KR101493049B1 - Asynchronous data transmission equipment and the effectiveness decision method that use optical sensor - Google Patents

Abstract

The present invention provides an asynchronous data transmission apparatus using an optical sensor and a transmission method thereof. The present invention is configured to decide a high/low state by the brightness of a light source at a receiving side terminal, receiving asynchronous data with a periodic, namely, random pulse width, from a transmission side terminal via optical communications; and to discriminate bits of the asynchronous data via a validation process in accordance with a signal detection of a rising edge or a falling edge, thereby easily deciding whether the received asynchronous data is data with effectiveness and also enhancing transmission and reception efficiency of the asynchronous data in accordance with the optical communications while more smoothly realizing data transmission and reception between terminals which make optical communications.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an asynchronous data transmission apparatus using an optical sensor,

The present invention relates to a technique for transmitting asynchronous data using an optical sensor, and more particularly to a technique for transmitting asynchronous data using an optical sensor. More particularly, the present invention relates to a technique for transmitting asynchronous data using optical sensors, In the process, when a transmitting terminal transmits asynchronous data having an aperiodic, i.e., a random pulse width, the receiving terminal can easily determine whether the receiving terminal has valid data through a verification process To an asynchronous data transmission apparatus and a validity determination method.

Generally, the optical communication system of a terminal using a light source (e.g., a mobile terminal, a smart device such as a smart phone and a tablet PC, a smart watch, etc.) constitutes a transmitter (light emitting unit) and a receiver (optical sensor) It uses a dedicated chip (Remote Control Chip) to transmit and receive low-speed data through optical communication.

For example, a plurality of terminals (for example, a mobile communication terminal) constituting a transmitting unit (light emitting unit) and a receiving unit (optical sensor), respectively, are disclosed in Japanese Laid-Open Patent Publication No. 10-2004-0015520 (Smart phone) equipped with a light sensor (illuminance sensor) and a terminal equipped with a light source (for example, a smart watch) can transmit and receive data at low speed through an optical communication, Wireless communication for transmitting and receiving asynchronous data at a low speed can be performed without an additional device.

However, in the conventional optical communication systems, it is possible to analyze the asynchronous data transmitted from the transmitting terminal by determining the pulse width to be high or low when transmitting and receiving asynchronous data, When the asynchronous data having the non-periodic, that is, the rampant pulse width is transmitted, the receiving side terminal not only detects the bit of the received asynchronous data but also generates an error in judgment of high or low, The data can not be transmitted and received between the terminals smoothly.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide an asynchronous data transmission method and an asynchronous data transmission method, The bits of the asynchronous data are discriminated through the verification procedure according to the signal detection of the rising edge or the falling edge so that the asynchronous data can be easily judged whether or not the received asynchronous data is valid data It is an object of the present invention to provide an asynchronous data transmission apparatus and an effectiveness determination method using an optical sensor that can smoothly transmit and receive data between terminals that perform optical communication.

According to an aspect of the present invention, there is provided an asynchronous data transmission apparatus using an optical sensor, wherein asynchronous data is transmitted and received between a transmitting terminal equipped with an optical transmitter and a receiving terminal equipped with a light receiver, A first central processing unit for generating asynchronous data having an aperiodic pulse width to be transmitted through the optical communication, and a second central processing unit for generating asynchronous data having an aperiodic pulse width corresponding to high or low And the light receiving unit receives the light source through the light receiving unit and detects a light amount signal from the electric signal when converting into an electric signal. And a light quantity detection unit An edge detector for detecting a rising edge or a falling edge of the asynchronous data and a light amount signal detected from the light amount detector to a light amount threshold value to determine a high or low level of an aperiodic pulse width of the asynchronous data, A second central processing unit for comparing the illumination value of the signal with the illumination threshold value and discriminating the bits of the asynchronous data according to the rising edge or the folding edge detected from the edge detecting unit and determining the validity of the asynchronous data having the non- .

The asynchronous data having the non-periodic pulse width is determined to be high if the light amount signal is equal to or greater than the light amount threshold value in the second central processing unit. If the light amount signal is smaller than the light amount threshold value, the asynchronous data having the non- And a first determination program for determining that the determination is low.

In the second central processing unit, the light amount signal of the asynchronous data having the non-periodic pulse width exceeds the illumination threshold value and the rising edge or the falling edge of the asynchronous data having the non-periodic pulse width exceeding the illumination threshold value, And a second judgment program for distinguishing bits of data.

