KR102464685B1 - Method and apparatus for optical signal communication - Google Patents

Abstract

Disclosed are a method for optical signal communication and an apparatus for transmitting an optical signal. The method for optical signal communication performed in an apparatus for transmitting an optical signal comprises the steps of: receiving the current input data to be modulated into an optical signal; dividing the received current input data into a plurality of sub data including first sub data and second sub data; modulating the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data; and transmitting the optical signal to an apparatus for receiving an optical signal.

Description

Optical signal communication method and apparatus

The embodiments below relate to optical signal communication technology.

Recently, medical devices using ICT (Information and Communication Technology) technology have appeared. Medical devices through ICT technology are being implemented in various forms such as being able to be attached to the body or worn directly, as well as insertable into the human body. Such a medical device has a function of collecting various signals of a living body and transmitting the collected signals to an external device.

Although the use of implantable medical devices is increasing in order to promote convenience, stability and accuracy of collecting biosignals, existing medical devices including radio frequency (RF)-based wireless communication modules consume a lot of power, It has a limitation in that the battery drains quickly. Furthermore, in human implantable medical devices, errors often occur in the data transmission/reception process. Therefore, there is a need for research to overcome the limitations of conventional implantable medical devices.

An optical signal communication method performed by an optical signal transmission apparatus according to an embodiment includes: receiving current input data to be modulated into an optical signal; dividing the received current input data into a plurality of sub data including first sub data and second sub data; modulating the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data; and transmitting the optical signal to an optical signal receiving device, wherein the optical signal receiving device receives the start pulse, and after a time count corresponding to a threshold is reached, the optical signal transmitting device sends the intermediate When at least one of the pulse and the end pulse is not received, it may be determined not to demodulate the received optical signal.

The first sub data includes a high-order bit of the current input data, the second sub-data includes a low-order bit of the current input data, and the number of bits of the first sub-data is a bit of the second sub-data less than the number, the interval between the start pulse and the intermediate pulse is determined based on a data value of the first sub data, and the interval between the intermediate pulse and the end pulse is determined based on a data value of the second sub data can be determined by

An optical signal communication method performed by an optical signal transmission apparatus according to an embodiment includes: receiving current input data to be modulated into an optical signal; When the difference between the value between the current input data and the previous input data is less than or equal to the threshold value, the current input data is not transmitted, and when the difference between the current input data and the previous input data is greater than the threshold value, modulating the current input data into an optical signal; and transmitting the optical signal to the optical signal receiving apparatus based on a predetermined transmission period shared between the optical signal transmitting apparatus and the optical signal receiving apparatus.

When the optical signal receiving apparatus receives a current optical signal from the optical signal transmission apparatus based on a predetermined transmission period, and fails to receive the current optical signal from the optical signal transmission apparatus based on the predetermined transmission period , it is possible to determine the current input data based on the previous optical signal.

In the modulating, when a difference between the current input data and the previous input data is greater than a threshold value, the current input data is converted to a light including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data. It may include modulating with a signal.

According to an embodiment, it is possible to develop an ultra-low power wireless data transmission communication module for an implantable medical biometric monitoring device.

According to an embodiment, by displaying information at intervals of the start pulse, the middle pulse, and the end pulse, the time for the light source to output light may be shortened, thereby reducing energy consumption.

According to an embodiment, errors such as omission of data that may occur in the process of transmitting and receiving wireless data may be prevented, and even if an error occurs, it is possible to minimize the effect on data transmitted and received thereafter.

According to an embodiment, by dividing the high-order bit of the data into first sub-data having a smaller number of bits than the second sub-data and the low-order bit into second sub data having a larger number of bits than the first sub data, the data It is possible to improve the accuracy of transmission and reception.

According to an embodiment, by setting the maximum value of the time interval for receiving the end pulse after receiving the start pulse, even if an error occurs during signal transmission/reception, it is possible to minimize the influence on the signal to be transmitted/received later.

