output, the priority processing circuit 21 gives priority to the analysis data a over the statistical data b. ,
Each data is controlled based on the control data 22 of the color set setting file, and is superimposed on the background map by the superimposition circuit 23. By performing such output, as shown in FIG. 21, it is possible to visually see where and how many households are out of the service area of the electric field strength mesh diagram, and to evaluate how many households can be covered. Can be.

Thus, from the statistical data of each mesh,
For example, by accumulating the number of mesh households entering a service area with an electric field strength of up to 50 dB, the number of mesh households entering a service area of up to 60 dB, and specifying a range, the ratio to the total number of households in the range is determined. , The coverage can be determined. Maximum electric field strength calculation result,
The same applies to the interference calculation result.

It should be noted that the present invention is not limited to the above embodiment, and various modifications are possible. For example, in the above embodiment, the angle and gain are set for each of the horizontal and vertical directions as the transmission antenna directional characteristics, but the contents are discrete angles and gain for each of the horizontal and vertical directions by numerical values. It is difficult to grasp the characteristics. Therefore, a means for drawing a three-dimensional directional characteristic curve based on the set value is prepared,
The directional characteristics may be displayed as a three-dimensional curve, or may be displayed as a two-dimensional curve with a cross section at an arbitrary horizontal or vertical angle. In the calculation of the electric field strength, circumferential division and radial calculation division are performed to calculate the radiation direction, and interpolation calculation is performed based on the calculated values near three points of the mesh to be obtained. Alternatively, the calculation of each mesh may be performed directly.

[0041]

As is apparent from the above description, according to the present invention, the electric field intensity calculating means for obtaining the electric field intensity in each mesh based on the analysis conditions input by the input means and the specifications of the broadcasting station, Means for calculating the maximum electric field strength in each mesh based on the electric field strength calculated by the means, and interference calculating means for obtaining the presence or absence of interference in each mesh based on the electric field strength calculated by the intensity calculating means. , The maximum electric field strength and the presence or absence of interference are stored as analysis data, and a map and analysis result are output based on the map data and the analysis data. , And can be output visually using an interference diagram or the like. Moreover, by selecting a combination of broadcasting stations and outputting a maximum electric field intensity map, an interference diagram, and the like, it is possible to provide various information necessary for the location planning of the transmission / relay base of the television wave. Further, by outputting the data together with the statistical data such as the population and the number of households, it is possible to easily grasp the coverage status of each area.

[Brief description of the drawings]

FIG. 1 is a diagram showing an embodiment of a broadcast wave propagation analysis system according to the present invention.

FIG. 2 is a diagram illustrating a data configuration example of a map data file.

FIG. 3 is a diagram illustrating a configuration example of map management data.

FIG. 4 is a diagram illustrating an example of a data configuration of a broadcast station specification file.

FIG. 5 is a diagram illustrating a data configuration example of a color set setting file.

FIG. 6 is a diagram illustrating a data configuration example of an electric field strength calculation result file.

FIG. 7 is a diagram illustrating a data configuration example of a maximum electric field strength calculation result file.

FIG. 8 is a diagram illustrating an example of a data configuration of an interference calculation result file.

FIG. 9 is a diagram for explaining a flow of an overall analysis process of the broadcast radio wave propagation analysis system and input / output of a file in each process.

FIG. 10 is a diagram for explaining the concept of electric field strength calculation.

FIG. 11 is a diagram illustrating a process of calculating an electric field intensity.

FIG. 12 is a diagram for explaining processing of electric field strength calculation.

FIG. 13 is a diagram for explaining an interpolation process for developing a field strength calculation result into a mesh.

FIG. 14 is a diagram for explaining processing of a subroutine.

FIG. 15 is a diagram illustrating the processing of a subroutine.

FIG. 16 is a diagram showing an example of a case where there is a mountain related to mountain diffraction between transmission and reception points.

FIG. 17 is a diagram illustrating a process of calculating a maximum electric field intensity.

FIG. 18 is a diagram illustrating a process of interference calculation.

FIG. 19 is a diagram showing an example of a display screen of the same / adjacent broadcasting station list.

FIG. 20 is a diagram illustrating a configuration example of a calculation result output control circuit.

FIG. 21 is a diagram illustrating an example of a calculation result output diagram.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 output device 2 input device 3 storage device 4 arithmetic processing device 11 map data file 12 setting data file 13 analysis data file 14 input / output control unit 15 electric field strength Calculation unit, 16: Maximum electric field strength calculation unit, 17: Radio interference calculation unit, 18: Calculation result output control unit

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Yoshito Bando 1-3-2 Shibaura, Minato-ku, Tokyo Shimizu Corporation (72) Inventor Hideo Kobayashi 1-3-2 Shibaura, Minato-ku, Tokyo Shimizu Construction Co., Ltd. (72) Inventor Chiba Gen 2-3-2 Shibaura, Minato-ku, Tokyo Shimizu Corporation F-term (reference) 5K042 BA08 BA11 CA02 CA12 CA23 DA01 DA19 EA02 EA14 FA11 FA15 GA01 GA06 GA11 GA17 HA02 HA14 HA16 5K061 AA00 AA11 BB01 CC01 DD08 JJ06 JJ07

