JP2013055525A - Visible light communication system, visible light communication method, transmission device, transmission method, transmission program, reception device, reception method, and reception program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a visible light communication system that is able to multiplex signals while suppressing flicker of light.SOLUTION: A visible light communication system 200 generates a first signal that is a signal representing a first bit string, that is divided by each first symbol period into portions each representing a bit, and that has a first mark rate value which is a mark rate other than 50% relative to the first symbol period; generates a second signal that is a signal representing a second bit string, that is divided by each second symbol period into portions each representing a bit, the second symbol period being a value obtained by multiplying the first symbol period by an integer equal to 2 or more, and that has a second mark rate value which is a mark rate relative to the second symbol period; and in a state in which a symbol period is synchronized, generates exclusive OR of the first signal and the second signal as a multiplex signal, and generates an optical signal by emitting light when a signal value of the generated multiplex signal has is a true value, and not emitting light when the signal value is a false value.

Description

  The present invention relates to a visible light communication system for transmitting an optical signal from a transmission device to a reception device.

  A visible light communication system that transmits an optical signal from a transmission device to a reception device is known. As one of the multiplexed communication methods of this type of visible light communication system, the visible light communication system described in Patent Document 1 transmits a first bit string by transmitting an optical signal from a transmission device to a reception device, and The second bit string is multiplexed and transmitted from the transmitting apparatus to the receiving apparatus.

  Specifically, the transmission device generates a first signal that represents a first bit string and has a signal value of either a true value or a false value. The first signal is a signal in which each of the divided parts for each first symbol period is a false value when the bit is 0 and is a true value when the bit is 1.

  Further, the transmission device generates a second signal that represents the second bit string and has a signal value of either a true value or a false value. The second signal has a false value when each of the parts divided for each second symbol period that is larger than the first symbol period is a bit of 0, and a true value when the bit is 1. Is a signal.

  In addition, the transmission apparatus generates a multiplexed signal obtained by multiplexing the generated first signal and the generated second signal according to a time division multiplexing method. The transmitter generates light when the signal value of the generated multiplexed signal is a true value, and does not emit light when the signal value is a false value, thereby generating an optical signal.

  According to this, by transmitting the optical signal from the transmission device to the reception device, the first bit string and the second bit string can be multiplexed and transmitted from the transmission device to the reception device.

JP 2011-109185 A

  By the way, in the visible light communication system, there are cases where relatively many false values are continued in the multiplexed signal due to the continuation of 0 in the first bit string or the second bit string. As a result, there is a problem that the flicker of light due to the optical signal may be excessive. This problem also occurs when the optical communication system uses multiple signals having three or more signal values.

  As described above, the visible light communication system has a problem in that it is used in a place where it can be seen by human eyes due to excessive light flicker.

  For this reason, an object of the present invention is to provide a visible light communication system capable of multiplexing optical signals while solving the above-described problem that “light flickering due to optical signals may be excessive”. is there.

In order to achieve such an object, a visible light communication system according to one aspect of the present invention is provided.
The system transmits a first bit string and a second bit string from the transmitting apparatus to the receiving apparatus by transmitting an optical signal from the transmitting apparatus to the receiving apparatus.

Furthermore, this visible light communication system
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. First signal generating means for generating a first signal, which is a signal having a preset first mark ratio value, the mark ratio being different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. The second signal generation for generating the second signal, wherein the mark rate, which is the ratio of the time during which the signal value is the true value in the symbol period, is a signal having a preset second mark rate value Means,
Multiplex signal generating means for generating an exclusive OR of the generated first signal and the generated second signal as a multiplexed signal in a state where the symbol period is synchronized,
An optical signal generating means for generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value;
Is provided.

In addition, the visible light communication method according to another aspect of the present invention includes:
This is a method for transmitting a first bit string and a second bit string from the transmitting apparatus to the receiving apparatus by transmitting an optical signal from the transmitting apparatus to the receiving apparatus.

Furthermore, this visible light communication method
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value,
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
This is a method of generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value.

In addition, a transmission apparatus according to another aspect of the present invention is
The device transmits the first bit string and the second bit string to the receiving device by transmitting the optical signal to the receiving device.

Furthermore, this transmission device
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. First signal generating means for generating a first signal, which is a signal having a preset first mark ratio value, the mark ratio being different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. The second signal generation for generating the second signal, wherein the mark rate, which is the ratio of the time during which the signal value is the true value in the symbol period, is a signal having a preset second mark rate value Means,
Multiplex signal generating means for generating an exclusive OR of the generated first signal and the generated second signal as a multiplexed signal in a state where the symbol period is synchronized,
An optical signal generating means for generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value;
Is provided.

In addition, a transmission method according to another aspect of the present invention includes:
This is a method for transmitting a first bit string and a second bit string to the receiving apparatus by transmitting an optical signal to the receiving apparatus.

Furthermore, this transmission method is
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value,
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
This is a method of generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value.

Moreover, the transmission program which is the other form of this invention is the following.
By transmitting the optical signal to the receiving device, the transmitting device that transmits the first bit string and the second bit string to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value,
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
For generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value. It is a program.

In addition, a receiving apparatus according to another aspect of the present invention is
By receiving an optical signal transmitted by a transmission device, the device acquires a first bit string and a second bit string from the transmission device.

Furthermore, this receiving device
Each of the portions of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with the change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, Non-inverted bit string acquisition means for acquiring a non-inverted bit string from the multiplexed signal by acquiring a bit that is 0 for
The signal value in the portion of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal, divided for each first symbol period. If there is a bit associated with the change according to the first method, the bit is acquired for the part, and the signal value change in the part is associated with the change according to the first method. Inversion bit string acquisition means for acquiring an inverted bit string from the inverted multiplex signal by acquiring a bit that is 0 for the portion when the given bit does not exist;
First bit string acquisition means for acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where the symbol period is synchronized;
Is provided.

Moreover, the receiving method which is the other form of this invention is the following.
This is a method for acquiring a first bit string and a second bit string from the transmitting apparatus by receiving an optical signal transmitted by the transmitting apparatus.

Furthermore, this receiving method is
Each of the portions of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with the change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, On the other hand, by acquiring a bit that is 0, a non-inverted bit string is acquired from the multiplexed signal,
The signal value in the portion of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal, divided for each first symbol period. If there is a bit associated with the change according to the first method, the bit is acquired for the part, and the signal value change in the part is associated with the change according to the first method. If the given bit does not exist, by obtaining the bit that is 0 for the part, obtain the inverted bit string from the inverted multiplexed signal,
This is a method of acquiring the logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where the symbol period is synchronized.

Moreover, the receiving program which is the other form of this invention is:
By receiving the optical signal transmitted by the transmitting device, the first bit string and the receiving device that acquires the second bit string from the transmitting device,
Each of the portions of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with the change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, On the other hand, by acquiring a bit that is 0, a non-inverted bit string is acquired from the multiplexed signal,
The signal value in the portion of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal, divided for each first symbol period. If there is a bit associated with the change according to the first method, the bit is acquired for the part, and the signal value change in the part is associated with the change according to the first method. If the given bit does not exist, by obtaining the bit that is 0 for the part, obtain the inverted bit string from the inverted multiplexed signal,
A program for executing a process of acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where the symbol period is synchronized.