1 is a diagram showing an outline of an optical signal communication system according to an embodiment.
2 is a flowchart illustrating an optical signal communication method performed by an optical signal transmission apparatus according to an exemplary embodiment.
3 is a flowchart illustrating an optical signal communication method performed by an optical signal transmission apparatus according to another exemplary embodiment.
4 is a diagram for describing an optical signal modulated based on divided sub data according to an exemplary embodiment.
5 is a diagram for describing an optical signal according to an exemplary embodiment.
6 is a diagram for explaining a section in which the same value of biosignals is maintained.
7 is a flowchart illustrating an optical signal communication method performed between entities according to another exemplary embodiment.
8 and 9 are diagrams for explaining an optical signal according to the first embodiment.
10 is a diagram for explaining an optical signal according to the second embodiment.
11 is a diagram for explaining an optical signal according to the third embodiment.
12 is a diagram illustrating a configuration of an optical signal transmission apparatus according to an embodiment.
13 is a diagram showing the configuration of an optical signal transmission apparatus according to another embodiment.

Specific structural or functional descriptions of the embodiments are disclosed for purposes of illustration only, and may be changed and implemented in various forms. Accordingly, the actual implementation form is not limited to the specific embodiments disclosed, and the scope of the present specification includes changes, equivalents, or substitutes included in the technical spirit described in the embodiments.

Although terms such as first or second may be used to describe various elements, these terms should be interpreted only for the purpose of distinguishing one element from another. For example, a first component may be termed a second component, and similarly, a second component may also be termed a first component.

When a component is referred to as being “connected” to another component, it may be directly connected or connected to the other component, but it should be understood that another component may exist in between.

The singular expression includes the plural expression unless the context clearly dictates otherwise. In this specification, terms such as "comprise" or "have" are intended to designate that the described feature, number, step, operation, component, part, or combination thereof exists, and includes one or more other features or numbers, It should be understood that the possibility of the presence or addition of steps, operations, components, parts or combinations thereof is not precluded in advance.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present specification. does not

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. In the description with reference to the accompanying drawings, the same components are assigned the same reference numerals regardless of the reference numerals, and the overlapping description thereof will be omitted.

1 is a diagram showing an outline of an optical signal communication system according to an embodiment.

The optical signal communication system described in this specification can perform low-power wireless communication using a light emitting diode (LED) having a characteristic that power is consumed only when the power is turned on. The optical signal communication system may divide the input data into relatively significant first sub-data including a high-order bit of the input data and relatively less significant second sub-data including a low-order bit of the input data. The optical signal communication system converts the input data into an optical signal by determining an interval between a start pulse and an intermediate pulse of the optical signal based on the first sub data, and determining an end pulse of an intermediate pulse of the optical signal based on the second sub data. can be tampered with. The optical signal communication system makes the number of bits of the relatively important first sub data smaller than the number of bits of the relatively less important second sub data, thereby reducing the possibility of errors that may occur during transmission and reception of the relatively important first sub data. , even if an error occurs, the impact of the error on the entire data can be minimized.

In addition, the optical signal communication system described in this specification may omit the process of transmitting the current input data when the difference between the values of the current input data to be transmitted and the previously transmitted input data is smaller than a threshold value. . That is, in this case, previous input data may be recognized as current input data.

Referring to FIG. 1 , the optical signal communication method may be performed through an optical signal transmission apparatus 110 and an optical signal reception apparatus 120 . The optical signal transmission apparatus 110 may modulate input data into an optical signal and transmit it to the optical signal reception apparatus 120 . Also, the optical signal receiving apparatus 120 may acquire input data corresponding to the optical signal by demodulating the optical signal received from the optical signal transmitting apparatus 110 .

When the optical signal transmission device 110 transmits an optical signal to the optical signal reception device 120 , the optical signal transmission apparatus 110 minimizes the time for the light source to output light, thereby reducing power consumption. In addition, the optical signal transmission apparatus 110 divides input data into a plurality of sub data, modulates the divided sub data into an optical signal including a start pulse, an intermediate pulse, and an end pulse, so that the optical signal is transmitted and It is possible to minimize power consumption and minimize errors in the process of receiving. The optical signal transmission apparatus 110 omits division, modulation, and transmission of input data while the same section of input data is repeated, and when the optical signal reception apparatus 120 does not receive the optical signal, the last Unreceived input data may be determined based on the received optical signal.

