JP5940938B2 - Home wiring estimation device and home wiring estimation method - Google Patents

Description

  The present invention relates to a home wiring estimation device and a home wiring estimation method for estimating the configuration of a home wiring.

  In recent years, services that allow users to view terrestrial digital broadcasts, BS digital broadcasts, and the like without requiring the installation of antennas have become widespread (see Non-Patent Document 1). When receiving such a service, it is usual to conduct a home hearing work. In home concert construction, the antenna is removed, and the wiring is changed to a configuration in which the output of the line terminator (GV-ONU) is connected to the input of the distributor. If the home concerting work is implemented, it will be possible to watch TV in each room.

NTT, FLET'S TV, [Search on July 26, 2012], Internet <URL: http://www.isdn-info.co.jp/ftv/service.html>

  However, it is difficult to find a distributor because the number of distributors and the installation method differ depending on each house and no wiring diagram or the like remains. Therefore, it was not possible to quickly determine the necessity of construction and the construction scale. The construction worker searches for a distributor based on his / her own know-how. However, there are cases where the distributor cannot be found for a long time or the distributor cannot be found and the construction cannot be performed.

  An object of the present invention is to provide a home wiring estimation device and a home wiring estimation method capable of estimating the configuration of a home wiring in view of the conventional technology described above.

In order to achieve the above object, the invention according to the first aspect is a home wiring estimation device that estimates the configuration of a home wiring, and is calculated by a calculation unit that calculates a loss in a home distributor and the calculation unit. A map creation unit that estimates a configuration of the home wiring based on the loss and creates a wiring map indicating the estimated home wiring configuration, and the calculation unit includes an antenna signal attenuation characteristic for each terminal of the distributor And the map creation unit estimates the number of vertical stages of the distributor based on the attenuation characteristic of the antenna signal .
The invention according to the second aspect is a home wiring estimation device that estimates the configuration of a home wiring, and includes a calculation unit that calculates a loss in a home distributor, and a home wiring based on the loss calculated by the calculation unit And a map creation unit that creates a wiring map indicating the estimated home wiring configuration, the calculation unit calculates the attenuation characteristics of the inter-terminal signal between the terminals of the distributor, The gist is that the map creating unit estimates the number of horizontal stages of the distributor based on the attenuation characteristic of the inter-terminal signal.
The gist of the invention according to a third aspect is that the calculation unit calculates the attenuation characteristics of the antenna signal in a plurality of frequency bands.
The gist of the invention according to a fourth aspect is that the calculation unit calculates the attenuation characteristics of the inter-terminal signal in a plurality of frequency bands.
In the invention according to the fifth aspect, the calculation unit calculates a transmission / reception time of an IP signal or an electric signal between the terminals of the distributor, and the map creation unit calculates the transmission / reception time of the distributor based on the transmission / reception time. The gist is to estimate the distance between terminals.
The invention according to the sixth aspect is a home wiring estimation method for estimating the configuration of a home wiring, a calculation step for calculating a loss in a home distributor, and a home wiring based on the loss calculated in the calculation step And a map creation step of creating a wiring map indicating the estimated home wiring configuration, and calculating the attenuation characteristics of the antenna signal for each terminal of the distributor in the calculation step, and creating the map The gist is to estimate the number of vertical stages of the distributor based on the attenuation characteristic of the antenna signal in the step.
The invention according to the seventh aspect is a home wiring estimation method for estimating the configuration of a home wiring, a calculation step for calculating a loss in a home distributor, and a home wiring based on the loss calculated in the calculation step And a map creating step for creating a wiring map indicating the estimated home wiring configuration, and calculating the attenuation characteristics of the inter-terminal signal between the terminals of the distributor in the calculating step, The gist of the present invention is to estimate the number of horizontal stages of the distributor based on the attenuation characteristic of the inter-terminal signal in the map creating step.

  ADVANTAGE OF THE INVENTION According to this invention, it is possible to provide the home wiring estimation apparatus and home wiring estimation method which can estimate the structure of a home wiring.