  By being configured as described above, the present invention can perform visible light communication in which transmission signals are multiplexed while suppressing flickering of light.

1 is a diagram illustrating a schematic configuration of a visible light communication system according to a first embodiment of the present invention. It is a block diagram showing the structure of the transmitter which concerns on 1st Embodiment of this invention. It is a block diagram showing the structure of the receiver which concerns on 1st Embodiment of this invention. It is a block diagram showing the structure of the receiver which concerns on 2nd Embodiment of this invention. It is a figure showing schematic structure of the visible light communication system which concerns on 3rd Embodiment of this invention. It is a block diagram showing the structure of the transmitter which concerns on 3rd Embodiment of this invention. It is a block diagram showing the structure of the receiver which concerns on 3rd Embodiment of this invention. It is the time chart which showed the 1st signal, 2nd signal, and multiplexed signal based on 3rd Embodiment of this invention. It is explanatory drawing which showed notionally the relationship between the area | region which can acquire a 1st bit sequence, and the area | region which can acquire a 2nd bit sequence based on 3rd Embodiment of this invention. It is a block diagram showing the structure of the optical communication system which concerns on 4th Embodiment of this invention.

  Hereinafter, referring to FIG. 1 to FIG. 10 for each embodiment of a visible light communication system, a visible light communication method, a transmission device, a transmission method, a transmission program, a reception device, a reception method, and a reception program according to the present invention. While explaining.

<First Embodiment>
(Constitution)
As shown in FIG. 1, the visible light communication system 1 according to the first embodiment includes a transmission device 10 and a reception device 20. The visible light communication system 1 transmits the first bit sequence and the second bit sequence from the transmission device 10 to the reception device 20 by transmitting an optical signal from the transmission device 10 to the reception device 20.

  In the present example, the transmission device 10 is a lighting device (for example, a lighting device using an inverter fluorescent lamp or LED (Light Emitting Diode)). The transmission device 10 may be a display device that displays an image using a plurality of light emitting elements.

  The transmission device 10 includes a light emitting unit 11 that emits light when supplied with current. In this example, the light is visible light. The receiving device 20 includes a light receiving unit 21 including a light receiving element that receives light and converts the received light into a current. The transmission device 10 transmits an optical signal when the light emitting unit 11 emits light. The receiving device 20 receives the optical signal transmitted from the transmitting device 10 by the light receiving unit 21.

Next, the configuration of each of the transmission device 10 and the reception device 20 will be described in more detail.
As illustrated in FIG. 2, the transmission device 10 includes a first signal generation unit (first signal generation unit) 12, a second signal generation unit (second signal generation unit) 13, and signal synchronization adjustment. Unit 14, multiple signal generation unit (multiplex signal generation means) 15, and light emission control unit 16.

  The first signal generation unit 12 receives the first bit string and generates a first signal representing the received first bit string. In this example, the first bit string is generated by the transmission device 10. The bit string is a plurality of consecutive bits (“0” or “1”).

  The first signal is a signal having either a true value (Hi value) or a false value (Low value). Further, in the first signal, each of the parts (symbols) divided for each preset first symbol period Ta corresponds to the change of the signal value in the part according to the preset first method. Represents an attached bit.

  In addition, the first signal is a signal in which a mark rate in an arbitrary symbol period (symbol) has a preset first mark rate value. Here, the mark rate is the ratio of the time when the signal value is a true value in one symbol period to the first symbol period Ta. Further, the first mark rate value is a value different from 50%.

For example, the first signal generation unit 12 generates the first signal according to a pulse position modulation method in which the first mark ratio value is 25%. The first signal generation unit 12 may be configured to generate the first signal according to another method.
The first signal generation unit 12 outputs the generated first signal to the multiplexed signal generation unit 15.

  The second signal generator 13 receives the second bit string and generates a second signal representing the received second bit string. In this example, the second bit string is generated by the transmission device 10.

  The second signal is a signal having either a true value (Hi value) or a false value (Low value). Further, in the second signal, each of the parts divided for each preset second symbol period Tb is associated with the change in the signal value in the part according to the preset second method. Represents a bit.

  Here, the minimum change time Tb2 of the signal value in the second signal is determined to be a value obtained by multiplying the first symbol period Ta by the natural number n. That is, the mathematical formula Tb2 = n · Ta.

  In addition, the second signal is a signal in which the mark rate in an arbitrary symbol period has a preset second mark rate value. Here, the mark rate is the ratio of the time when the signal value is a true value in one symbol period to the second symbol period Tb.

For example, the second signal generation unit 13 generates the second signal according to the Manchester encoding method. The second signal generation unit 13 may be configured to generate the second signal according to another method such as a pulse position modulation method in which the second mark ratio value is 25%. In this case, since the second symbol period Tb is twice the minimum change time Tb2 of the signal value in the second signal, the equation Tb = 2n · Ta is established.
The second signal generation unit 13 outputs the generated second signal to the multiplexed signal generation unit 15.

  The signal synchronization adjustment unit 14 synchronizes the symbol periods of the first signal generated by the first signal generation unit 12 and the second signal generated by the second signal generation unit 13. That is, the signal synchronization adjustment unit 14 is configured to output a timing at which a portion of N consecutive symbol periods (symbols) of the first signal is output by the first signal generation unit 12 and the second signal. The timing at which the portion where one symbol period (symbol) starts is output by the second signal generator 13 is matched. Here, N is an equation N = 2n.

The multiplex signal generation unit 15 uses an exclusive OR of the first signal output from the first signal generation unit 12 and the second signal output from the second signal generation unit 13 as a multiplex signal. Generate. That is, the multiplexed signal generation unit 15 synchronizes the symbol period with the first signal generated by the first signal generation unit 12 and the second signal generated by the second signal generation unit 13. Are generated as a multiplexed signal.
The multiplex signal generation unit 15 outputs the generated multiplex signal to the light emission control unit 16.

  The light emission control unit 16 controls the light emission unit 11 based on the multiplexed signal output from the multiplexed signal generation unit 15. Specifically, the light emission control unit 16 supplies a current to the light emitting unit 11 when the signal value of the multiplexed signal is a true value, and also supplies a current to the light emitting unit 11 when the signal value of the multiplexed signal is a false value. Is not supplied (current supply is cut off).

  In this way, the light emission control unit 16 and the light emission unit 11 emit light when the signal value of the multiplexed signal generated by the multiplexed signal generation unit 15 is a true value, and when the signal value is a false value. By not emitting light, optical signal generation means for generating an optical signal is configured.

  As shown in FIG. 3, the receiving device 20 includes a non-inverted bit string acquisition unit (non-inverted bit string acquisition unit, intermediate signal acquisition unit) 22, an inverted bit string acquisition unit (inverted bit string acquisition unit) 23, a first A bit string acquisition unit (first bit string acquisition unit) 24 and a second bit string acquisition unit (second bit string acquisition unit) 25.

  The light receiving unit 21 receives the optical signal transmitted by the transmission device 10. The light receiving unit 21 converts the received optical signal into an electrical signal and outputs the converted electrical signal (multiplexed signal).

