KR20050040279A - Method and apparatus for saving a power in infra red data association communication - Google Patents

Abstract

The present invention relates to a power-saving infrared communication method and apparatus configured to prevent waste of power due to infrared communication by varying transmission power of an infrared signal according to a separation distance between two devices that transmit and receive an infrared signal.

When the infrared main unit 210 transmits a transmission infrared signal and receives a response infrared signal from the infrared external device 120, the infrared main unit is determined to determine the strength of the response infrared signal so that the transmission infrared signal is equal to the strength of the response infrared signal. Automatically adjust the resistance value at 210, characterized in that the transmission power of the transmission infrared signal is variable,

According to the present invention, the transmission power is automatically adjusted according to the separation distance of the two devices for transmitting and receiving the infrared signal, it is possible to prevent the waste of power due to the transmission and reception of the infrared signal. In addition, when a device for transmitting infrared signals uses a battery, it may increase the use time of the battery in the long term.

Description

Power-saving infrared communication method and apparatus {Method and Apparatus for Saving a Power in Infra Red Data Association Communication}

The present invention relates to a power-saving infrared communication method and device, and more preferably, by varying the transmission power of the infrared signal according to the separation distance between the two devices for transmitting and receiving the infrared signal, it is possible to prevent waste of power due to infrared communication It relates to a power-saving infrared communication method and apparatus configured to be.

Technology for transmitting and receiving data using infrared rays has been actively applied to wireless communication devices including mobile communication terminals. Infrared communication mainly uses infrared light emitting diodes, which may be installed in computers, printers, and mobile terminals to establish wireless communication connections between these devices. For example, when the contents of the facsimile or e-mail are stored in the mobile terminal, the user points the printer to the mobile terminal to issue an output command, and the printer outputs a hard copy from the mobile terminal according to the output command by infrared communication. Frequently called numbers may be downloaded from the mobile terminal to the computer or vice versa.

1 is a configuration diagram schematically showing the configuration of a two-way infrared communication device 100 between two conventional devices.

The conventional two-way infrared communication device 100 transmits an infrared signal according to a user's input, or receives an infrared signal from the infrared main unit 110, the infrared main unit 110 to receive the infrared signal from the outside, or performs the operation accordingly It is composed of an infrared external device 120 for transmitting a response signal to the infrared main device 110 as an infrared signal.

The infrared main unit 110 includes an infrared control unit 112 for transmitting a user's input command as a command signal, and an infrared module unit 114 for generating and transmitting an infrared signal according to a command signal applied from the infrared control unit 112. do. As shown in FIG. 1, the infrared module unit 114 is connected to an infrared power source (IRDA Vcc) for supplying power for transmitting and receiving an infrared signal to one side, and to the other side through another current limiting resistor (R). The power supply (IRDA Vcc) is connected.

That is, in the conventional bidirectional infrared communication device 100 configured as described above, when a user inputs an arbitrary command for infrared communication, the infrared control unit 112 controls the infrared module unit 114 in the infrared mode (IR_SD_MODE) to make a command. The infrared signal according to the transmission to the infrared external device 120. Accordingly, the infrared external device 120 emits a response infrared signal according to the infrared signal transmitted from the infrared main apparatus 110 or performs an operation according to the received infrared signal. The response infrared signal transmitted from the infrared external device 120 is received by the infrared module unit 114 and applied to the infrared control unit 112.

In the conventional two-way infrared communication device 100 operating in the above process, the infrared signal is operated at the maximum power by the current control resistor (R) provided in the infrared module unit 114 to transmit the maximum range. . Therefore, since the value of the current control resistor R is set to be constant so that infrared communication can be performed at a maximum distance irrespective of the separation distance between the infrared main unit 110 and the infrared external device 120, the infrared main unit 110 and the infrared unit 110 are infrared rays. Even when the external device 120 is near, the infrared signal is transmitted at the maximum power. Accordingly, even though the two devices are in a short range, waste of power occurs due to transmission and reception with an infrared signal at maximum power, and there is a problem of reducing the battery usage time in the long term.

The present invention for solving the above problems, by varying the transmission power of the infrared signal according to the separation distance between the two devices for transmitting and receiving the infrared signal, power-saving infrared communication method configured to prevent waste of power due to infrared communication And to provide a device.