Claims (15)

[Claims] 1. A broadcast wave propagation analysis system for inputting broadcast station specifications, calculating an electric field intensity from the broadcast station in each mesh divided into meshes for each region, and analyzing a broadcast wave propagation state of each broadcast station. Map data storage means for storing map data mesh-divided for each region; input means for selecting analysis conditions, broadcast station specifications, analysis conditions and broadcast station specifications, and inputting instructions; Means for calculating the electric field strength in each of the meshes based on the analysis conditions input by the means and the broadcasting station specifications; and a maximum electric field for obtaining the maximum electric field strength in each of the meshes based on the electric field strength calculated by the strength calculating means. Strength calculating means, interference calculating means for determining the presence or absence of interference in each of the meshes based on the electric field strength calculated by the strength calculating means, the electric field strength, Analysis data storage means for storing the maximum electric field strength and the presence / absence of interference as analysis data, and outputting a map and an analysis result based on the map data stored in the map data storage means and the analysis data stored in the analysis data storage means Output means for performing the operation, the broadcasting station input by the input means, and the respective calculation means based on the analysis conditions to control the calculation means, store the analysis data in the analysis data storage means, and map data stored in the map data storage means. And a control means for controlling the output of the output means based on the analysis data stored in the analysis data storage means. 2. The electric field strength calculating means calculates the electric field strength in the radiation direction based on the division pitch by performing circumferential division and radial calculation division, and calculates the electric field strength in three radiation points in the vicinity of each mesh. 2. The broadcast radio wave propagation analysis system according to claim 1, wherein the intensity of each of the meshes is calculated based on interpolation. 3. The calculation of the electric field strength in the radiation direction is performed in consideration of whether there is a view from a broadcasting station, whether there is a mountain related to mountain diffraction between transmitting and receiving points, and whether a reflected wave is blocked by the mountain. 3. The broadcast radio wave propagation analysis system according to claim 2, wherein 4. The apparatus according to claim 1, wherein said maximum electric field strength calculating means performs the electric strength calculation by comparing the electric field strengths of the selected broadcasting stations to obtain a maximum value.
Broadcast radio wave propagation analysis system as described. 5. The interference calculation means searches for a disturbing station by setting a broadcasting station that is subject to interference as a desired station and a broadcasting station on the same channel as the desired station and an adjacent channel as a disturbing station.
2. The broadcast radio wave propagation analysis system according to claim 1, wherein interference calculation is performed for a selected jamming station among the searched jamming stations. 6. The method according to claim 5, wherein the presence or absence of the interference is determined based on whether or not a difference between the electric field strength of the desired station and the electric field strength of the interfering station is larger than a predetermined interference ratio. Broadcast radio wave propagation analysis system as described. 7. The broadcast wave propagation analysis system according to claim 1, wherein the map data includes background map data, contour map data, and elevation mesh data. 8. The method according to claim 1, wherein the map data includes statistical data for each of the meshes, and the control unit superimposes the statistical data and the analysis data on a map and outputs the superimposed statistical data to the output unit. Item 2. The broadcast wave propagation analysis system according to Item 1. 9. The broadcast radio wave propagation analysis system according to claim 8, wherein said statistical data is a population or the number of households. 10. The broadcast radio wave propagation analysis system according to claim 8, wherein said control means separates said statistical data and analysis data and outputs them to said output means in different output modes. 11. The broadcast radio wave propagation analysis system according to claim 8, wherein said control means sets the output priority of the analysis data higher than the statistical data, and outputs the analysis data from the output means while superimposing the analysis data on a map. 12. The apparatus according to claim 8, further comprising means for totalizing the statistical data corresponding to the analysis data of each of the meshes, and calculating a ratio of the statistical data to a total value of the statistical data in a specified range. Broadcast radio wave propagation analysis system as described. 13. As the analysis conditions, the transmission antenna directional characteristics are set by angle and gain for each of horizontal and vertical, and the transmission antenna directional characteristics by angle and gain for each of the set horizontal and vertical are drawn three-dimensionally. 2. The broadcast radio wave propagation analysis system according to claim 1, further comprising means. 14. A broadcast station position on a map, transmission antenna directivity characteristics, and other broadcast station specifications are set, an electric field strength in each mesh divided into meshes for each area is calculated, and a calculation result is output on a mesh map. A broadcast wave propagation analysis system that analyzes the state of propagation of broadcast waves. 15. Setting the number of circumferential divisions centered on a broadcasting station, the number of radial calculation divisions of calculation points from the broadcasting station to the calculation radius, calculating the electric field strength in the radiation direction based on the division pitch, and 13. The broadcast radio wave propagation analysis system according to claim 12, wherein the intensity calculation of each mesh is performed by linearly interpolating based on the calculated values in the radiation direction of three points in the vicinity of.