  The non-inverted bit string acquisition unit 22 performs pattern match determination processing on each of the portions (symbols) divided for each first symbol period Ta of the multiplexed signal output from the light receiving unit 21.

  In the pattern match determination process, whether the change in signal value in one symbol matches one of the patterns determined according to the first method (that is, there is a bit associated according to the first method). This is a process for determining whether or not.

  The non-inverted bit string acquisition unit 22 performs a bit operation based on the result of the pattern match determination process for each portion (symbol) divided for each first symbol period Ta of the multiplexed signal output from the light receiving unit 21. To get.

  Specifically, the non-inverted bit string acquisition unit 22 determines that the change is made when the change in the signal value in a certain symbol matches one of the patterns determined according to the first scheme. The bit associated with the pattern according to the first method is acquired as a bit for the symbol.

  Further, when it is determined that the change in the signal value in a certain symbol does not match any of the patterns determined according to the first method, the non-inverted bit string acquisition unit 22 sets “0” to the bit for the symbol. Get as.

  In this way, the non-inverted bit string acquisition unit 22 includes bits acquired for each portion (symbol) divided for each first symbol period Ta of the multiplexed signal output by the light receiving unit 21. Get bit string as non-inverted bit string.

  The non-inverted bit string acquisition unit 22 outputs the acquired non-inverted bit string to the first bit string acquisition unit 24.

  Further, the non-inverted bit string acquisition unit 22 is based on the result of the pattern match determination processing for each portion (symbol) divided for each first symbol period Ta of the multiplexed signal output by the light receiving unit 21. To obtain an intermediate signal.

  Specifically, the non-inverted bit string acquisition unit 22 sets the symbol to a false value when it is determined that the change in the signal value in a certain symbol matches one of the patterns determined according to the first method. At the same time, when it is determined that the change in the signal value does not match any of the patterns determined according to the first method, the intermediate signal is acquired by replacing the symbol with a true value.

  The non-inverted bit string acquisition unit 22 outputs the acquired intermediate signal to the second bit string acquisition unit 25.

  The inverted bit string acquisition unit 23 generates an inverted multiplexed signal by replacing the true value and the false value of the signal value included in the multiplexed signal output by the light receiving unit 21. Further, the inverted bit string acquisition unit 23 performs the pattern match determination process for each portion (symbol) divided for each first symbol period Ta of the generated inverted multiplexed signal.

  The inverted bit string acquisition unit 23 acquires bits based on the result of the pattern match determination process for each portion (symbol) divided for each first symbol period Ta of the inverted multiplexed signal.

  Specifically, the inverted bit string acquisition unit 23 determines that the signal value change in a certain symbol matches with any of the patterns determined according to the first scheme. A bit associated with the pattern according to the first method is acquired as a bit for the symbol.

  Further, when it is determined that the change in the signal value in a certain symbol does not match any of the patterns determined according to the first method, the inverted bit string acquisition unit 23 sets “0” as a bit for the symbol. get.

  In this way, the inverted bit string acquisition unit 23 acquires, as an inverted bit string, a bit string made up of bits acquired for each portion (symbol) divided for each first symbol period Ta of the inverted multiplexed signal. To do.

  The inverted bit string acquisition unit 23 outputs the acquired inverted bit string to the first bit string acquisition unit 24.

  The first bit string acquisition unit 24 performs a logical sum of the non-inverted bit string output from the non-inverted bit string acquisition unit 22 and the inverted bit string output from the inverted bit string acquisition unit 23 in a state where the symbol period is synchronized. Obtained as the first bit string. That is, the first bit string acquisition unit 24 is a bit string composed of bits that are the logical sum of two bits acquired for the same symbol (bits constituting a non-inverted bit string and bits constituting an inverted bit string). As the first bit string.

  For each portion (symbol) of the intermediate signal output by the non-inverted bit sequence acquisition unit 22 divided for each second symbol period Tb, the second bit sequence acquisition unit 25 obtains the signal value in the part. Get the bit associated with the change according to the second scheme.

  In this way, the second bit string acquisition unit 25 is acquired for each portion (symbol) divided for each second symbol period Tb of the intermediate signal output by the non-inverted bit string acquisition unit 22. A bit string consisting of the bits is acquired as the second bit string.

(Operation)
Next, the operation of the visible light communication system 1 described above will be described.
The transmission device 10 generates each of the first bit string and the second bit string. Next, the transmission device 10 generates a first signal based on the generated first bit string. Furthermore, the transmission device 10 generates a second signal based on the generated second bit string.

  Then, the transmission apparatus 10 generates a multiplexed signal based on the generated first signal and the generated second signal. Next, the transmitting device 10 transmits an optical signal representing the multiplexed signal to the receiving device 20 by controlling the light emitting unit based on the generated multiplexed signal.

  The receiving device 20 receives the optical signal transmitted by the transmitting device 10. The receiving device 20 acquires each of the non-inverted bit string and the inverted bit string based on the multiplexed signal represented by the received optical signal. Next, the receiving device 20 acquires a first bit string based on the acquired non-inverted bit string and the acquired inverted bit string.

  Furthermore, the receiving device 20 acquires an intermediate signal based on the multiplexed signal represented by the received optical signal. Next, the receiving device 20 acquires a second bit string based on the acquired intermediate signal.

  In this way, the visible light communication system 1 transmits the first bit sequence and the second bit sequence from the transmission device 10 to the reception device 20 by transmitting the optical signal from the transmission device 10 to the reception device 20. .

  As described above, according to the visible light communication system 1 according to the first embodiment of the present invention, in the multiplexed signal, the signal value is a true value in an arbitrary symbol period with respect to the second symbol period Tb. The mark rate, which is the ratio of, can be set to a constant value. As a result, the flickering of light due to the optical signal can be suppressed. Furthermore, since the first bit string and the second bit string are transmitted without controlling the light intensity (amplitude), the circuit for generating the optical signal can be simplified, thereby reducing the circuit size and the manufacturing cost. Can be reduced.

  In the visible light communication system 1 according to the first embodiment, the non-inverted bit string acquisition unit 22 is configured to acquire the intermediate signal based on the multiplexed signal. However, the inverted bit string acquisition unit 23 is the inverted multiplexed signal. The intermediate signal may be acquired based on

Second Embodiment
Next, a visible light communication system according to the second embodiment of the present invention will be described. The visible light communication system according to the second embodiment is different from the optical communication system according to the first embodiment in that a second bit string is obtained by using a low-pass filter. Accordingly, the following description will focus on such differences.

  The reception device 20 according to the second embodiment includes an intermediate signal acquisition unit (intermediate signal acquisition means) 26 in addition to the configuration included in the reception device 20 according to the first embodiment.

  The intermediate signal acquisition unit 26 includes a low-pass filter. The intermediate signal acquisition unit 26 uses a low-pass filter to generate a signal component having a symbol period shorter than the second symbol period Tb (for example, the first symbol period Ta) from the multiplexed signal output from the light receiving unit 21. An intermediate signal from which is removed is acquired. The intermediate signal acquisition unit 26 outputs the acquired intermediate signal to the second bit string acquisition unit 25.

  Further, the second bit string acquisition unit 25 according to the second embodiment acquires the second bit string based on the intermediate signal output by the intermediate signal acquisition unit 26.