In order to achieve the above object, the present invention is a power-saving infrared communication device for varying the resistance value to vary the transmission power of the infrared signal, receiving the infrared signal and performing the operation according to the response, or response corresponding to the infrared signal An infrared external device for transmitting an infrared signal; Receives the response infrared signal from the infrared external device to detect the intensity level of the response infrared signal, and automatically adjusts the resistance value according to the detected intensity level of the response infrared signal to control the power output of the infrared signal. It provides a power-saving infrared communication device, characterized in that it comprises an infrared main unit.

In addition, according to a second object of the present invention, a power-saving infrared communication device that varies the transmission power of the infrared signal according to the separation distance between the two devices for transmitting and receiving the infrared signal, the infrared control unit for transmitting the user's input command as a command signal ; Transmitting the infrared signal corresponding to the command signal applied from the infrared control unit to an infrared external device, receiving a response infrared signal from the infrared external device, detecting an intensity level of the received infrared signal, and detecting the resistance An infrared transmitting / receiving unit for varying an output power of the infrared signal according to a value; And a microcontroller configured to receive the intensity level of the response infrared signal from the infrared transceiver and apply a resistance value corresponding to the intensity level of the response infrared signal to the infrared transceiver. To provide.

In addition, according to a third object of the present invention, there is provided a power-saving infrared communication method for varying the transmission power of an infrared signal according to a separation distance between two devices for transmitting and receiving an infrared signal, the method comprising: transmitting an infrared signal according to a user's input command; Stage 1; A second step of receiving a response infrared signal from an external device receiving the infrared signal; Determining a strength level of the response infrared signal; And a fourth step of varying the transmission power of the infrared signal to a resistance value corresponding to the intensity level of the response infrared signal.

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

First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings.

In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

2 is a configuration diagram schematically showing the configuration of a power-saving infrared communication device 200 according to an embodiment of the present invention.

The power saving infrared communication device 200 according to the present invention includes, for example, an infrared main device 210 such as a computer, a printer, a mobile terminal, and the like; It is composed of an infrared external device 120 for transmitting and receiving an infrared signal with the infrared main device (210).

The infrared main unit 210 receives an infrared signal from the infrared external device 120 to detect a level of the infrared signal, converts the signal into an appropriate resistance value according to the detected level of the infrared signal, and resistance of the power variable resistor VR. By varying the value to the converted resistance value, the transmission power of the infrared signal is controlled to vary according to the separation distance of the infrared external device 120.

The infrared main unit 210 has a configuration including an infrared control unit 112, an infrared transceiver 220, and a microcontroller 230.

The infrared transceiver 220 may change the resistance value of the power variable resistor VR according to the resistance value control of the microcontroller 230, and the microcontroller 230 may control the infrared signal received from the infrared external device 120. The intensity level is detected, and a resistance value corresponding to the detected intensity level of the infrared signal is applied to the infrared transceiver unit 220 so that the infrared transceiver unit 220 adjusts the resistance value of the power variable resistor VR according to the resistance value. By adjusting, it controls so that the transmission power of an infrared signal may vary.

The infrared transceiver 220 generally includes a buffer 222 that actually drives the infrared light emitting diode (IRED) 242. In the infrared transceiver 220, the IRED 242 is connected to the supply voltage V _cc through the power variable resistor VR. The power variable resistor VR has a variable resistance value according to a resistance signal applied from the microcontroller 230.

Infrared communication by the infrared transmitter / receiver 220 transmits an infrared signal by the IRED 242 to a PIN photodiode 244 connected to the amplifier 228 and the analog-to-digital (A / D) converter 226. Infrared signals are received from the outside.

The PIN photodiode 244 is normally inverse biased by the bias 224, whereby the current flowing through the PIN photodiode 244 is proportional to the infrared photon λ received from the infrared external device 120. . The infrared signal in analog form is converted into a digital signal, pulse train or code interpreted by IRDA in the A / D converter 226.

The infrared external device 120 generally constitutes a circuit corresponding to the infrared main device 210 including an IRED 246 and a PIN photodiode 248.

FIG. 3 is a graph showing current I _IRED through IRED 242 and power P _IRED (λ) emitted as infrared radiation by IRED 242.