The optical signal transmission device 110 includes different wavelength lengths of a start pulse, an intermediate pulse, and an end pulse corresponding to the optical signal, division of input data, different widths of the start pulse, the middle pulse and the end pulse, and error detection included in the optical signal An error in transmitting an optical signal may be minimized by using at least one of information and error correction information.

In this specification, the optical signal transmission apparatus 110 is mainly described as an embodiment in which the input data is divided into two sub data, but the embodiment is not limited to the embodiment described in this specification, and the optical signal transmission apparatus 110 according to the embodiment may divide the input data into three or more sub data. In addition, the sub-data may be divided in various ways without being limited to the embodiment in which the sub-data is divided into high-order bits and low-order bits, or even bits and odd bits.

The optical signal receiving apparatus 120 may acquire data corresponding to the optical signal based on the time interval between the start pulse and the middle pulse of the optical signal and the time interval between the middle pulse and the end pulse of the optical signal. In addition, the optical signal receiving apparatus 120 has different wavelength lengths of the start pulse, the middle pulse, and the end pulse corresponding to the optical signal, an identifier bit for indicating the order of sub data, and different widths of the start pulse, the middle pulse, and the end pulse , a threshold value corresponding to a time interval between the start pulse, the middle pulse, and the end pulse, and at least one of error detection information or error correction information included in the optical signal, in receiving the optical signal, an error may be minimized.

2 is a flowchart illustrating an optical signal communication method performed by an optical signal transmission apparatus according to an exemplary embodiment.

Referring to FIG. 2 , the optical signal transmission apparatus may receive current input data to be modulated into an optical signal in step 210 . For example, the input data may have a data value in the form of a 16-bit binary number, but the size and shape of the input data are not limited to the description herein and may further have other sizes and shapes.

In operation 220 , the optical signal transmission apparatus may divide the received current input data into a plurality of sub data including the first sub data and the second sub data. Here, the first sub data may include a high-order bit of the current input data, and the second sub-data may include a low-order bit of the current input data. Also, the number of bits of the first sub data may be less than the number of bits of the second sub data, and the number of bits of the second sub data may be greater than the number of bits of the first sub data. In input data, since the data included in the high-order bit may be more important than the data included in the low-order bit in general, if an error occurs while transmitting the bit higher than the lower bit, the entire data may be greatly affected. Due to the characteristics of the optical signal transmission method, as the interval between pulses increases, an error is more likely to occur in the receiving position. That is, as the number of bits to be expressed in one optical signal increases, the probability of an error may increase. In the optical signal transmission device, in order to minimize the effect on the entire data when an error occurs, the upper bit that has a greater effect on the entire data than the lower bit when an error occurs is the first sub data, and when an error occurs, the upper bit is added to the entire data By performing asymmetric division in which the lower bit having a smaller influence is divided into the second sub data, the occurrence of an error can be prevented, and even when an error occurs, the influence on the entire data can be minimized.

In operation 230 , the optical signal transmission apparatus may modulate the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data. The interval between the start pulse and the middle pulse may be determined based on a data value of the first sub data, and the interval between the middle pulse and the end pulse may be determined based on a data value of the second sub data. Since the number of bits of the first sub data is smaller than the number of bits of the second sub data, the interval between the start pulse and the intermediate pulse may be smaller than the interval between the middle pulse and the end pulse.

In another embodiment, each of the start pulse, the middle pulse, and the end pulse may be distinguished from each other based on the width of the pulse or the length of the wavelength of the pulse. That is, the width of the start pulse, the middle pulse, and the end pulse may be different or the wavelength may be different. A characteristic in which a start pulse, an intermediate pulse, and an end pulse are distinguished by the width of the pulse or the wavelength length of the pulse may be described with reference to FIGS. 5 and 11 .

In another embodiment, the optical signal transmission apparatus may modulate each of the first sub data and the second sub data into an optical signal including a start pulse and an end pulse. That is, the optical signal transmission apparatus may modulate the first sub data into a first optical signal including a first start pulse and a first end pulse, and convert the second sub data to include a second start pulse and a second end pulse. can be modulated with a second optical signal. In an embodiment, the first end pulse and the second start pulse may be replaced with an intermediate pulse. In an embodiment, since the intermediate pulse replaces the two pulses, the optical signal transmission apparatus according to an embodiment may transmit input data using a smaller number of pulses than the optical signal transmission apparatus according to another embodiment.