  The visible light communication system 1 configured as described above can provide the same operations and effects as the visible light communication system 1 according to the first embodiment.

<Third Embodiment>
(Constitution)
Next, a visible light communication system according to the third embodiment of the present invention will be described.
As shown in FIG. 5, the visible light communication system 100 according to the third embodiment includes a transmission device 110 and a reception device 120.

  The visible light communication system 100 transmits the first bit sequence and the second bit sequence from the transmission device 110 to the reception device 120 by transmitting an optical signal from the transmission device 110 to the reception device 120.

  In this example, the optical signal is formed by visible light. In the present example, the first bit string is data representing content. For example, the content is an image, a sound, or a moving image. The second bit string is data indicating that the transmission device 110 is delivering content. That is, the optical communication system 100 is a system that distributes content.

  The transmission device 110 is a display device including a display panel 110a. The transmission device 110 transmits an optical signal by blinking a plurality of LEDs disposed in the display panel 110a. The transmission device 110 may be a lighting device (for example, an illuminator using an inverter fluorescent lamp or LED), a television receiver, an LED traffic light, or the like.

  The receiving device 120 is a portable terminal device. The receiving device 120 includes a display panel 120a, a plurality of key buttons 120b,..., And a light receiving unit 121.

  The receiving device 120 receives the optical signal transmitted from the transmitting device 110, thereby acquiring the first bit string and the second bit string. The receiving device 120 outputs the content represented by the acquired first bit string (displays it on the display panel 120a). The receiving device 120 outputs the data represented by the acquired second bit string (displays it on the display panel 120a).

  The light receiving unit 121 includes a light receiving element that receives light and converts the received light into a current. The light receiving unit 121 receives the optical signal transmitted from the transmission device 110 by the light receiving element. The light receiving unit 121 converts the received optical signal into an electrical signal and outputs the converted electrical signal (multiplexed signal).

Next, the configurations of the transmission device 110 and the reception device 120 will be described in more detail.
As illustrated in FIG. 6, the transmission device 110 includes a transmission data processing unit 111, a 4 PPM (4 Pulse Position Modulation) modulation unit (first signal generation unit) 112, and a Manchester encoding unit (second signal generation unit). Means) 113, a signal synchronization adjustment unit 114, a multiple signal generation unit (multiple signal generation unit) 115, and an LED drive unit 116.

  As described above, a plurality of LEDs 110b,... Are arranged in the display panel 110a. In this example, the display panel 110a constitutes a light emitting unit that emits light when supplied with current.

  Transmission data processing section 111 outputs a first bit string as data representing content to 4PPM modulation section 112. Further, the transmission data processing unit 111 outputs a second bit string as data representing that the transmission device 110 is delivering content to the Manchester encoding unit 113.

  In this example, the transmission data processing unit 111 stores a first bit string and a second bit string in advance. Note that the transmission data processing unit 111 may be configured to generate the first bit string and the second bit string.

  The 4PPM modulation unit 112 has the same function as the first signal generation unit 12 according to the first embodiment. Based on the first bit string output from transmission data processing section 111, 4PPM modulation section 112 generates a first signal according to a pulse position modulation scheme in which the first mark ratio value is 25%.

  Specifically, the 4PPM modulation unit 112 stores in advance four records in which a change in signal value in one symbol is associated with a bit. In this example, the first record is a true value in the first period of four periods obtained by dividing the symbol period into four equal parts, and a change in signal value that is a false value in the remaining period, and “00” Is a record in which these two bits are associated with each other. The second record is composed of a change in signal value that is a true value in the second period of the four periods obtained by dividing the symbol period into four equal parts, and a false value in the remaining period, and “01”. A record in which two bits are associated with each other.

Further, the third record is composed of a change in signal value that is a true value in the third period of the four periods obtained by dividing the symbol period into four equal parts, and a false value in the remaining period, and “10”. A record in which two bits are associated with each other. Further, the fourth record is a true value in the last period of the four periods obtained by dividing the symbol period into four equal parts, and a change in signal value that is a false value in the remaining period and 2 consisting of “11”. A record in which two bits are associated with each other.
The 4PPM modulation unit 112 generates a first signal based on the stored record.

  The Manchester encoding unit 113 has the same function as the second signal generation unit 13 according to the first embodiment. The Manchester encoding unit 113 generates a second signal according to the Manchester encoding method based on the second bit string output from the transmission data processing unit 111.

Specifically, the Manchester encoding unit 113 stores in advance two records in which a change in signal value in one symbol is associated with a bit. In this example, the first record is a true value in the first period of two periods obtained by dividing the symbol period into two equal parts, and a change in signal value that is a false value in the remaining period, Is a record in which one bit is associated. The second record is a false value in the first period of the two periods obtained by dividing the symbol period into two equal parts, and a change in the signal value that is a true value in the remaining period and 1 consisting of “1”. A record in which two bits are associated with each other.
The Manchester encoding unit 113 generates a second signal based on the stored record.

  In this example, the second symbol period Tb is a value obtained by multiplying the first symbol period Ta by “4”. That is, the mathematical formula Tb = 4 · Ta holds.

The signal synchronization adjustment unit 114 has the same function as the signal synchronization adjustment unit 14 according to the first embodiment.
The multiplexed signal generator 115 has the same function as that of the multiplexed signal generator 15 according to the first embodiment.

  The LED driving unit 116 controls the display panel 110a based on the multiplexed signal output from the multiplexed signal generating unit 115. Specifically, the LED drive unit 116 supplies current to the LED 110b when the signal value of the multiplexed signal is a true value, and does not supply current to the LED 110b when the signal value of the multiplexed signal is a false value ( Cut off the current supply).

  In this manner, the LED driving unit 116 and the display panel 110a emit light when the signal value of the multiplexed signal generated by the multiplexed signal generating unit 115 is a true value, and when the signal value is a false value. By not emitting light, optical signal generation means for generating an optical signal is configured.

  Further, as illustrated in FIG. 7, the reception device 120 includes a 4PPM demodulation unit (non-inverted bit string acquisition unit) 122, an I-4PPM (Inverse 4 PPM) demodulation unit (inversion bit string acquisition unit) 123, and a logical sum unit ( (First bit string acquisition unit) 124, Manchester code decoding unit (second bit string acquisition unit) 125, low-pass filter unit 126, binarization unit 127, binarization unit 128, and received data processing unit 129 And comprising.

  The binarization unit 127 performs binarization processing on the multiplexed signal output from the light receiving unit 121. The binarization process is a process of correcting the signal value of the multiplexed signal to either a true value or a false value. Specifically, the binarization process is a process of correcting the signal value to a value closer to the true value and the false value. The binarization unit 127 outputs the multiplexed signal corrected by the binarization process to each of the 4PPM demodulation unit 122 and the I-4PPM demodulation unit 123.

  The 4PPM demodulation unit 122 has the same function as the non-inverted bit string acquisition unit 22 according to the second embodiment. The 4PPM demodulation unit 122 acquires a non-inverted bit string based on the multiplexed signal output from the binarization unit 127.