It is explanatory drawing of the home concert construction in embodiment of this invention, Comprising: (a) Before home concert construction implementation, (b) After implementation of home concert construction. It is a block diagram which shows the structural example of the household wiring in embodiment of this invention. It is explanatory drawing of function (1)-(4) in embodiment of this invention. It is a block diagram of the in-home wiring estimation system in the embodiment of the present invention. It is a block diagram of the household wiring estimation apparatus in embodiment of this invention. It is a block diagram of the database memorize | stored in the memory | storage part in embodiment of this invention. It is explanatory drawing of the measurement point in embodiment of this invention. It is a sequence diagram of the household wiring estimation apparatus in the embodiment of the present invention. It is a flowchart which shows the function (1) in embodiment of this invention in detail. It is a block diagram which shows the basic structural example in embodiment of this invention, Comprising: (a) Pattern a, (b) Pattern b, (c) Pattern c, (d) Pattern d. It is a flowchart which shows the function (2) in embodiment of this invention in detail. It is a flowchart which shows the function (3) in embodiment of this invention in detail. It is explanatory drawing of the specific example of the function (3) in embodiment of this invention, Comprising: (a) Connection example 1, (b) Connection example 2, (c) Relationship between delay theoretical value and distance, (d) Calculation result. It is a figure which shows the specific example 1 of the measurement result in embodiment of this invention. It is a figure which shows the specific example 1 of the wiring map in embodiment of this invention. It is a figure which shows the specific example 2 of the measurement result in embodiment of this invention. It is a figure which shows the specific example 2 of the wiring map in embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments exemplify an in-home wiring estimation device for embodying the technical idea of the present invention, and the configuration of the device and the data structure are limited to the following embodiments. It is not something.

(Home Hearing Work)
Fig.1 (a) has shown the state before implementing a home concert construction. As shown in this figure, before the home hearing work, the antenna 10 is connected to the input terminal 20A of the distributor 20, and the output terminals 20B, 20C, 20D of the distributor 20 are connected to the wall surfaces of the rooms 30, 40, 50. The television receivers 32, 42, and 52 are connected to the television receivers 31, 41, and 51. The antenna 10 inputs the received broadcast signal (hereinafter referred to as “antenna signal”) to the input terminal 20 </ b> A of the distributor 20. The distributor 20 distributes the antenna signal 21 and outputs it from the output terminals 20B, 20C, and 20D. The antenna signals output from the output terminals 20B, 20C, and 20D of the distributor 20 are input to the television receivers 32, 42, and 52, respectively. As a result, the television receivers 32, 42, and 52 can view images based on the antenna signals.

  FIG.1 (b) has shown the state after implementing home concert construction. In recent years, broadcast signals (net signals) are also transmitted from a communication network. In order to view the video by such a net signal on each of the television receivers 32, 42, 52, it is necessary to remove the antenna 10 from the distributor 20 and attach a line terminator 34 such as a GV-ONU to the distributor 20. .

(Outline of the present invention)
FIG. 2 schematically shows a configuration example of the home wiring. As shown in this figure, the two distributors 24 are connected to the antenna 10, and the two distributors 23 and 25 are connected to the two distributors 24. Further, the two distributors 22 are connected to the two distributors 23, and the two distributors 21 are connected to the two distributors 22. Further, a 2 distributor 26 is connected to the 2 distributor 25, and a 2 distributor 27 is connected to the 2 distributor 26. In many cases, these two distributors 21 to 27 (collectively referred to as “distributor 20”) are installed in a place where it is difficult to work such as an attic, so it is difficult to find the distributor 20.

  Therefore, in the present invention, the following method is adopted. That is, as shown in FIG. 3, the home wiring estimation device 60 is connected to the output terminals A to H of the distributor 20. The home wiring estimation device 60 calculates a loss in the home distributor, estimates a home wiring configuration based on the calculated loss, and creates a wiring map indicating the estimated home wiring configuration.

  The main functions of the home wiring estimation device 60 can be broadly divided into the following functions (1) to (4). The function (1) is a function for estimating the number of stages in the vertical direction (vertical direction) of the distributor 20. The function (2) is a function for estimating the number of stages in the horizontal direction (horizontal direction) of the distributor 20 and the type (number of distributions) of the distributor 20. The function (3) is a function for estimating the distance between the terminals of the distributor 20. The function (4) is a function for creating a wiring map indicating the configuration of the home wiring based on the results of the functions (1) to (3).

