KR20100128226A - Visible light transmitter and method for displaying linearity of visible light source - Google Patents

Abstract

PURPOSE: A visible light transmitter and a method for displaying linearity of a visible light source are provided to conveniently prevent the distortion of a visible light signal transferred through a visible light wireless audio transmission device by controlling an amplification level of an amplification unit in a transmitter. CONSTITUTION: A voltage level mounting unit(120) monitors an output voltage level of an electric signal, and a bias voltage calculator(140) calculates the bias voltage applied fro the transmission of a visible light signal. Based on the voltage value for the application of the bias voltage to the output voltage level exists in a predetermined linear voltage section of the visible signal, a linearity determination unit(150) determines the linearity of the visible signal. A linearity notification unit(152) outputs the determination output of the linearity determination unit.

Description

Visible light transmitter and method for displaying linearity of visible light source}

The present invention relates to a visible light transmitting apparatus and method for informing linearity, and more particularly, to indicate whether the visible light emitting part of the transmitting device is operated out of linearity so that distortion of an audio signal does not occur in a wireless transmission / reception system using visible light wireless communication. A visible light transmitting apparatus and method.

The present invention is derived from the research conducted as part of the IT source technology development project of the Ministry of Knowledge Economy and the Ministry of Information and Communication Research and Development. [Task management number: 2008-F-009-02, Project name: IT lighting communication convergence 380 ~ 780 nano] Meter Visible RGB Screening Wireless Communication Research].

In general, visible light communication that transmits information using visible visible light has an advantage that its use band is wide and can be freely used without being regulated. In addition, the visible light communication has an advantage that the receiving range of the information can be known accurately because the location where the light is generated or the direction in which the light is generated can be seen. Therefore, it can be trusted in terms of security.

1 is a diagram illustrating a configuration of a transmitting and receiving device for analog visible light wireless communication generally used. When the audio player 1 outputs an electrical audio signal, the visible light wireless audio transmitter 2 converts the electrical audio signal into a visible light signal through a light emitting element such as an LED, and transmits the visible light wireless audio receiver 3. The signal is received and output through the speaker 4 or the headset 5 or the like.

2 to 4 illustrate the internal structure of the audio transmitter of FIG. 1 in more detail. In particular, FIG. 2 is a view of a conventional visible light wireless audio transmitter that performs only all-optical conversion without additional electrical modulation. It is a block diagram which shows a structure.

Referring to FIG. 2, in the case of a conventional visible light wireless audio transmitter that performs only all-optical conversion without additional electrical modulation, the audio signal applying and light emitting unit power applying unit 11 may include a DC bias power supply unit 12. The audio signal amplified by the DC bias power supply and the audio signal amplifier 10 is transferred to the visible light emitting unit. Accordingly, the visible light emitter 13 converts the electrical audio signal into a visible light signal and transmits the same.

3 is a block diagram showing the configuration of a conventional visible light wireless audio transmitting apparatus that performs all-optical signal conversion after electrically performing FM modulation.

Referring to FIG. 3, in the case of a conventional visible light wireless audio transmitter that electrically performs FM modulation and then performs all / optical signal conversion, the audio signal amplified by the audio signal amplifier 20 may be an audio signal FM modulator. FM is modulated at 21. The FM modulated signal applying unit and the light emitting unit power applying unit 23 transmit the FM modulated signal amplified by the DC bias power supply unit and the FM modulated signal amplifier unit 22 of the DC bias power supply unit 24 to the visible light emitting unit 25. To pass. Accordingly, the visible light emitting unit 25 converts the electrical FM modulated signal into a visible light signal and transmits the visible light signal.

4 is a block diagram showing the configuration of a conventional visible light wireless audio transmission apparatus that performs all-optical signal conversion after electrically performing AM modulation.

Referring to FIG. 4, in the case of a conventional visible light wireless audio transmitting apparatus that electrically performs AM modulation and then performs all / optical signal conversion, the audio signal amplified by the audio signal amplifier 30 is an audio signal AM modulator. AM is modulated at 31. In addition, the AM modulated signal applying unit and the light emitting unit power applying unit 33 transmit the AM biased signal amplified by the DC bias power supply and the AM modulated signal amplifier 32 of the DC bias power supply unit 34 to the visible light emitting unit 35. To pass. Accordingly, the visible light emitting unit 35 converts the electrical AM modulated signal into a visible light signal and transmits it.