  Specifically, the 4PPM demodulation unit 122 stores four records in advance as in the 4PPM modulation unit 112. The 4PPM demodulator 122 obtains a non-inverted bit string by performing a pattern match determination process based on the multiplexed signal and the stored record.

  The I-4PPM demodulation unit 123 has the same function as the inverted bit string acquisition unit 23 according to the second embodiment. The I-4PPM demodulation unit 123 acquires an inverted bit string based on the multiplexed signal output from the binarization unit 127.

  Specifically, the I-4PPM demodulation unit 123 generates an inverted multiplexed signal in which the true value and the false value of the signal value included in the multiplexed signal output from the binarizing unit 127 are replaced. Also, the I-4PPM demodulation unit 123 stores four records in advance as in the 4PPM modulation unit 112. The I-4PPM demodulation unit 123 obtains an inverted bit string by performing a pattern match determination process based on the generated inverted multiplexed signal and the stored record.

  The logical sum unit 124 has the same function as that of the first bit string acquisition unit 24 according to the second embodiment. The logical sum unit 124 outputs the acquired first bit string to the reception data processing unit 129.

  The low-pass filter unit 126 has the same function as the intermediate signal acquisition unit 26 according to the second embodiment. The low pass filter unit 126 outputs the acquired intermediate signal to the binarization unit 128.

  The binarization unit 128 executes binarization processing on the intermediate signal output from the low pass filter unit 126. The binarization unit 128 outputs the intermediate signal corrected by the binarization process to the Manchester code decoding unit 125.

  The Manchester code decoding unit 125 has the same function as the second bit string acquisition unit 25 according to the second embodiment. The Manchester code decoding unit 125 acquires the second bit string based on the intermediate signal output from the binarization unit 128.

  Specifically, the Manchester code decoding unit 125 stores two records in advance in the same manner as the Manchester encoding unit 113. The Manchester code decoding unit 125 acquires the second bit string based on the intermediate signal and the stored record. The Manchester code decoding unit 125 outputs the acquired second bit string to the reception data processing unit 129.

  The reception data processing unit 129 executes processing for outputting content based on the first bit string output by the logical sum unit 124. In addition, the reception data processing unit 129 executes processing for outputting data indicating that the transmission apparatus 110 is distributing content, based on the second bit string output by the Manchester code decoding unit 125.

(Operation)
Next, the operation of the above-described optical communication system 100 will be described.
The transmission data processing unit 111 outputs the first bit string to the 4PPM modulation unit 112 and outputs the second bit string to the Manchester encoding unit 113. Next, the 4PPM modulation unit 112 generates a first signal based on the input first bit string. Further, the Manchester encoding unit 113 generates a second signal based on the input second bit string.

  FIG. 8 is a time chart showing the first signal, the second signal, and the multiplexed signal. As described above, in this example, the symbol period (second symbol period) Tb in the second signal is four times the symbol period (first symbol period) Ta in the first signal.

  Then, the multiplexed signal generation unit 115 multiplexes the exclusive OR of the generated first signal and the generated second signal in a state where the symbol period is synchronized by the signal synchronization adjustment unit 114. Generate as a signal.

  That is, as shown in FIG. 8, the generated multiplexed signal has a signal value in the first signal in a section where the signal value is a false value in the second signal, while the second signal In the section in which the signal value is a true value, the signal value in the first signal is inverted (the true value and the false value are replaced).

  Next, the LED drive unit 116 transmits an optical signal representing the multiplexed signal by blinking the plurality of LEDs 110b,... Based on the generated multiplexed signal.

  As shown in FIG. 8, the mark rate of the multiplexed signal with respect to the second symbol period Tb is a constant value (50% in this example). Therefore, the brightness perceived by a person when viewed by the optical signal transmitted by the transmission device 110 is constant (does not vary with time). That is, it is possible to suppress flickering of light due to an optical signal.

  The light receiving unit 121 receives the optical signal transmitted by the transmission device 110. The light receiving unit 121 generates a multiplexed signal represented by the received optical signal. Next, the binarization unit 127 performs binarization processing on the generated multiplexed signal, and converts the binarized multiplexed signal to the 4PPM demodulation unit 122 and the I-4PPM demodulation unit 123, respectively. Output to.

  The 4PPM demodulator 122 acquires a non-inverted bit string based on the input multiplexed signal, and outputs the acquired non-inverted bit string to the logical sum unit 124. Further, the I-4PPM demodulation unit 123 generates an inverted multiplexed signal obtained by inverting the input multiplexed signal, acquires an inverted bit string based on the generated inverted multiplexed signal, and ORs the acquired inverted bit string. To 124.

  Next, the logical sum unit 124 acquires a logical sum of the input non-inverted bit string and the input inverted bit string as a first bit string, and outputs the acquired first bit string to the reception data processing unit 129. To do.

  Further, the low-pass filter unit 126 removes an intermediate signal obtained by removing a signal component having a symbol period shorter than the second symbol period Tb (for example, the first symbol period Ta) from the multiplexed signal generated by the light receiving unit 121. The data is output to the binarization unit 128.

  Next, the binarization unit 128 performs binarization processing on the input intermediate signal, and outputs the binarized intermediate signal to the Manchester code decoding unit 125. Then, Manchester code decoding section 125 acquires the second bit string based on the input intermediate signal, and outputs the acquired second bit string to reception data processing section 129.

  In this way, the optical communication system 100 transmits the first bit sequence and the second bit sequence from the transmission device 110 to the reception device 120 by transmitting the optical signal from the transmission device 110 to the reception device 120.

  Then, the received data processing unit 129 executes processing for outputting content based on the input first bit string. Thereby, the receiving device 120 outputs the content. In addition, the reception data processing unit 129 executes processing for outputting data indicating that the transmission apparatus 110 is delivering content based on the input second bit string. Thereby, the receiving device 120 outputs the data.

  Here, the relationship between the communication range of the optical signal transmitted by the transmission apparatus 110 and the method of using the first bit string and the second bit string will be described.

  FIG. 9 shows a relationship between an area (first communication area) R1 in which the first bit string can be acquired and an area (second communication area) R2 in which the second bit string can be acquired.

  For example, the content represented by the first bit string is information for guiding a facility where the transmission apparatus 110 is installed, or information for advertising a store in the facility (for example, coupon information). That is, the first communication area R1 is an area in which a first bit string representing information related to position information representing a position (location) where the transmission device 110 is installed can be acquired.

  Such content often includes data representing images, sounds, or moving images. Therefore, in order to transmit a signal representing the first bit string, it is necessary to perform communication using a high frequency band in which data can be transmitted at high speed (a large amount of data can be transmitted per unit time).

By the way, in general, the propagation loss in free space is expressed by the equation (4πd / λ) ^{2 where} the communication distance is d (m) and the wavelength of the transmission signal is λ (m). That is, the propagation loss increases in proportion to the square of the communication distance and increases in inverse proportion to the square of the wavelength. Therefore, the communication area for communication using the high frequency band (first communication area R1 in this example) is narrower than the communication area for communication using the low frequency band (second communication area R2 in this example). .

  If the transmission apparatus 110 transmits an optical signal representing only the first signal representing the first bit string, the reception apparatus 120 is not located in a region where the distance from the transmission apparatus 110 is relatively short. As long as the information from the transmission device 110 cannot be obtained.