(System configuration example)
FIG. 4 is a configuration diagram of the home wiring estimation system. As shown in FIG. 4, this system includes an antenna 10, a distributor 20, connection terminals (1) to X, and a home wiring estimation device 60. Of the output terminals A to H of the distributor 20, the output terminals connected to the home wiring estimation device 60 are referred to as “connection terminals (1) to X”. The in-home wiring estimation device 60 can be connected to the output terminals A to H of the distributor 20 by inserting the coaxial line drawn from the in-home wiring estimation device 60 into the TV terminal on the wall surface of each room. When the function (1) is realized, one coaxial line drawn from the home wiring estimation device 60 is connected to one of the connection terminals (1) to X. When realizing the functions (2) and (3), the two coaxial wires drawn from the in-home wiring estimation device 60 are connected to two of the connection terminals (1) to X.

(Configuration example of home wiring estimation device)
FIG. 5 is a configuration diagram of the home wiring estimation apparatus 60. As shown in this figure, the in-home wiring estimation device 60 includes a transmission unit 61, a reception unit 62, a notification unit 63, a calculation unit 64, a storage unit 65, a map creation unit 66, and a map display unit 67. It has. The transmission unit 61 transmits signals and packets to the connection terminals (1) to X via the coaxial line. The receiving unit 62 receives signals and packets from the connection terminals (1) to X via a coaxial line. The notification unit 63 notifies the calculation unit 64 of the reception result of the reception unit 62. The calculation unit 64 calculates a loss or the like in the home distributor 20. The storage unit 65 stores the calculation result of the calculation unit 64. A configuration example of the database stored in the storage unit 65 is shown in FIG. As shown in FIG. 6, the storage unit 65 stores the calculation results of the functions (1) to (4). The map creation unit 66 refers to the storage unit 65 to estimate the configuration of the home wiring based on the calculation result of the calculation unit 64 and creates a wiring map indicating the estimated home wiring configuration. The map display unit 67 displays the wiring map created by the map creation unit 66.

  Here, when the function (1) is realized, the calculation unit 64 calculates the attenuation characteristic of the antenna signal for each terminal of the distributor 20, and the map creation unit 66 calculates the distributor 20 based on the attenuation characteristic of the antenna signal. Is estimated. When realizing the function (2), the calculation unit 64 calculates the attenuation characteristic of the inter-terminal signal between the terminals of the distributor 20, and the map creation unit 66 distributes based on the attenuation characteristic of the inter-terminal signal. The number of horizontal stages of the distributor 20 and the type of distributor 20 are estimated. Furthermore, when the function (3) is realized, the calculation unit 64 calculates the transmission / reception time of the IP signal or the electric signal between the terminals of the distributor 20, and the map creation unit 66 calculates the distributor 20 based on the transmission / reception time. Estimate the distance between the terminals.

(Frequency band)
The calculation unit 64 may calculate the attenuation characteristics of the antenna signal or the signal between terminals in a plurality of frequency bands. If a plurality of frequency bands are used, the attenuation characteristics can be calculated for each frequency band. Therefore, the attenuation characteristics can be calculated more accurately than when a single frequency band is used.

  Specifically, as shown in FIG. 7, antenna signals and inter-terminal signals are measured at measurement points I to Y that are not used in terrestrial digital broadcasting, BS digital broadcasting, or the like. Which of the measurement points I to Y is used is not particularly limited, but the attenuation characteristic can be calculated more accurately in a lower frequency band (for example, 1 to 90 MHz).

(sequence)
FIG. 8 is a sequence diagram of the home wiring estimation apparatus 60. First, antenna signals are transmitted and received at the connection terminals (1) to X, respectively, and the loss is calculated (step S1). This step S1 corresponds to the function (1), and it is understood how many stages the distributor 20 has in the vertical direction. Next, inter-terminal signals are transmitted and received between the connection terminals (1) to X, and the loss is calculated (step S2). This step S2 corresponds to the function (2), and it can be understood how many stages the distributor 20 has in the horizontal direction. Next, the number of vertical and horizontal stages of the distributor 20 is estimated based on the loss results of steps S1 and S2 (step S3). Next, an IP signal or an electrical signal such as Ping is transmitted / received between the connection terminals (1) to X, and the transmission / reception time is calculated (step S4). This step S4 corresponds to function (3), and the cable distance between the terminals can be known. Finally, a wiring map is created based on the results of functions (1), (2), and (3) (step S5). It is possible to improve the accuracy of the wiring map by creating a database of actual results.