Meanwhile, the asynchronous data validity determination method implemented by the asynchronous data transmission apparatus using the optical sensor transmits asynchronous data having the aperiodic pulse width through the optical communication in the transmitting terminal, and when receiving the asynchronous data, A first step of detecting a bit light quantity signal of the light source; A second step of determining whether a bit light quantity signal of the asynchronous data detected from the first step exceeds an illumination threshold value; A third step of discriminating and counting bits of asynchronous data from the rising edge or the falling edge of the asynchronous data exceeding the illumination threshold value, when the bit light quantity signal of the asynchronous data exceeds the illumination threshold value as a result of the second step; A fourth step of determining whether the bit light amount signal of the asynchronous data counted from the third step exceeds the light amount threshold value; And if the bit light amount signal of the asynchronous data is greater than or equal to the light amount threshold value, the bit of the asynchronous data is determined to be high. If the bit light amount signal of the asynchronous data is less than the light amount threshold value, Determining whether the asynchronous data having the non-periodic pulse width is data having validity while judging to be low; .

As described above, according to the present invention, even if asynchronous data having an aperiodic or random pulse width is transmitted by optical communication in the transmitting terminal, the receiving terminal that receives the asynchronous data through the optical communication determines high / low with the brightness of the light source, The bits of the asynchronous data are distinguished through a verification procedure according to the signal detection of the rising edge or the falling edge. It is possible to easily judge whether the received asynchronous data is valid data or not, It is expected that the efficiency of transmission and reception of asynchronous data due to optical communication can be enhanced while data transmission and reception can be performed more smoothly.

1 is a block diagram of an asynchronous data transmission apparatus using an optical sensor according to an embodiment of the present invention.
2 is a waveform diagram of asynchronous data having an aperiodic pulse width according to an embodiment of the present invention;
3 is a flow chart showing validity of asynchronous data (8 bits) using an optical sensor according to an embodiment of the present invention.

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

FIG. 1 is a block diagram of an asynchronous data transmission apparatus using an optical sensor according to an embodiment of the present invention, and FIG. 2 is a waveform diagram of asynchronous data having an aperiodic pulse width according to an embodiment of the present invention.

1 and 2, an asynchronous data transmission apparatus using an optical sensor according to an embodiment of the present invention includes an optical transmission unit 11, a first central processing unit 12, and a light amount generating unit 13 (For example, a smart terminal) including a transmitting side terminal (e.g., a smart watch) 10 including a light receiving portion 21 and a light amount detecting portion 22, an edge detecting portion 23 and a second central processing portion 24. [ Phone, and tablet PC) 20 can transmit and receive asynchronous data having an aperiodic pulse width by optical communication with each other.

That is, the first central processing unit 12 included in the transmitting terminal 10 is configured to generate asynchronous data having an aperiodic pulse width to be transmitted through the optical communication and then transmit the asynchronous data to the light amount generating unit 13, The light amount generator 13 generates a light source that adjusts a light amount corresponding to a high or low level of asynchronous data having an aperiodic pulse width generated from the first central processing unit 12, To the receiving side terminal (20).

The light receiving unit 21 included in the receiving terminal 20 receives the light source through the optical communication unit 11 in the optical transmitter 11 of the transmitting terminal 10 and transmits the received light source to an electric signal And transmits it to the light amount detecting unit 22.

The light amount detection unit 22 detects a light amount signal from a light source that is converted into an electrical signal through the light reception unit 21 and then transmits the detected light amount signal to the edge detection unit 23 and the second central processing unit 24 .

The edge detector 23 detects a rising edge or a falling edge of the light amount signal detected by the light amount detector 22 and then transmits the detection signal to the second central processor 24 .

The second central processing unit 24 compares the light amount signal detected from the light amount detecting unit 22 with a light amount threshold value (Threshold_HL) to determine a high or low level of an aperiodic pulse width of asynchronous data, (R) or a polling edge detected from the edge detector (23) while comparing the illuminance value of the light amount signal detected from the illuminance detector (22) with the illuminance threshold value (Threshold_B) The validity of the asynchronous data having the pulse width is judged, and the first and second judgment programs are installed for the judgment.

That is, as shown in FIG. 2, the first determination program determines asynchronous data having an aperiodic pulse width as high if the light amount signal is equal to or greater than the light amount threshold value (Threshold_HL), and outputs the light amount signal as a light amount threshold value Threshold_HL), the asynchronous data having the non-periodic pulse width can be determined to be low.

2, the second determination program determines whether or not the light amount signal of the asynchronous data having the non-periodic pulse width exceeds the illumination threshold value (Threshold_B) and the non-periodic pulse width exceeding the illumination threshold value Is to distinguish the rising edge of asynchronous data (RE) or bits of asynchronous data from the polling edge.