  Therefore, in this example, the transmission device 110 transmits a second signal representing a second bit string indicating that the transmission device 110 is delivering content together with the first signal. The second bit string has a smaller amount of data than the first bit string. Therefore, the second bit string can be transmitted by performing communication using a low frequency band in which data can be transmitted at a lower speed than the first bit string.

  Thus, in the visible light communication system 100 according to the present embodiment, the receiving device 120 outputs data represented by the second bit string at a position relatively far from the transmitting device 110. Thereby, the user holding the receiving device 120 determines whether or not to acquire the data represented by the first bit string.

  Then, when the user holding the reception device 120 desires to acquire the data represented by the first bit string, the user approaches the transmission device 110. Thereby, the receiving apparatus 120 acquires the data represented by the first bit string and outputs the data. As a result, user convenience can be improved.

  As described above, the visible light communication system 100 according to the third embodiment can achieve the same operations and effects as the optical communication system 1 according to the first embodiment.

<Fourth embodiment>
Next, a visible light communication system according to the fourth embodiment of the present invention will be described with reference to FIG.
The visible light communication system 200 according to the fourth embodiment transmits a first bit sequence and a second bit sequence from the transmission device to the reception device by transmitting an optical signal from the transmission device to the reception device. It is.

Furthermore, the visible light communication system 200 includes:
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. A first signal generation unit (first signal generation unit) 201 for generating a first signal, which is a signal having a preset first mark ratio value, the mark ratio being different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. The second signal generation for generating the second signal, wherein the mark rate, which is the ratio of the time during which the signal value is the true value in the symbol period, is a signal having a preset second mark rate value Unit (second signal generating means) 202,
Multiplex signal generating unit (multiplexed signal generating means) for generating an exclusive OR of the generated first signal and the generated second signal as a multiplexed signal in a state where the symbol period is synchronized 203,
An optical signal generator (optical signal) that emits light when the signal value of the generated multiplexed signal has a true value and does not emit light when the signal value is a false value. Generating means) 204,
Is provided.

  According to this, in the multiplexed signal, the mark rate, which is the ratio of the time when the signal value is a true value in an arbitrary symbol period to the second symbol period, can be set to a constant value. As a result, the flickering of light due to the optical signal can be suppressed. Furthermore, since it is possible to transmit the first bit string and the second bit string without controlling the intensity (amplitude) of the light, the circuit for generating the optical signal can be simplified. Manufacturing cost can be reduced.

  Although the present invention has been described with reference to the above embodiment, the present invention is not limited to the above-described embodiment. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention within the scope of the present invention.

  In each of the above embodiments, each function of the visible light communication system is realized by hardware such as a circuit. By the way, each of the transmission device and the reception device includes a processing device and a storage device that stores a program (software), and the processing device executes the program so that each function is realized. It may be configured. In this case, the program may be stored in a computer-readable recording medium. For example, the recording medium is a portable medium such as a flexible disk, an optical disk, a magneto-optical disk, and a semiconductor memory.

  In addition, as another modified example of the above-described embodiment, any combination of the above-described embodiments and modified examples may be employed.

<Appendix>
A part or all of the above embodiment can be described as the following supplementary notes, but is not limited thereto.

(Appendix 1)
A visible light communication system that transmits a first bit string and a second bit string from the transmitting device to the receiving device by transmitting an optical signal from the transmitting device to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. First signal generating means for generating a first signal, which is a signal having a preset first mark ratio value, the mark ratio being different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. The second signal generation for generating the second signal, wherein the mark rate, which is the ratio of the time during which the signal value is the true value, in the symbol period is a signal having a preset second mark rate value Means,
Multiplex signal generation means for generating an exclusive OR of the generated first signal and the generated second signal as a multiplexed signal in a state where the symbol period is synchronized,
An optical signal generating means for generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value;
A visible light communication system.

  According to this, in the multiplexed signal, the mark rate, which is the ratio of the time when the signal value is a true value in an arbitrary symbol period to the second symbol period, can be set to a constant value. As a result, the flickering of light due to the optical signal can be suppressed. Furthermore, since it is possible to transmit the first bit string and the second bit string without controlling the intensity (amplitude) of the light, the circuit for generating the optical signal can be simplified. Manufacturing cost can be reduced.

(Appendix 2)
The visible light communication system according to appendix 1,
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. A bit that is 0 for the part, if the bit is obtained for the part and there is no bit associated with the change in signal value in the part according to the first method. By obtaining a non-inverted bit sequence from the multiplexed signal,
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. Inversion bit string acquisition means for acquiring an inverted bit string from the inverted multiplex signal by acquiring a bit that is 0 for the portion when the given bit does not exist;
First bit string acquisition means for acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where the symbol period is synchronized;
A visible light communication system.

(Appendix 3)
The visible light communication system according to appendix 1 or appendix 2,
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. In this case, by replacing the part with a false value and replacing the part with a true value when there is no change in the signal value in the part and the bit associated according to the first method, Intermediate signal acquisition means for acquiring an intermediate signal;
For each portion of the acquired intermediate signal divided for each second symbol period, a signal value change in the portion and a bit associated according to the second scheme are acquired. A second bit string acquisition means for acquiring the second bit string from the intermediate signal,
A visible light communication system.

(Appendix 4)
The visible light communication system according to appendix 1 or appendix 2,
Intermediate signal acquisition means for acquiring an intermediate signal obtained by removing a signal component having a symbol period shorter than the second symbol period from the multiplexed signal represented by the optical signal by using a low-pass filter;
For each portion of the acquired intermediate signal divided for each second symbol period, a signal value change in the portion and a bit associated according to the second scheme are acquired. A second bit string acquisition means for acquiring the second bit string from the intermediate signal,
A visible light communication system.

(Appendix 5)
The visible light communication system according to any one of supplementary notes 1 to 4,
The visible light communication system, wherein the first signal generation means is configured to generate the first signal in accordance with a pulse position modulation method in which the first mark ratio value is 25%.

(Appendix 6)
The visible light communication system according to any one of supplementary notes 1 to 5,
The visible light communication system, wherein the second signal generation means is configured to generate the second signal according to a Manchester encoding method.

(Appendix 7)
The visible light communication system according to any one of supplementary notes 1 to 5,
The visible light communication system configured to generate the second signal in accordance with a pulse position modulation method in which the second mark ratio value is 25%.

(Appendix 8)
The visible light communication system according to any one of appendices 1 to 7,
The optical signal generation means is a visible light communication system configured to generate the optical signal by emitting visible light.

(Appendix 9)
A visible light communication method for transmitting a first bit string and a second bit string from the transmitting apparatus to the receiving apparatus by transmitting an optical signal from the transmitting apparatus to the receiving apparatus,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value;
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
A visible light communication method of generating light by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value.

(Appendix 10)
The visible light communication method according to attachment 9, wherein
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. A bit that is 0 for the part, if the bit is obtained for the part and there is no bit associated with the change in signal value in the part according to the first method. To obtain a non-inverted bit string from the multiplexed signal,
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. If the given bit does not exist, by obtaining the bit that is 0 for the part, obtain the inverted bit string from the inverted multiplexed signal,
A visible light communication method of acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state in which a symbol period is synchronized.