(Details of function (1))
FIG. 9 is a flowchart showing the function (1) in detail. As shown in this figure, in the function (1), it is calculated whether there are N types of antenna signal strengths for each of the connection terminals (1) to X (step S11). Specifically, the coaxial line drawn from the home wiring estimation device 60 is connected to the output terminal A of the distributor 20 and the strength of the antenna signal received through the output terminal A is calculated. Thereafter, the strength of the antenna signal is calculated by the same method while sequentially changing the insertion position of the coaxial line drawn from the in-home wiring estimation device 60 as the output terminals B, C,..., G, H. As a result, if it is found that there are N types of antenna signal strengths, it is estimated that the number of vertical stages is N (step S12).

  FIG. 10 is a diagram showing a basic configuration example according to the embodiment of the present invention. The number of stages in the vertical direction can be estimated by “number of antenna signal strength types + 0 or 1”. Either 0 or 1 may be added, but 0 is added in the present embodiment. The distributor 20 having the largest distribution number is at the apex, and there are distributors 20 having a distribution number less than that at the apex. Basically, if the distributor 20 is too complicated, there are many losses and it is difficult to view the television. Therefore, the following patterns a to d are usually set.

  In the pattern a, as shown in FIG. 10A, the 6 distributor 20 is connected to the antenna 10. In this case, there is only one kind of antenna signal intensity at the output terminals A to F. The output terminals A to F having the greatest strength are closest to the distributor 20 connected to the antenna 10. The number of stages in the vertical direction is one.

  In the pattern b, as shown in FIG. 10B, the two distributors 20 are connected to the antenna 10, and the two distributors 20 are connected one by one under each output terminal of the two distributors 20. In this case, there is only one kind of antenna signal intensity at the output terminals A to D. The output terminals A to D having the greatest strength are closest to the distributor 20 connected to the antenna 10. The number of stages in the vertical direction is one.

  In the pattern c, as shown in FIG. 10C, the four distributors 20 are connected to the antenna 10, and one two distributor 20 is connected to one output terminal of the four distributors 20. In this case, the strength of the antenna signals at the output terminals C to E is stronger than the strength of the antenna signals at the output terminals A and B. There are two types of antenna signal strength. The output terminals C to E having the greatest strength are closest to the distributor 20 connected to the antenna 10. The number of stages in the vertical direction is two.

  In the pattern d, as shown in FIG. 10 (d), two distributors 20 are connected to the antenna 10, and two distributors 20 are connected in series under each output terminal of the two distributors 20. Yes. In this case, there are three types of antenna signal strengths: “A, B, G, H”, “C, F”, and “D, E”. The output terminals D and E having the greatest strength are closest to the distributor 20 connected to the antenna 10. The number of stages in the vertical direction is three.

(Details of function (2))
FIG. 11 is a flowchart showing the function (2) in detail. As shown in this figure, in the function (2), it is calculated whether there are M kinds of signal strengths between the terminals (1) to X (step S21). Specifically, the coaxial line drawn from the in-home wiring estimation device 60 is connected to the output terminals A and B of the distributor 20, and the strength of the signal between terminals transmitted and received between the output terminals A to B is calculated. After that, while sequentially changing the insertion position of the coaxial line drawn from the home wiring estimation device 60, such as output terminals A and B, A and C,. Calculate strength. As a result, when it is found that there are M kinds of signal strengths between terminals, the number of horizontal stages is estimated to be M (step S22).

  The method for estimating the number of steps in the horizontal direction is the same as the method for estimating the number of steps in the vertical direction. That is, the number of horizontal stages can be estimated by “the number of types of signal strength between terminals + 0 or 1”. Either 0 or 1 may be added, but 0 is added in the present embodiment.