5 is a schematic diagram showing an input / output port configuration of a typical audio player, and the visible light wireless audio transmitter 2 receives a signal from the speaker or the headset output port of FIG. 5. Therefore, when the volume is increased through the audio volume control unit of FIG. 5, the electrical audio signal is input to the visible light wireless audio transmitter 2 at a high volume, and when the volume is reduced, the electrical audio signal is transmitted to the visible light wireless audio transmitter 2. It is small.

FIG. 6 is a conceptual diagram illustrating the characteristics of visible light output power compared to a typical applied voltage or current of a visible light LED or a visible light LD (laser diode) applied to a visible light emitting unit of a visible light wireless audio transmitter. _{LIN_min} to V _{LIN_max} are linear sections of the visible light emitting unit 13, 25, or 35, and V _bias , which is an intermediate value of the linear sections, is usually set to a DC bias voltage in order to make the best use of the linear sections.

In this case, the linearity of the visible light signal transmitted to the receiving device may be maintained only by transmitting the visible light signal in the linear period, thereby minimizing signal distortion. In other words, when the audio transmitting device 2 outputs a visible light signal out of the linear section, the signal input to the audio receiving device 3 is already broken in linearity, which may cause severe signal distortion.

However, in the conventional visible light wireless communication device, it is not possible to confirm whether the visible light signal is linearly output in the transmitting device, and it is possible to confirm whether the signal is distorted by outputting the signal received through the receiving device. Therefore, when the receiving device is not close to the transmitting device, it is also difficult to check whether the signal transmitted from the transmitting device is out of linearity.

In order to solve the above problems, the present invention provides a method and apparatus for indicating whether the visible light emitting unit of the transmitting device is operated out of linearity so that distortion of an electrical signal does not occur in a wireless transmission / reception system using visible light wireless communication. The purpose is to provide.

The visible light transmitting device which reports linearity according to an embodiment of the present invention is a device for converting and transmitting an electrical signal into a visible light signal, and converting and receiving the visible light signal into an electrical signal, the voltage for monitoring the output voltage level of the electrical signal. Level monitoring unit; A bias voltage calculator configured to calculate a bias voltage applied for the transmission of the visible light signal; A linearity determination unit determining a linearity of the transmitted visible light signal based on whether a voltage value applied with a bias voltage to the output voltage level exists within a predetermined linearity voltage section of the visible light signal; And a linearity notification unit for outputting a determination result of the linearity determination unit. Characterized in that it comprises a.

In addition, the output voltage level of the electrical signal preferably includes the maximum and minimum output voltage.

In addition, the predetermined linear voltage range preferably includes a maximum and a minimum linear voltage.

In addition, the bias voltage calculation unit preferably calculates the bias voltage from a predetermined linear voltage range in which the linearity of the visible light signal is maintained.

The linearity determining unit preferably determines that the visible light signal is out of linearity when the sum of the maximum output voltage and the bias voltage of the electrical signal is greater than the maximum linear voltage.

In addition, the linearity determiner may determine that the visible light signal is out of linearity when the sum of the minimum output voltage and the bias voltage of the electrical signal is smaller than the minimum linear voltage.

The amplifier may further include an amplifier for amplifying the electrical signal, and the amplifier may vary the output voltage level of the electrical signal according to a determination result of the linearity determination unit.

In addition, it is preferable to further include a visible light emitting unit for generating a visible light signal, the visible light emitting unit is to vary the brightness of the visible light signal according to the determination result of the linearity determination unit.

In addition, the electrical signal is preferably an FM modulated signal.

The electrical signal is preferably an AM modulated signal.

In addition, the electrical signal is preferably an unmodulated signal.

On the other hand, the visible light transmission method for informing the linearity according to an embodiment of the present invention, a method for converting and transmitting an electrical signal to a visible light signal, converting the visible light signal into an electrical signal and receiving, the voltage level monitoring unit, Monitoring the output voltage level; Comprising a bias voltage calculation unit, calculating a bias voltage applied for the transmission of the visible light signal; Determining, by the linearity determining unit, the linearity of the transmitted visible light signal based on whether a voltage value applied with a bias voltage to the output voltage level exists within a predetermined linearity voltage section of the visible light signal; And outputting a determination result by the linearity notification unit. Characterized in that it comprises a.

According to the present invention, when a deviation of the linearity of the visible light signal is detected in the transmission device of the visible light transmission / reception system, the distortion of the visible light signal transmitted by the visible light wireless audio transmission device is adjusted by adjusting the volume of the audio player and the amplification degree of the amplification unit in the transmission device. Can be prevented conveniently.