In Figure 3, curve I represents the current and curve P represents the optically emitted power. As shown in Fig. 3, the output (luminance) of current I and power P both increase with voltage until the current reaches a very high level, and at the maximum rising level, heat decreases in quantum efficiency. Results in. IRED then degrades efficiency and light emission, and reduces optical power output. The current I increases more slowly because the resistance in the infrared mains 210 becomes very large. Therefore, according to the embodiment of the present invention, the power variable resistor VR is automatically changed by the control of the microcontroller 230 so that its power is also variable.

The optimum operating voltage changes in relation to the ambient temperature, with higher temperatures decreasing the optimum voltage and lower temperatures increasing the optimum voltage. This change can be hundreds of millivolts (± 200 Hz) at nominal or room temperature. Diodes made of various materials or of a layer can have different turn-on voltages and can produce different infrared spectra.

Next, a power saving type infrared communication method according to an embodiment of the present invention will be described with reference to the flowchart shown in FIG. 4.

First, when an arbitrary command is input by the user through the user interface (User_Interface) in the infrared main unit 210, the infrared control unit 112 transmits a command signal to the infrared transceiver unit 220 according to the input command.

The infrared transceiver 220 transmits a command signal to the IRED 242 via the buffer 222, thereby transmitting a transmission infrared signal corresponding to the command signal from the IRED 242 to the infrared external device 120 (S402). ).

The transmission infrared signal transmitted from the infrared main unit 210 is received by the PIN photodiode 248 of the infrared external device 120, and the infrared external device 120 performs an operation corresponding to the transmission infrared signal or transmits infrared light. In response to the signal, a response infrared signal indicating the result is sent to the infrared main unit 210 through the IRED 246.

The infrared main device 210 receives the response infrared signal transmitted from the infrared external device 120 through the PIN photodiode 244 of the infrared transceiver 220 (S404).

The reverse photo bias is applied to the PIN photodiode 244 of the infrared ray transceiver 220 by the bias 224, whereby the current flowing through the PIN photodiode 244 is a response infrared ray received from the infrared external device 120. It is proportional to the strength of the signal. Accordingly, the photoelectric response infrared signal operates the PIN photodiode 244 so that a current flows, and the magnitude of the current amount increases when the intensity level of the response infrared signal is high and decreases when the intensity level is low.

The analogue response infrared signal is amplified by the amplifier 228 and converted into digital data by the A / D converter 226. That is, the current value is converted into digital data by the A / D converter 226 by the received response infrared signal.

The current value for the response infrared signal is transmitted to the microcontroller 230, and the microcontroller 230 determines the intensity level of the response infrared signal as the current value for the response infrared signal (S406).

Subsequently, the microcontroller 230 may adjust the power variable resistor (ie, the current value flowing through the IRED 242 of the infrared transceiver 220 according to the intensity level of the response infrared signal, that is, the current value of the response infrared signal). The resistance value for adjusting the VR is transmitted to the infrared transceiver 220 (S408).

The infrared ray transmitting and receiving unit 220 adjusts the resistance value of the power variable resistor VR according to the resistance value applied from the microcontroller 230, so that the current value flowing through the IRED 242 flows through the PIN photodiode 244. Make it equal to the value. Accordingly, the transmission infrared signal is transmitted from the IRED 242 by the power according to the variable resistance value of the power variable resistor VR (S410). Therefore, the intensity of the response infrared signal transmitted from the infrared external device 120 and the intensity of the transmission infrared signal transmitted from the infrared main device 210 become the same, and the power consumption is reduced in the infrared main device 210, thereby wasting power. Will be able to prevent.

According to an embodiment of the present invention, the power-saving infrared communication method and apparatus configured to prevent the waste of power due to infrared communication by varying the transmission power of the infrared signal according to the separation distance between the two devices for transmitting and receiving infrared signals Can be realized.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments.

The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, the transmission power is automatically adjusted according to the separation distance between the two devices transmitting and receiving the infrared signal, it is possible to prevent the waste of power due to the transmission and reception of the infrared signal. In addition, when a device for transmitting infrared signals uses a battery, it may increase the use time of the battery in the long term.