(Appendix 11)
The visible light communication method according to appendix 9 or appendix 10, wherein
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. In this case, by replacing the part with a false value and replacing the part with a true value when there is no change in the signal value in the part and the bit associated according to the first method, Get an intermediate signal,
For each portion of the acquired intermediate signal divided for each second symbol period, a signal value change in the portion and a bit associated according to the second scheme are acquired. To obtain the second bit string from the intermediate signal.

(Appendix 12)
The visible light communication method according to appendix 9 or appendix 10, wherein
By using a low-pass filter, an intermediate signal obtained by removing a signal component having a symbol period shorter than the second symbol period is obtained from the multiplexed signal represented by the optical signal,
For each portion of the acquired intermediate signal divided for each second symbol period, a signal value change in the portion and a bit associated according to the second scheme are acquired. To obtain the second bit string from the intermediate signal.

(Appendix 13)
A transmitting device that transmits an optical signal to a receiving device to transmit the first bit string and the second bit string to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. First signal generating means for generating a first signal, which is a signal having a preset first mark ratio value, the mark ratio being different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. The second signal generation for generating the second signal, wherein the mark rate, which is the ratio of the time during which the signal value is the true value, in the symbol period is a signal having a preset second mark rate value Means,
Multiplex signal generation means for generating an exclusive OR of the generated first signal and the generated second signal as a multiplexed signal in a state where the symbol period is synchronized,
An optical signal generating means for generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value;
A transmission apparatus comprising:

(Appendix 14)
A transmission method for transmitting a first bit string and a second bit string to a receiving device by transmitting an optical signal to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value;
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
A transmission method that emits light when a signal value of the generated multiplexed signal is a true value and generates the optical signal by not emitting light when the signal value is a false value.

(Appendix 15)
By transmitting the optical signal to the receiving device, the transmitting device that transmits the first bit string and the second bit string to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value;
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
For generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value. Send program.

(Appendix 16)
By receiving the optical signal transmitted by the transmitting device, the receiving device acquires the first bit string and the second bit string from the transmitting device,
Each portion of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with a change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, Non-inverted bit string acquisition means for acquiring a non-inverted bit string from the multiplexed signal by acquiring a bit that is 0 for
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. Inversion bit string acquisition means for acquiring an inverted bit string from the inverted multiplex signal by acquiring a bit that is 0 for the portion when the given bit does not exist;
First bit string acquisition means for acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where the symbol period is synchronized;
A receiving device.

(Appendix 17)
The receiving device according to attachment 16, wherein
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. In this case, by replacing the part with a false value and replacing the part with a true value when there is no change in the signal value in the part and the bit associated according to the first method, Intermediate signal acquisition means for acquiring an intermediate signal;
For each portion divided for each preset second symbol period, which is a value obtained by multiplying the first symbol period by an integer of 2 or more in the acquired intermediate signal, Second bit string acquisition means for acquiring the second bit string from the intermediate signal by acquiring a bit associated with a change in the signal value according to a preset second method;
A receiving device.

(Appendix 18)
The receiving device according to attachment 16, wherein
By using a low pass filter, the multiplexed signal represented by the optical signal has a symbol period shorter than a preset second symbol period, which is a value obtained by multiplying the first symbol period by an integer of 2 or more. Intermediate signal acquisition means for acquiring an intermediate signal from which signal components have been removed;
For each portion of the acquired intermediate signal divided for each second symbol period, a change in signal value in the portion is associated with a bit associated according to a preset second method. A second bit string acquisition means for acquiring the second bit string from the intermediate signal by acquiring;
A receiving device.

(Appendix 19)
A receiving method for acquiring a first bit string and a second bit string from the transmitting apparatus by receiving an optical signal transmitted by the transmitting apparatus,
Each portion of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with a change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, On the other hand, by acquiring a bit that is 0, a non-inverted bit string is acquired from the multiplexed signal,
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. If the given bit does not exist, by obtaining the bit that is 0 for the part, obtain the inverted bit string from the inverted multiplexed signal,
A receiving method, wherein a logical sum of the acquired non-inverted bit string and the acquired inverted bit string is acquired as the first bit string in a state where symbol periods are synchronized.

(Appendix 20)
The reception method according to attachment 19, wherein
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. In this case, by replacing the part with a false value and replacing the part with a true value when there is no change in the signal value in the part and the bit associated according to the first method, Get an intermediate signal,
For each portion divided for each preset second symbol period, which is a value obtained by multiplying the first symbol period by an integer of 2 or more in the acquired intermediate signal, A receiving method of acquiring the second bit string from the intermediate signal by acquiring a bit associated with a change in signal value according to a preset second method.

(Appendix 21)
The reception method according to attachment 19, wherein
By using a low pass filter, the multiplexed signal represented by the optical signal has a symbol period shorter than a preset second symbol period, which is a value obtained by multiplying the first symbol period by an integer of 2 or more. Obtain an intermediate signal with the signal components removed,
For each portion of the acquired intermediate signal divided for each second symbol period, a change in signal value in the portion is associated with a bit associated according to a preset second method. A receiving method of acquiring the second bit string from the intermediate signal by acquiring.

(Appendix 22)
By receiving the optical signal transmitted by the transmitting device, the first bit string and the receiving device that acquires the second bit string from the transmitting device,
Each portion of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with a change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, On the other hand, by acquiring a bit that is 0, a non-inverted bit string is acquired from the multiplexed signal,
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. If the given bit does not exist, by obtaining the bit that is 0 for the part, obtain the inverted bit string from the inverted multiplexed signal,
A receiving program for executing a process of acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where symbol periods are synchronized.

(Appendix 23)
The receiving program according to attachment 22, wherein
The processing is as follows:
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. In this case, by replacing the part with a false value and replacing the part with a true value when there is no change in the signal value in the part and the bit associated according to the first method, Get an intermediate signal,
For each portion divided for each preset second symbol period, which is a value obtained by multiplying the first symbol period by an integer of 2 or more in the acquired intermediate signal, A reception program configured to acquire the second bit string from the intermediate signal by acquiring a bit associated with a change in signal value according to a preset second method.

(Appendix 24)
The receiving program according to attachment 22, wherein
The processing is as follows:
By using a low pass filter, the multiplexed signal represented by the optical signal has a symbol period shorter than a preset second symbol period, which is a value obtained by multiplying the first symbol period by an integer of 2 or more. Obtain an intermediate signal with the signal components removed,
For each portion of the acquired intermediate signal divided for each second symbol period, a change in signal value in the portion is associated with a bit associated according to a preset second method. A receiving program configured to acquire the second bit string from the intermediate signal by acquiring.

  The present invention is applicable to a visible light communication system that transmits an optical signal from a transmission device to a reception device.