1 is a block diagram showing the configuration of a visible light wireless audio transmission and reception system using a conventional visible light wireless communication.
FIG. 2 is a block diagram illustrating a configuration of a conventional visible light wireless audio transmitter that performs only all-optical signal conversion without using an additional electrical modulation method.
3 is a block diagram showing the configuration of a conventional visible light wireless audio transmitter for performing all-optical signal conversion after performing FM modulation.
4 is a block diagram illustrating a configuration of a conventional visible light wireless audio transmitter that performs all / optical signal conversion after performing AM modulation.
5 is a schematic diagram showing an input / output port configuration of a typical audio player.
FIG. 6 is a conceptual diagram illustrating characteristics of visible light output power compared to a typical applied voltage or current of a visible light LED or a visible light LD (laser diode) applied to a light emitting unit of a visible light wireless audio transmitter.
FIG. 7 is a block diagram illustrating a configuration of a visible light transmitting apparatus that reports linearity with respect to a general analog signal input including an audio signal according to a first embodiment of the present invention.
8 is a signal processing flowchart of determining whether the visible light emitter is out of linearity in the visible light transmitting apparatus according to the first embodiment of the present invention.
FIG. 9 is a block diagram illustrating a configuration of a visible light transmitting apparatus that reports linearity with respect to an audio signal input not using an electrical modulation method according to a second embodiment of the present invention.
FIG. 10 is a signal processing flowchart of determining whether the visible light emitter is out of linearity in the visible light audio transmission apparatus that does not use the electrical modulation method according to the second embodiment of the present invention.
Fig. 11 is a block diagram showing the configuration of a receiving apparatus for receiving a visible light audio transmission signal without using the electrical modulation method according to the second embodiment of the present invention.
12 is a block diagram showing the configuration of a visible light transmitting apparatus using the FM modulation method according to the third embodiment of the present invention.
13 is a signal processing flowchart of determining whether the visible light emitter is out of linearity in the visible light transmitting apparatus using the FM modulation method according to the second embodiment of the present invention.
14 is a block diagram showing the configuration of a receiving apparatus for receiving a visible light transmission signal using the FM modulation method according to the third embodiment of the present invention.
15 is a block diagram showing the configuration of a visible light transmitting apparatus using an AM modulation method according to a fourth embodiment of the present invention.
16 is a signal processing flowchart of determining whether the visible light emitter is out of linearity in the visible light transmitting apparatus using the AM modulation method according to the fourth embodiment of the present invention.
17 is a block diagram showing the configuration of a receiving apparatus for receiving a visible light transmission signal using the AM modulation method according to the fourth embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 7 is a diagram illustrating a configuration of a visible light transmitting apparatus informing linearity according to the first embodiment of the present invention. In the description, it will be assumed that the visible light transmitting apparatus informing linearity according to the present invention is configured to transmit an electrical analog signal as a visible light signal. In addition, in the embodiment of the present invention, but exemplified based on the voltage of the electrical signal, the linearity may be determined based on the voltage or current of the electrical signal is not limited to this.

Referring to FIG. 7, a visible light transmitting apparatus according to a first embodiment of the present invention includes a voltage level monitoring unit for monitoring an output voltage level of an amplified electrical signal and a bias voltage for calculating a bias voltage applied for transmission of a visible light signal. The calculation unit may output a determination result of the linearity determination unit and the linearity determination unit to determine the linearity of the transmitted visible light signal based on whether the voltage value applied with the bias voltage to the output voltage level is present in the linearity voltage section of the visible light signal. It comprises a linearity notification unit.

In this case, the visible light transmitting apparatus includes an analog signal amplifying unit 110 capable of receiving an analog signal and amplifying the signal, a visible light emitting unit 114 emitting visible light, an analog signal amplified by the analog signal amplifying unit 110, and And an analog signal application and a light emitter power supply 112 for outputting a bias voltage, for example, DC power, to the visible light emitter 114.

In addition, the visible light transmitting apparatus includes a linear voltage section input unit 130 for receiving a linear voltage section (see FIG. 6) corresponding to a linear light emission section of the visible light emitter 114, and a linear voltage section input unit 130 for the light emitter. And a linear voltage section storage unit 132 for storing a linear voltage section of the input visible light emitter 114.

The voltage level monitoring unit outputs from the analog signal voltage level monitoring unit 120 and the analog signal voltage level monitoring unit 120 to monitor the output voltage level including the minimum output voltage and the maximum output voltage of the analog signal amplifying unit 110. An analog signal maximum / minimum voltage level storage unit 122 that stores the voltage level.

The bias voltage calculator includes a DC bias voltage calculator 140 of a light emitter for calculating a DC bias voltage of the visible light emitter 114 based on information stored in the linear voltage section storage unit 132 of the light emitter, and a DC bias voltage of the light emitter. And a DC bias voltage storage unit 142 of the light emitting unit that stores the DC bias voltage of the visible light emitting unit 114 calculated by the calculator 140.