(Details of function (3))
FIG. 12 is a flowchart showing the function (3) in detail. As shown in this figure, in the function (3), the transmission / reception time of the IP signal or the electric signal is calculated between the connection terminals (1) to X (step S31). Specifically, the coaxial line drawn from the home wiring estimation device 60 is connected to the output terminals A and B of the distributor 20, and IP communication such as ping is performed between the output terminals A and B or electrical signals are transmitted and received. And calculate the transmission / reception time. After that, the transmission / reception time is calculated in the same manner while sequentially changing the insertion position of the coaxial line drawn from the home wiring estimation device 60, such as output terminals A and B, A and C,. To do. Thereby, the distance between each terminal is estimated based on transmission / reception time (step S32).

  FIG. 13 is an explanatory diagram of a specific example of the function (3). FIG. 13A shows a connection example 1 in which communication is performed by an IP communication device through a coaxial cable of S-5C-FB10m. FIG.13 (b) has shown the example 2 of a connection communicated by an IP communication apparatus through the coaxial cable of S-5C-FB20m, and 2 divider | distributor. FIG. 13C shows the relationship between the theoretical delay value per 10 m (sec) and the distance (m). FIG. 13D shows the calculation results of the delay values in connection example 1 and connection example 2. Specifically, the upper and lower 50 Mbps UDP traffic was applied for 1 minute in N2X, the maximum delay value and the minimum delay value were measured twice, and the average delay value was calculated. Based on such an average delay value, the distance between the terminals can be estimated.

(Specific example 1)
FIG. 14 is a diagram showing a specific example 1 of a measurement result in the embodiment of the present invention. Here, a case where measurement is performed with the output terminal A as the center in the configuration shown in FIG. 3 will be described.

  The measurement result of function (1) is that output terminals A and B are -60 dB, output terminal C is -55 dB, output terminals D and E are -50 dB, output terminal F is -55 dB, and output terminals G and H are -60 dB. there were. Focusing on the intensity of these signals, the output terminals D and E are the first stage, the output terminals C and F are the second stage, the output terminals A, B, G, and H are the third stage. The number of stages can be estimated as three.

  The measurement result of function (2) shows that the output terminal B is −30 dB, the output terminal C is −35 dB, the output terminal D is −40 dB, the output terminal E is −50 dB, the output terminal F is −55 dB, and the output terminals G and H are It was −60 dB. Focusing on the intensity of these signals, output terminal B is the first stage, output terminal C is the second stage, output terminal D is the third stage, output terminal E is the fourth stage, output terminal F is the fifth stage, output terminal G and H become the sixth stage, and the number of stages in the horizontal direction of the distributor 20 can be estimated to be six.

  The measurement result of function (3) is as follows: output terminal B is 0.1 m, output terminal C is 2 m, output terminal D is 4 m, output terminal E is 8 m, output terminal F is 12 m, output terminal G is 15 m, output terminal H Was 15 m. Since the measurement result (0.1 m) of the output terminal B is not more than a predetermined threshold value, it is estimated that the output terminals A and B are output terminals of the same distributor.

  FIG. 15 is a diagram showing a specific example 1 of the wiring map according to the embodiment of the present invention. This wiring map is created based on the measurement result of FIG.

  First, based on the measurement result of function (1), the output terminals A to H are arranged in three stages in the vertical direction. Specifically, the output terminals D and E are arranged in the first stage, the output terminals C and F are arranged in the second stage, and the output terminals A, B, G, and H are arranged in the third stage.

  Next, based on the measurement result of function (2), the output terminals A to H are arranged in six stages in the horizontal direction. Specifically, output terminals A and B are the first stage, output terminal C is the second stage, output terminal D is the third stage, output terminal E is the fourth stage, output terminal F is the fifth stage, output terminal G And H are arranged in the sixth row.

  Next, information indicating the distance between the terminals is arranged based on the measurement result of the function (3). Specifically, 2 m between the output terminals A to C, 4 m between the output terminals A to D, 8 m between the output terminals A to E, 12 m between the output terminals A to F, and between the output terminals A to G and H. Information indicating 15 m is arranged.

  Finally, the wiring map created in this way is displayed on the map display unit 67.