1 to 3, the first central processing unit 12 of the transmitting terminal 10 generates asynchronous data having an aperiodic pulse width and supplies the asynchronous data to the light amount generating unit 13 The light amount generator 13 determines the high / low level of the asynchronous data, adjusts the light amount of the asynchronous data according to the determination, and transmits the asynchronous data to the light receiving unit (not shown) of the receiving terminal 20 through the light transmitting unit 11 21).

Then, as a first step, the light reception unit 21 included in the reception-side terminal 20 converts the light source of the received asynchronous data into an electrical signal and transmits it to the light amount detection unit 22,

The light amount detecting unit 22 detects a bit light amount signal of the asynchronous data converted into an electrical signal, and transmits the signal to the edge detecting unit 23 and the second central processing unit 24.

Then, as the second step, the second judgment program of the second central processing unit 24 judges whether the bit light quantity signal of the asynchronous data detected from the light quantity detecting unit 22 exceeds the illumination threshold value (Threshold_B) .

As a third step, in the second determination program of the second central processing unit 24, the bit light quantity signal of the asynchronous data exceeds the illumination threshold value (Threshold_B) and the rising of the bit light quantity signal exceeding the illumination threshold value When the edge RE or the polling edge is detected from the edge detecting unit 23, the bit of the asynchronous data can be distinguished.

As a fourth step, the first judgment program of the second central processing unit 24 judges whether the bit light amount signal of the asynchronous data judged and distinguished from the second judgment program exceeds the light amount threshold value (Threshold_HL) .

If the bit light amount signal of the asynchronous data is greater than or equal to the light amount threshold value (Threshold_HL) in the first determination program of the second central processing unit 24 as shown in FIG. 2, the asynchronous data The asynchronous data having the non-periodic pulse width is determined to be low when the bit light quantity signal of the asynchronous data is less than the light quantity threshold Threshold_HL as shown in FIG. 2, The asynchronous data having the non-periodic pulse width is finally recognized as valid data from the determination result after finally determining whether the data has validity.

While the present invention has been described in connection with certain exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is to be understood that such changes and modifications are within the scope of the claims.

10; A transmitting side terminal 11; The optical transmitter
12; A first central processing unit 13; The light-
20; A receiving side terminal 21; Light receiver
22; A light amount detecting unit 23; The edge detector
24; The second central processing unit

Claims (4)

Wherein the asynchronous data is transmitted and received between the transmitting-side terminal equipped with the optical transmitting unit and the receiving-side terminal provided with the optical receiving unit, and the asynchronous data is transmitted to the transmitting- Generating a light source that adjusts a light amount corresponding to a high or a low level of asynchronous data having an aperiodic pulse width generated from the first central processing unit and transmits the light source through the optical transmission unit A light amount detection unit configured to detect a light amount signal from the electric signal when the light source is received through the light reception unit and converted into an electrical signal, and a light amount detection unit configured to detect a light amount signal, An edge detection unit for detecting a falling edge, and a second central processing unit And,
The asynchronous data having an aperiodic pulse width is judged to be high if the light quantity signal detected from the light quantity detecting section is equal to or greater than the light quantity threshold value, A first determination program for determining asynchronous data having a low level of the asynchronous data; And a rising edge or a falling edge of asynchronous data having an aperiodic pulse width exceeding the illumination threshold value exceeding the illumination threshold value, wherein the light amount signal of the asynchronous data having the aperiodic pulse width detected by the light amount detection section exceeds the illumination threshold value, A second judgment program for judging the validity of the asynchronous data having the non-periodic pulse width by distinguishing the bits of the asynchronous data from the detected rising edge or the falling edge upon detection from the edge detecting section; Asynchronous data transfer apparatus using an optical sensor. delete delete A first step of transmitting asynchronous data having an aperiodic pulse width through an optical communication in a transmitting side terminal and detecting a bit light amount signal of asynchronous data upon receiving by the receiving side terminal;
A second step of determining whether a bit light quantity signal of the asynchronous data detected from the first step exceeds an illumination threshold value;
A third step of discriminating and counting bits of asynchronous data from the rising edge or the falling edge of the asynchronous data exceeding the illuminance threshold value when the bit light quantity signal of the asynchronous data exceeds the illumination threshold value as a result of the second step;
A fourth step of determining whether the bit light amount signal of the asynchronous data counted from the third step exceeds the light amount threshold value; And
If the bit light amount signal of the asynchronous data is greater than or equal to the light amount threshold value, the bit of the asynchronous data is determined to be high, and if the bit light amount signal of the asynchronous data is less than the light amount threshold value, Determining whether or not the asynchronous data having the non-periodic pulse width is data having validity; Wherein the step of determining the validity of the asynchronous data is performed using the optical sensor.

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