The linearity determiner determines whether the visible light analog signal is out of linearity based on the information stored in the analog signal maximum / minimum voltage level storage unit 122, the linear voltage section storage unit 132 of the light emitting unit, and the DC bias voltage storage unit 142 of the light emitting unit. The linearity determination unit 150 of the visible light analog signal to determine the.

In addition, the linearity notification unit includes a linearity notification unit 152 of the visible light analog signal outputting the determination result of the linearity determination unit 150 of the visible light analog signal.

In addition, the present invention includes a DC power supply unit 116 for supplying DC power to the analog signal application and the light emitting unit power supply unit 112 based on the information stored in the DC bias voltage storage unit 142 of the light emitting unit.

Here, the output voltage level of the electrical signal includes the maximum and minimum output voltages. In addition, the predetermined linear voltage range includes the maximum and minimum linear voltages (see FIG. 6). The output voltage level and the description of the predetermined linear voltage section will be described later.

Accordingly, the bias voltage calculator calculates a bias voltage from a predetermined linear voltage range in which the linearity of the visible light signal is maintained.

The linearity determiner may determine that the visible light signal is out of linearity when the sum of the maximum output voltage and the bias voltage of the electrical signal is greater than the maximum linear voltage. The linearity determination unit may determine that the visible light signal is out of linearity when the sum of the minimum output voltage and the bias voltage of the electrical signal is smaller than the minimum linear voltage. This linearity determination method will be described later.

8 is a signal processing flowchart of determining whether the visible light emitter is out of linearity in the visible light transmitting apparatus according to the first embodiment of the present invention. In the description, a detailed process of determining whether the visible light analog signal is linear will be described as an example.

As shown in FIG. 8, the linear voltage section input unit 130 emits linear voltage section information, that is, V _{LIN _ min.} And V _{LIN _ max} is input (S10), V _{LIN _ min} And V _{LIN _ max} in the linear voltage section storage unit 132 of the light emitting unit (S12). Where V _{LIN _ min} Is the minimum linear voltage, V _{LIN _ max} Is the maximum linear voltage. That is, the linear voltage section includes a section between the maximum and minimum linear voltages.

At this time, the DC bias voltage calculator 140 of the light emitting unit V _{LIN _ min} stored in the linear voltage section storage unit 132 of the light emitting unit. And V _{_} V _LIN calculate the _bias of DC bias voltage and using the _max, the DC bias voltage calculation is performed on the basis of the equation (1) to (S14). Accordingly, the bias voltage calculator calculates a median value between the linear voltage sections in which the linearity of the visible light signal is maintained as the bias voltage.

(1)

(One)

In addition, the V _bias calculated based on Equation (1) described above is stored in the DC bias voltage storage unit 142 of the light emitting unit (S16).

On the other hand, the analog signal voltage level monitoring unit 120 is a minimum output voltage, V _{Analog_min} and a maximum output voltage by monitoring V _{Analog_max} (S30), the analog signal maximum / minimum voltage from the output signal of the analog signal amplifier (110) The data is stored in the level storage unit 122 (S32). That is, the output voltage level of the electrical signal will include the voltage level between the maximum and minimum output voltage.

In this case, the linearity determination unit 150 of the visible light analog signal may include V _bias stored in the DC bias voltage storage unit 142 of the light emitting unit, V _{Analog_min} and V _{Analog_max} stored in the analog signal maximum / minimum voltage level storage unit 122, and the light emitting unit. Using V _{LIN_min} and V _{LIN_max} stored in the linear voltage section storage unit 132, it is determined whether the following Equation (2) or Equation (3) is satisfied (S20).

(2)

(2)

(3)

(3)

If the above equation is satisfied, the linearity determination unit 150 of the visible light analog signal determines that the analog signal deviates from the linearity (S22), and if not, determines that the linearity is satisfied (S24). At this time, the linearity determination unit 150 of the visible light analog signal to output the determination result through the linearity notification unit 152 of the visible light analog signal (S26). That is, in the present invention, the linearity determiner may determine that the visible light signal is out of linearity when the sum of the maximum output voltage and the bias voltage of the electrical signal is greater than the maximum linear voltage. The linearity determination unit may determine that the visible light signal is out of linearity when the sum of the minimum output voltage and the bias voltage of the electrical signal is smaller than the minimum linear voltage.