(Specific example 2)
FIG. 16 is a diagram showing a specific example 2 of the measurement result in the embodiment of the present invention. Here, a case where measurement is performed with the output terminal D as the center in the configuration shown in FIG. 3 will be described.

  The measurement result of function (1) is that output terminals A and B are -60 dB, output terminal C is -55 dB, output terminals D and E are -50 dB, output terminal F is -55 dB, and output terminals G and H are -60 dB. there were. Focusing on the intensity of these signals, the output terminals D and E are the first stage, the output terminals C and F are the second stage, the output terminals A, B, G, and H are the third stage. The number of stages can be estimated as three.

  The measurement results of function (2) were 40 dB for output terminal A, 40 dB for output terminal B, 35 dB for output terminal C, 40 dB for output terminal E, 45 dB for output terminal F, and 50 dB for output terminals G and H. Focusing on the intensity of these signals, the output terminal C is the first stage, the output terminals A, B, and E are the second stage, the output terminal F is the third stage, and the output terminals G and H are the fourth stage. It can be estimated that the number of horizontal stages is four.

  The measurement result of function (3) is that the output terminal A is 6 m, the output terminal B is 6 m, the output terminal C is 4 m, the output terminal E is 8 m, the output terminal F is 12 m, the output terminal G is 15 m, and the output terminal H is 15 m. Met.

  FIG. 17 is a diagram showing a specific example 2 of the wiring map in the embodiment of the present invention. This wiring map is created based on the measurement result of FIG.

  First, based on the measurement result of function (1), the output terminals A to H are arranged in three stages in the vertical direction. Specifically, the output terminals D and E are arranged in the first stage, the output terminals C and F are arranged in the second stage, and the output terminals A, B, G, and H are arranged in the third stage.

  Next, based on the measurement result of function (2), the output terminals A to H are arranged in four stages in the horizontal direction. Specifically, the output terminal C is arranged at the first stage, the output terminals A, B and E are arranged at the second stage, the output terminal F is arranged at the third stage, and the output terminals G and H are arranged at the fourth stage. Here, although the antenna 10 is represented by “X”, whether or not the antenna 10 is arranged on the wiring map is not particularly limited.

  Next, information indicating the distance between the terminals is arranged based on the measurement result of the function (3). Specifically, the output terminals C to C are 4 m, the output terminals D to A and B are 6 m, the output terminals D to E are 8 m, the output terminals D to F are 12 m, and the output terminals D to G, H Information indicating that the interval is 15 m is arranged. The number of horizontal stages of the output terminals A, B, and E is all second, but the distance between the output terminals D to A and B is 6 m, and the distance between the output terminals D to E is 8 m. Therefore, the arrangement of the output terminals on the wiring map is adjusted so that the distance (8 m) between the output terminals D to E is larger than the distance (6 m) between the output terminals D to A and B.

  Finally, the wiring map created in this way is displayed on the map display unit 67.

  As described above, the home wiring estimation device 60 according to the embodiment of the present invention calculates the loss in the home distributor 20, estimates the home wiring configuration based on the calculated loss, and estimates the estimated home wiring configuration. Create a wiring map showing As a result, the configuration of the home wiring (number and type of distributors 20 and the like) can be ascertained prior to the construction, so that it is possible to quickly determine the necessity of construction and the construction scale.

  Specifically, the calculation unit 64 calculates the attenuation characteristic of the antenna signal for each terminal of the distributor 20, and the map creation unit 66 estimates the number of stages in the vertical direction of the distributor 20 based on the attenuation characteristic of the antenna signal. May be. Thereby, it is possible to estimate the number of vertical steps quickly by a simple method.

  The calculation unit 64 calculates the attenuation characteristic of the inter-terminal signal between the terminals of the distributor 20, and the map creation unit 66 estimates the number of horizontal stages of the distributor 20 based on the attenuation characteristic of the inter-terminal signal. May be. Thereby, it is possible to estimate the number of horizontal steps quickly by a simple method.

  The calculation unit 64 may calculate the attenuation characteristics of the antenna signal or the signal between terminals in a plurality of frequency bands. As a result, the attenuation characteristics can be calculated more accurately than when a single frequency band is used.