1 is a configuration diagram schematically showing the configuration of a two-way infrared communication device 100 between two conventional devices,

2 is a configuration diagram schematically showing the configuration of a power-saving infrared communication device 200 according to an embodiment of the present invention;

3 is a graph showing the current I _IRED through IRED 242 and the power P _IRED (λ) emitted as infrared radiation by IRED 242,

4 is a flowchart illustrating a power-saving infrared communication method according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: bidirectional infrared communication device 110: infrared main device

112: infrared control unit 114: infrared module unit

120: infrared external device 200: power-saving infrared communication device

210: infrared main unit 220: infrared transceiver

222: buffer 224: bias

226: A / D converter 228: amplifier

230: microcontrollers 242, 246: IRED

244, 248: PIN photodiode IRDA Vcc: infrared power

R: Current limiting resistor VR: Power variable resistor

Claims (9)

A power-saving infrared communication device for varying a resistance value to vary the power output of an infrared signal, An infrared external device that receives the infrared signal and performs an operation according to it, or transmits the infrared signal as a response infrared signal corresponding to the infrared signal; Receives the response infrared signal from the infrared external device to detect the intensity level of the response infrared signal, and automatically adjusts the resistance value according to the detected intensity level of the response infrared signal to control the power output of the infrared signal. Power-saving infrared communication device comprising an infrared main unit. The method of claim 1, The infrared main unit, An infrared control unit transmitting a user's input command as a command signal; The infrared signal is generated according to the command signal applied from the infrared controller, or the response infrared signal transmitted from the infrared external device is received, the intensity level of the received response infrared signal is detected, and the applied An infrared transmitting / receiving unit for varying an output power of the infrared signal according to a resistance value; And And a microcontroller for determining a strength level of the response infrared signal and applying a resistance value corresponding to the strength level of the response infrared signal to the infrared transceiver. The method of claim 2, The infrared transceiver, The infrared signal is transmitted by adjusting the resistance value of the power variable resistor VR according to the resistance value applied from the microcontroller so that the current value flowing through the infrared light emitting diode IRD is equal to the current value flowing through the photodiode. A power saving infrared communication device, characterized in that the power is variable. The method of claim 3, wherein The microcontroller may be configured to adjust the power variable resistor VR to adjust the power variable resistance VR to be equal to a current value flowing through the infrared transceiver unit according to the response infrared signal, and a current value flowing through the infrared light emitting diode IRD. Power saving infrared communication device, characterized in that for transmitting to the infrared transceiver. The method of claim 4, wherein The microcontroller may determine the magnitude of the current value as the magnitude of the current value flowing through the photodiode of the infrared transceiver is increased or decreased according to the intensity of the response infrared signal received from the infrared external device. Power-saving infrared communication device. A power-saving infrared communication device for varying the transmission power of the infrared signal according to the separation distance between the two devices that transmit and receive the infrared signal, An infrared control unit transmitting a user's input command as a command signal; Transmitting the infrared signal corresponding to the command signal applied from the infrared control unit to an infrared external device, receiving a response infrared signal from the infrared external device, detecting an intensity level of the received infrared signal, and detecting the resistance An infrared transmitting / receiving unit for varying an output power of the infrared signal according to a value; And And a microcontroller configured to receive an intensity level of the response infrared signal from the infrared transceiver and apply a resistance value corresponding to the intensity level of the response infrared signal to the infrared transceiver. A power-saving infrared communication method for varying the transmission power of the infrared signal according to the separation distance between the two devices that transmit and receive the infrared signal, A first step of transmitting an infrared signal according to a user's input command; A second step of receiving a response infrared signal from an external device receiving the infrared signal; Determining a strength level of the response infrared signal; And And a fourth step of varying the transmission power of the infrared signal to a resistance value corresponding to the intensity level of the response infrared signal. The method of claim 6, In the third step, the magnitude of the current value flowing through the photodiode of the infrared transceiver which transmits the infrared signal or receives the response infrared signal is increased or decreased according to the strength of the response infrared signal received from the external device. Power saving infrared communication method characterized in that the judging by the magnitude of the current value. The method of claim 7, wherein In the fourth step, the infrared transmitter / receiver adjusts the resistance value of the power variable resistor (VR) according to a resistance value applied from the microcontroller to determine the intensity level of the response infrared signal to the infrared transceiver. A power-saving infrared communication method, characterized in that the output power of the infrared signal is varied by making the current value flowing through the diode (IRED) equal to the current value flowing through the photodiode.