Therefore, according to the present invention, it is possible to control the magnitude of the analog signal input to the transmitter according to the result output through the linearity notification unit 152 of the visible light analog signal. For example, the user reduces the visible light communication error by adjusting the size of the analog signal input to the transmitting device according to the linearity display result of the visible light transmitting device.

In the present invention, it is preferable to vary the output voltage level of the electrical signal according to the determination result of the linearity determination unit. For example, the linearity of the visible light signal may be maintained by increasing or decreasing the output or amplification degree of the analog signal according to the determination result of the linearity determination unit.

In the present invention, it is preferable to vary the brightness of the visible light signal according to the determination result of the linearity determination unit. For example, the linearity of the visible light signal may be maintained by increasing or decreasing the brightness of the visible light signal, for example, the applied power, according to the determination result of the linearity determination unit.

As described above, according to the present invention, when deviation of the linearity of the visible light signal is detected in the transmission device of the visible light transmission / reception system, the visible light signal transmitted by the visible light transmission device is adjusted by adjusting the volume of the audio player and the amplification degree of the signal amplification unit in the transmission device. The distortion phenomenon can be conveniently prevented.

Hereinafter, other embodiments of the present invention will be described. In the second embodiment of the present invention, the visible light transmitting device informing linearity is configured to perform all / optical signal conversion without using an electrical modulation method. In the description, descriptions that overlap with the above-described embodiment will be omitted. Do it.

FIG. 9 is a block diagram illustrating a configuration of a visible light transmitting apparatus that performs all / optical signal conversion without using an electrical modulation method according to a second embodiment of the present invention.

The component according to the second embodiment of the present invention is a component for an audio signal that is not modulated in a timely manner among general analog signals, and thus, a detailed description thereof will be omitted.

In this case, the visible light transmitting apparatus receives an analog audio signal and amplifies the audio signal amplifying unit 210, the visible light emitting unit 214 emitting visible light, and the audio signal amplified by the audio signal amplifying unit 210. And an audio signal applying and light emitting unit power applying unit 212 for outputting a bias voltage, for example, DC power, to the visible light emitting unit 214.

In addition, the visible light transmitting apparatus includes a linear voltage section input unit 230 and a linear voltage section input unit 230 of the light emitting unit for receiving a linear voltage section (see FIG. 6) corresponding to the linear light emitting section of the visible light emitting unit 214. And a linear voltage section storage unit 232 for storing the linear voltage section of the input visible light emitter 214.

The voltage level monitoring unit outputs an audio signal voltage level monitoring unit 220 and an audio signal voltage level monitoring unit 220 to monitor an output voltage level including a minimum output voltage and a maximum output voltage of the audio signal amplifier 210. An audio signal maximum / minimum voltage level storage unit 222 for storing a voltage level.

The bias voltage calculator includes a DC bias voltage calculator 240 for calculating a DC bias voltage of the visible light emitter 214 based on information stored in the linear voltage section storage unit 232 of the light emitter, and a DC bias voltage of the emitter. And a DC bias voltage storage unit 242 of the light emitting unit that stores the DC bias voltage of the visible light emitting unit 214 calculated by the calculator 240.

The linearity determiner determines whether the visible light audio signal is out of linearity based on the information stored in the audio signal maximum / minimum voltage level storage unit 222, the linear voltage section storage unit 232 of the light emitting unit, and the DC bias voltage storage unit 242 of the light emitting unit. The linearity determination unit 250 of the visible light audio signal to determine the.

In addition, the linearity notifying unit includes a linearity notifying unit 252 of the visible light audio signal outputting a determination result from the linearity determining unit 250 of the visible light audio signal.

The present invention also includes a DC power supply unit 216 for supplying DC power to the audio signal applying unit and the light emitting unit power supply unit 212 based on the information stored in the DC bias voltage storage unit 242 of the light emitting unit.

FIG. 10 illustrates a detailed process of determining whether or not linearity of a visible light audio signal output from a visible light transmitting apparatus performing all / optical signal conversion without using an electrical modulation method is shown from a second embodiment of the present invention. Here, detailed processes S110 to S130 of the second embodiment correspond to S10 to S30 of the first embodiment, and thus a detailed description thereof will be omitted. _Unexplained symbol, V _{Audio_min} is the minimum audio output voltage output from the audio signal amplifier 210, V _{Audio_max} is the maximum audio output voltage output from the audio signal amplifier 210.