  The calculation unit 64 calculates the transmission / reception time of the IP signal or electrical signal between the terminals of the distributor 20, and the map creation unit 66 estimates the distance between the terminals of the distributor 20 based on the transmission / reception time. Also good. Thereby, since the distance between terminals can be reflected in a wiring map, it becomes possible to grasp | ascertain home environment more correctly.

  Here, the wiring map is displayed on the home wiring estimation device 60, but the wiring map may be displayed on another device connected to the home wiring estimation device 60 via a network. Of course, the wiring map can also be created with this other device. That is, the processing units 61 to 67 in FIG. 5 can be distributed to a plurality of devices.

  Further, it is possible to create a wiring map even when all of the functions (1) to (3) are not provided. For example, when the antenna 10 is an unsupported or difficult viewing area, the function (1) is not used and the wiring map may be created using only the functions (2) and (3). Of course, more accurate estimation is possible by using all of the functions (1) to (3).

  In addition, the present invention can be realized not only as an in-home wiring estimation device 60 but also as an in-home wiring estimation method using a characteristic processing unit provided in such an in-home wiring estimation device 60 as a step. It can also be realized as a program for causing a computer to execute steps. It goes without saying that such a program can be distributed via a recording medium such as a CD-ROM or a transmission medium such as the Internet.

60 ... In-home wiring estimation device 61 ... Transmission unit 62 ... Reception unit 63 ... Notification unit 64 ... Calculation unit 65 ... Storage unit 66 ... Map creation unit 67 ... Map display unit

Claims (7)

A home wiring estimation device for estimating the configuration of home wiring,
A calculation unit for calculating a loss in a distributor in the house;
A map creation unit for estimating a configuration of the home wiring based on the loss calculated by the calculation unit, and creating a wiring map indicating the estimated home wiring configuration ; and
The calculation unit calculates the attenuation characteristics of the antenna signal for each terminal of the distributor,
The map creation unit estimates the number of vertical stages of the distributor based on the attenuation characteristic of the antenna signal.
An in-home wiring estimation apparatus characterized by the above.   A home wiring estimation device for estimating the configuration of home wiring,
  A calculation unit for calculating a loss in a distributor in the house;
  A map creation unit for estimating a configuration of the home wiring based on the loss calculated by the calculation unit, and creating a wiring map indicating the estimated home wiring configuration;
  With
  The calculation unit calculates the attenuation characteristic of the signal between terminals for each terminal of the distributor,
  The map creation unit estimates the number of horizontal stages of the distributor based on the attenuation characteristic of the inter-terminal signal.
  An in-home wiring estimation apparatus characterized by the above.   The in-home wiring estimation apparatus according to claim 1, wherein the calculation unit calculates attenuation characteristics of the antenna signal in a plurality of frequency bands.   The in-home wiring estimation apparatus according to claim 2, wherein the calculation unit calculates attenuation characteristics of the signal between terminals in a plurality of frequency bands. The calculation unit calculates a transmission / reception time of an IP signal or an electric signal between terminals of the distributor,
5. The in-home wiring estimation apparatus according to claim 1, wherein the map creation unit estimates a distance between terminals of the distributor based on the transmission / reception time. A home wiring estimation method for estimating a home wiring configuration,
A calculation step for calculating the loss in the distributor in the house;
A map creating step for estimating a configuration of the home wiring based on the loss calculated in the calculation step, and creating a wiring map indicating the estimated home wiring configuration ; and
In the calculating step, the attenuation characteristic of the antenna signal is calculated for each terminal of the distributor,
In the map creating step, the number of vertical stages of the distributor is estimated based on the attenuation characteristic of the antenna signal.
An in-house wiring estimation method characterized by the above.   A home wiring estimation method for estimating a home wiring configuration,
  A calculation step for calculating the loss in the distributor in the house;
  A map creating step for estimating the configuration of the home wiring based on the loss calculated in the calculating step, and creating a wiring map indicating the estimated home wiring configuration;
  With
  In the calculating step, the attenuation characteristic of the inter-terminal signal is calculated for each terminal of the distributor,
  In the map creating step, the number of horizontal stages of the distributor is estimated based on the attenuation characteristic of the signal between the terminals.
  An in-house wiring estimation method characterized by the above.

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