DESCRIPTION OF SYMBOLS 1 Visible light communication system 10 Transmission apparatus 11 Light emission part 12 1st signal generation part 13 2nd signal generation part 14 Signal synchronization adjustment part 15 Multiplex signal generation part 16 Light emission control part 20 Reception apparatus 21 Light reception part 22 Non-inverted bit sequence acquisition Unit 23 inverted bit string acquisition unit 24 first bit string acquisition unit 25 second bit string acquisition unit 26 intermediate signal acquisition unit 100 visible light communication system 110 transmission device 110a display panel 110b,... LED
111 Transmission Data Processing Unit 112 4PPM Modulation Unit 113 Manchester Encoding Unit 114 Signal Synchronization Adjustment Unit 115 Multiplex Signal Generation Unit 116 LED Drive Unit 120 Receiver 120a Display Panel 120b,... Keyed Button 121 Light Receiving Unit 122 4PPM Demodulation Unit 123 4PPM demodulation unit 124 OR unit 125 Manchester code decoding unit 126 Low pass filter unit 127 Binarization unit 128 Binarization unit 129 Reception data processing unit 200 Optical communication system 201 First signal generation unit 202 Second signal generation unit 203 Multiplex signal generator 204 Optical signal generator

Claims (10)

A visible light communication system that transmits a first bit string and a second bit string from the transmitting device to the receiving device by transmitting an optical signal from the transmitting device to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. First signal generating means for generating a first signal, which is a signal having a preset first mark ratio value, the mark ratio being different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. The second signal generation for generating the second signal, wherein the mark rate, which is the ratio of the time during which the signal value is the true value, in the symbol period is a signal having a preset second mark rate value Means,
Multiplex signal generation means for generating an exclusive OR of the generated first signal and the generated second signal as a multiplexed signal in a state where the symbol period is synchronized,
An optical signal generating means for generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value;
A visible light communication system. The visible light communication system according to claim 1,
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. A bit that is 0 for the part, if the bit is obtained for the part and there is no bit associated with the change in signal value in the part according to the first method. By obtaining a non-inverted bit sequence from the multiplexed signal,
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. Inversion bit string acquisition means for acquiring an inverted bit string from the inverted multiplex signal by acquiring a bit that is 0 for the portion when the given bit does not exist;
First bit string acquisition means for acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where the symbol period is synchronized;
A visible light communication system. The visible light communication system according to claim 1 or 2,
For each portion of the multiplexed signal represented by the optical signal divided for each first symbol period, there is a bit associated with the change in the signal value in the portion and the first scheme. In this case, by replacing the part with a false value and replacing the part with a true value when there is no change in the signal value in the part and the bit associated according to the first method, Intermediate signal acquisition means for acquiring an intermediate signal;
For each portion of the acquired intermediate signal divided for each second symbol period, a signal value change in the portion and a bit associated according to the second scheme are acquired. A second bit string acquisition means for acquiring the second bit string from the intermediate signal,
A visible light communication system. The visible light communication system according to claim 1 or 2,
Intermediate signal acquisition means for acquiring an intermediate signal obtained by removing a signal component having a symbol period shorter than the second symbol period from the multiplexed signal represented by the optical signal by using a low-pass filter;
For each portion of the acquired intermediate signal divided for each second symbol period, a signal value change in the portion and a bit associated according to the second scheme are acquired. A second bit string acquisition means for acquiring the second bit string from the intermediate signal,
A visible light communication system. A transmitting device that transmits an optical signal to a receiving device to transmit the first bit string and the second bit string to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. First signal generating means for generating a first signal, which is a signal having a preset first mark ratio value, the mark ratio being different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. The second signal generation for generating the second signal, wherein the mark rate, which is the ratio of the time during which the signal value is the true value, in the symbol period is a signal having a preset second mark rate value Means,
Multiplex signal generation means for generating an exclusive OR of the generated first signal and the generated second signal as a multiplexed signal in a state where the symbol period is synchronized,
An optical signal generating means for generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value;
A transmission apparatus comprising: A transmission method for transmitting a first bit string and a second bit string to a receiving device by transmitting an optical signal to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value;
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
A transmission method that emits light when a signal value of the generated multiplexed signal is a true value and generates the optical signal by not emitting light when the signal value is a false value. By transmitting the optical signal to the receiving device, the transmitting device that transmits the first bit string and the second bit string to the receiving device,
Each of the portions representing the first bit string and having a signal value of either a true value or a false value and divided for each preset first symbol period is It represents a bit associated with a change in signal value according to a preset first method, and is a ratio of the time when the signal value is the true value in an arbitrary symbol period to the first symbol period. Generating a first signal, which is a signal having a preset first mark ratio value with a mark ratio different from 50%;
A signal that represents the second bit string and has a signal value of either a true value or a false value, and is a value obtained by multiplying the first symbol period by an integer of 2 or more. Each of the parts divided for each second symbol period represents a bit associated with a change in the signal value in the part according to a preset second method, and is arbitrary for the second symbol period. Generating a second signal in which a mark rate, which is a ratio of time during which the signal value is the true value in a symbol period, is a signal having a preset second mark rate value;
In a state where the symbol period is synchronized, an exclusive OR of the generated first signal and the generated second signal is generated as a multiplexed signal,
For generating the optical signal by emitting light when the signal value of the generated multiplexed signal is a true value and not emitting light when the signal value is a false value. Send program. By receiving the optical signal transmitted by the transmitting device, the receiving device acquires the first bit string and the second bit string from the transmitting device,
Each portion of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with a change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, Non-inverted bit string acquisition means for acquiring a non-inverted bit string from the multiplexed signal by acquiring a bit that is 0 for
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. Inversion bit string acquisition means for acquiring an inverted bit string from the inverted multiplex signal by acquiring a bit that is 0 for the portion when the given bit does not exist;
First bit string acquisition means for acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where the symbol period is synchronized;
A receiving device. A receiving method for acquiring a first bit string and a second bit string from the transmitting apparatus by receiving an optical signal transmitted by the transmitting apparatus,
Each portion of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with a change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, On the other hand, by acquiring a bit that is 0, a non-inverted bit string is acquired from the multiplexed signal,
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. If the given bit does not exist, by obtaining the bit that is 0 for the part, obtain the inverted bit string from the inverted multiplexed signal,
A receiving method, wherein a logical sum of the acquired non-inverted bit string and the acquired inverted bit string is acquired as the first bit string in a state where symbol periods are synchronized. By receiving the optical signal transmitted by the transmitting device, the first bit string and the receiving device that acquires the second bit string from the transmitting device,
Each portion of the multiplexed signal represented by the optical signal divided for each preset first symbol period is associated with a change in the signal value in the portion according to the preset first method. If the corresponding bit is present, the bit is acquired for the portion, and if the bit associated with the change in the signal value in the portion according to the first method does not exist, On the other hand, by acquiring a bit that is 0, a non-inverted bit string is acquired from the multiplexed signal,
The signal value in the portion for each of the divided portions of the inverted multiplexed signal obtained by replacing the true value and the false value of the signal value of the multiplexed signal represented by the optical signal for each of the first symbol periods. If there is a bit associated with the change according to the first scheme, the bit is acquired for the portion, and the signal value change in the portion is associated with the change according to the first scheme. If the given bit does not exist, by obtaining the bit that is 0 for the part, obtain the inverted bit string from the inverted multiplexed signal,
A receiving program for executing a process of acquiring a logical sum of the acquired non-inverted bit string and the acquired inverted bit string as the first bit string in a state where symbol periods are synchronized.

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