11 is a block diagram showing the configuration of a receiving apparatus for receiving a visible light audio transmission signal without using the electrical modulation method according to the second embodiment of the present invention. That is, the receiving device illustrated in FIG. 11 receives the visible light signal output by the visible light emitter 214 of FIG. 9 and outputs the signal through a headset or a speaker. That is, when the above-described transmission apparatus converts and transmits an electrical audio signal into a visible light signal through a light emitting element such as an LED, the visible light receiver 262 receives the visible light signal, and the photo / electric converter 264 is an electrical signal. Will be converted. The audio signal amplifier 266 amplifies this and outputs it through the headset 268 or the speaker 269.

In this case, since the method for processing the signal received through the visible light receiving apparatus is processed according to a signal processing technique used in the related art, a detailed description thereof will be omitted.

On the other hand, in the third embodiment of the present invention is a case in which the visible light transmitting device that informs linearity is configured to perform all / optical signal conversion after using the electric FM modulation method, and in the description, the first to second embodiments described above. Duplicate description with the embodiment will be omitted.

FIG. 12 is a block diagram illustrating a configuration of a visible light transmitting apparatus that performs all / optical signal conversion after using the FM modulation method according to the third embodiment of the present invention.

The components added to the third embodiment of the present invention are the audio signal FM modulator 316 and the FM modulated signal amplifier 318 according to the addition of the FM modulation function. Description is omitted.

In this case, the visible light transmitting apparatus includes an audio signal FM modulator 316 for FM modulating the output signal of the audio signal amplifier 310, an FM modulated signal amplifier 318 for amplifying a signal by receiving an FM modulated signal, Application and emission of an FM modulated signal for outputting the FM modulated signal amplified by the visible light emitter 314 and the FM modulated signal amplifier 318 and a bias voltage, for example, DC power, to the visible light emitter 314. A secondary power supply unit 312 is included.

In addition, the visible light transmitting apparatus includes a linear voltage section input unit 330 of the light emitting unit that receives a linear voltage section (see FIG. 6) corresponding to the linear light emitting section of the visible light emitting unit 314, and a linear voltage section input unit 330 of the light emitting unit. And a linear voltage section storage unit 332 for storing the linear voltage section of the input visible light emitter 314.

The voltage level monitoring unit may include an FM modulated signal voltage level monitor 320 and an FM modulated signal voltage level monitor 320 that monitor an output voltage level including a minimum output voltage and a maximum output voltage of the FM modulated signal amplifier 318. And an FM modulated signal maximum / minimum voltage level storage unit 322 for storing the output voltage level from the control unit.

The bias voltage calculator includes a DC bias voltage calculator 340 of the light emitter that calculates a DC bias voltage of the visible light emitter 314 based on information stored in the linear voltage section storage unit 332 of the light emitter, and a DC bias voltage of the light emitter. And a DC bias voltage storage unit 342 of the light emitting unit which stores the DC bias voltage of the visible light emitting unit 314 calculated by the calculator 340.

The linearity determiner determines the linearity of the visible light FM modulated signal based on the information stored in the FM modulated signal maximum / minimum voltage level storage unit 322, the linear voltage section storage unit 332 of the light emitting unit, and the DC bias voltage storage unit 342 of the light emitting unit. It includes a linearity determination unit 350 of the visible light FM modulated signal for determining whether the departure.

The linearity notifying unit includes a linearity notifying unit 352 of the visible light FM modulated signal which outputs a determination result from the linearity determining unit 350 of the visible light FM modulated signal.

In addition, the present invention includes a DC power supply unit 316 for supplying DC power to the FM modulation signal application and the light emitting unit power supply unit 312 based on the information stored in the DC bias voltage storage unit 342 of the light emitting unit.

FIG. 13 illustrates a detailed process of determining whether linearity of a visible light audio signal output from a visible light transmission apparatus performing an all / optical signal conversion after using the FM modulation method according to the third embodiment of the present invention. Here, detailed processes S210 to S230 of the third embodiment correspond to S10 to S30 of the first embodiment, and thus detailed description thereof will be omitted. _Reference numeral V _{FM_min} denotes a minimum output voltage of the FM modulated signal output from the FM modulated signal amplifier 318, and V _{FM_max} denotes a maximum output voltage of the FM modulated signal output from the FM modulated signal amplifier 318.

FIG. 14 is a block diagram showing a configuration of a receiver for receiving a visible light transmission signal using the FM modulation method according to the third embodiment of the present invention. The receiver shown in FIG. Receives the visible light signal output by the 314 to output through a headset or a speaker. That is, when the above-described transmission apparatus converts and transmits the electric FM modulated signal into a visible light signal through a light emitting device such as an LED, the visible light receiver 362 receives the visible light signal, and the photo / electric converter 364 is an electrical signal. Will be converted to. The converted FM modulated signal is demodulated by the FM modulated signal amplifying unit 365 and the FM demodulating unit 367, and the audio signal amplifying unit 366 amplifies it and outputs it through the headset 368 or the speaker 369. do.

In this case, since the method for processing the signal received through the visible light receiving apparatus is processed according to a signal processing technique used in the related art, a detailed description thereof will be omitted.

On the other hand, in the fourth embodiment of the present invention is a case where the visible light transmission device that informs linearity is configured to perform the pre / optical signal conversion after using the electrical AM modulation method, in the description, the first to third embodiments described above The description overlapping with is omitted.

FIG. 15 is a block diagram illustrating a configuration of a visible light wireless transmitter that performs all / optical signal conversion after using an AM modulation method according to a fourth embodiment of the present invention.

The components added to the fourth embodiment of the present invention are the audio signal AM modulator 416 and the AM modulated signal amplifier 418 according to the addition of the AM modulation function. Description is omitted.

In this case, the visible light transmitting apparatus includes an audio signal AM modulator 416 for AM modulating the output signal of the audio signal amplifier 410, an AM modulated signal amplifier 418 for amplifying a signal by receiving an AM modulated signal, Applied and emitted AM modulated signal for outputting the AM modulated signal amplified by the visible light emitter 414 and AM modulated signal amplifier 418 and the bias voltage, for example, DC power, to the visible light emitter 414. A secondary power supply unit 412 is included.

In addition, the visible light transmitting apparatus includes a linear voltage section input unit 430 of the light emitting unit that receives a linear voltage section (see FIG. 6) corresponding to the linear light emitting section of the visible light emitting unit 414, and a linear voltage section input unit 430 of the light emitting unit. A linear voltage section storage unit 432 of the light emitting unit for storing the linear voltage section of the input visible light emitting unit 414 is included.

The voltage level monitoring unit includes an AM modulated signal voltage level monitoring unit 420 and an AM modulated signal voltage level monitoring unit 420 for monitoring an output voltage level including a minimum output voltage and a maximum output voltage of the AM modulated signal amplifying unit 418. AM modulated signal maximum / minimum voltage level storage 422 for storing an output voltage level from the control circuit.

The bias voltage calculator includes a DC bias voltage calculator 440 of the light emitter that calculates a DC bias voltage of the visible light emitter 414 based on information stored in the linear voltage section storage 432 of the light emitter, and a DC bias voltage of the light emitter. And a DC bias voltage storage unit 442 of the light emitting unit that stores the DC bias voltage of the visible light emitting unit 414 calculated by the calculator 440.

The linearity determiner determines the linearity of the visible light AM modulated signal based on information stored in the AM modulated signal maximum / minimum voltage level storage unit 422, the linear voltage section storage unit 432 of the light emitting unit, and the DC bias voltage storage unit 442 of the light emitting unit. It includes a linearity determination unit 450 of the visible light AM modulated signal for determining whether the deviation.

The linearity notifying unit includes a linearity notifying unit 452 of the visible light AM modulated signal which outputs a determination result from the linearity determining unit 450 of the visible light AM modulated signal.

In addition, the present invention includes a DC power supply unit 416 for supplying DC power to the AM modulation signal application and the light emitting unit power supply unit 412 based on the information stored in the DC bias voltage storage unit 442 of the light emitting unit.

FIG. 16 illustrates a detailed process of determining whether or not linearity of a visible light audio signal output from a visible light transmitting apparatus performing an all / optical signal conversion after using the AM modulation method from the fourth embodiment of FIG. Here, detailed processes S310 to S330 of the fourth embodiment correspond to S10 to S30 of the first embodiment, and thus detailed description thereof will be omitted. _Unexplained symbol, V _{AM_min} is the minimum output voltage of the AM modulated signal output from the AM modulated signal amplifier 418, V _{AM _ max} Denotes an AM modulated signal maximum output voltage output from the AM modulated signal amplifier 418.

FIG. 17 is a block diagram illustrating a configuration of a receiver for receiving a visible light transmission signal using an AM modulation method according to a fourth embodiment of the present invention. In the receiver shown in FIG. 17, the visible light emitter 414 of FIG. Receives the visible light signal output by the to output through a headset or a speaker. That is, when the above-described transmission apparatus converts the electrical AM modulation signal into a visible light signal through a light emitting device such as an LED and transmits the visible light signal, the visible light receiver 462 receives the visible light signal, and the photo / electric converter 464 transmits the electrical signal. Will be converted to. The converted AM modulated signal is demodulated by the AM modulated signal amplifier 465 and the AM demodulator 467, and the audio signal amplifier 466 amplifies it and outputs it through the headset 468 or the speaker 469. do.

In this case, since the method for processing the signal received through the visible light receiving apparatus is processed according to a signal processing technique used in the related art, a detailed description thereof will be omitted.

As described above, the apparatus and method for transmitting the visible light according to the present invention may not be limitedly applied to the configuration and method of the embodiments described as described above, but the embodiments may be modified in various ways so that various modifications may be made. All or part of the examples may be optionally combined.

110: analog signal amplifier
112: analog signal application and light emitting unit power supply unit
114: visible light emitting portion
116: DC power supply
120: analog signal voltage level monitoring unit
122: analog signal maximum / minimum voltage level storage
130: linear voltage section input unit of the light emitting unit
132: linear voltage section storage unit of the light emitting unit
140: DC bias voltage calculation unit of the light emitting unit
142: DC bias voltage storage unit of the light emitting unit
150: linearity determination unit of the visible light analog signal
152: linearity notification unit of the visible light analog signal

Claims (20)

A visible light transmitting device that converts an electrical signal into a visible light signal and transmits the same.
A voltage level monitoring unit for monitoring an output voltage level of the electrical signal;
A bias voltage calculator configured to calculate a bias voltage applied to transmit the visible light signal;
A linearity determination unit determining the linearity of the visible light signal transmitted based on whether a voltage value of applying the bias voltage to the output voltage level is present within a predetermined linear voltage section of the visible light signal; And
And a linearity notification unit for outputting a determination result of the linearity determination unit. The method according to claim 1,
And the output voltage level of the electrical signal includes a maximum and minimum output voltage. The method according to claim 2,
And said predetermined linear voltage section includes a maximum and minimum linear voltage. The method according to claim 1,
The bias voltage calculator,
And the bias voltage is calculated from the predetermined linear voltage range in which the linearity of the visible light signal is maintained. The method according to claim 3,
The linearity determination unit,
And determining that the visible light signal is out of linearity when the sum of the maximum output voltage and the bias voltage of the electrical signal is greater than the maximum linear voltage. The method according to claim 5,
The linearity determination unit,
And when the sum value of the minimum output voltage and the bias voltage of the electrical signal is less than the minimum linear voltage, the linear light deviation apparatus determines the linearity deviation of the visible light signal. The method according to claim 1,
Further comprising an amplifier for amplifying the electrical signal,
And the amplifying unit changes the output voltage level of the electrical signal according to a determination result of the linearity determining unit. The method according to claim 1,
Further comprising a visible light emitting unit for generating the visible light signal,
The visible light emitting unit is a visible light transmitting device for indicating the linearity, characterized in that for varying the brightness of the visible light signal according to the determination result of the linearity determination unit. The method according to claim 1,
And said electrical signal is an FM modulated signal. The method according to claim 1,
And said electrical signal is an AM modulated signal. The method according to claim 1,
And said electrical signal is an unmodulated signal. A visible light transmission method for converting an electrical signal into a visible light signal and transmitting the same,
Monitoring, by a voltage level monitoring unit, an output voltage level of the electrical signal;
Calculating a bias voltage applied by the bias voltage calculator to transmit the visible light signal;
Determining, by the linearity determining unit, the linearity of the visible light signal transmitted based on whether a voltage value applying the bias voltage to the output voltage level is present within a predetermined linearity voltage section of the visible light signal; And
Outputting, by the linearity notifier, the determination result; Visible light transmission method for telling the linearity, characterized in that it comprises a. The method of claim 12,
And the output voltage level of the electrical signal includes a maximum and minimum output voltage. The method according to claim 13,
And the predetermined linear voltage section includes a maximum and minimum linear voltage. The method of claim 12,
Computing the bias voltage,
And the bias voltage is calculated from the predetermined linear voltage range in which the linearity of the visible light signal is maintained. The method according to claim 14,
Determining the linearity,
And determining the deviation of the linearity of the visible light signal when the sum of the maximum output voltage and the bias voltage of the electrical signal is greater than the maximum linear voltage. The method according to claim 16,
Determining the linearity,
And when the sum of the minimum output voltage and the bias voltage of the electrical signal is less than the minimum linear voltage, determining the deviation of the linearity of the visible light signal. The method of claim 12,
The amplifier further comprises amplifying the electrical signal,
The amplifying step, the visible light transmission method for indicating the linearity, characterized in that for varying the output voltage level of the electrical signal in accordance with the determination result. The method of claim 12,
The visible light emitting unit further comprises the step of generating the visible light signal,
The generating of the visible light signal may include: varying the luminance of the visible light signal according to the determination result. The method of claim 12,
And said electrical signal is a modulated signal.

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