In step 240 , the optical signal transmission device may transmit the optical signal to the optical signal reception device. In an embodiment, the optical signal may not include pulses other than the start pulse, the middle pulse, and the end pulse. When the optical signal receiving device does not receive at least one of the intermediate pulse and the end pulse from the optical signal transmitting device after a time count corresponding to the threshold value after receiving the start pulse, it is assumed that the received optical signal is not demodulated. can decide A description of the threshold value may be made in more detail in the description of FIG. 10 .

3 is a flowchart illustrating an optical signal communication method performed by an optical signal transmission apparatus according to another exemplary embodiment.

Referring to FIG. 3 , in step 310 , the optical signal transmission apparatus may receive current input data to be modulated into an optical signal. For example, the input data may have a data value in the form of a 16-bit binary number, but the size and shape of the input data are not limited to the description herein and may further have other sizes and shapes.

The optical signal transmission apparatus may compare the difference between the current input data and the previous input data. The optical signal transmission apparatus may not perform transmission of the current input data when a difference between values between the current input data and the previous input data is less than or equal to a threshold value. That is, when the difference between the values of the current input data and the previous input data is less than or equal to the threshold value, the optical signal transmission apparatus determines that the values of the current input data and the previous input data are the same, and the optical signal transmission apparatus determines the current input data may not perform transmission to . That is, when it is determined that the current input data and the previous input data are the same, the optical signal transmission apparatus performs a process of dividing the input data into sub data, a process of modulating the divided sub data into an optical signal, and a process of transmitting the modulated optical signal. All can be omitted. Here, the current input data may be the most recently received input data, and the previous input data may be input data received immediately before the current input data.

When the difference between the current input data and the previous input data is greater than the threshold value, in operation 320 , the optical signal transmission apparatus may modulate the optical signal with the current input data. The optical signal transmission apparatus may modulate the current input data into an optical signal including a start pulse and an end pulse, or modulate the current input data into an optical signal including at least one of a start pulse, an intermediate pulse, and an end pulse. can do. According to an embodiment, the optical signal transmission apparatus may divide the current input data into a plurality of sub data when a difference between the current input data and the previous input data is greater than a threshold value. The optical signal transmission apparatus may modulate the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data.

In operation 330, the optical signal transmission apparatus may transmit the optical signal to the optical signal reception apparatus based on a predetermined transmission period shared between the optical signal transmission apparatus and the optical signal reception apparatus.

The optical signal receiving apparatus may receive the current optical signal from the optical signal transmitting apparatus based on a predetermined transmission period. In an embodiment, the optical signal transmission apparatus may transmit information on a predetermined transmission period to the optical signal reception apparatus. Accordingly, the predetermined transmission period of the optical signal may be shared in advance between the optical signal transmission apparatus and the optical signal reception apparatus. If the optical signal receiving apparatus does not receive the current optical signal based on a predetermined transmission period from the optical signal transmitting apparatus, it may determine current input data based on the previous optical signal. When an error occurs in the reception process, or when the optical signal transmission device determines that the current input data and the previous input data are the same and omits the transmission of the optical signal corresponding to the current input data, the optical signal reception device is based on a predetermined transmission period Therefore, the current optical signal may not be received. In this case, the optical signal receiving apparatus may determine the most recently received optical signal among previously received optical signals as the current optical signal, and may determine current input data based on the optical signal determined as the current optical signal.

4 is a diagram for describing an optical signal modulated based on divided sub data according to an exemplary embodiment.

Referring to FIG. 4 , the input data 410 may be divided into 6-bit first sub-data 420 and 10-bit second sub data 430 . The first sub data 420 may include a high-order bit that greatly affects all data when an error occurs. That is, when a transmission/reception error occurs in the first sub-data 420 , the high-order bit has a greater effect on the entire data than when a transmission/reception error in the second sub-data 430 occurs. When a transmission/reception error occurs in the second sub-data 430 , the second sub-data 430 may include a lower bit that has a smaller effect on the entire data than when a transmission/reception error in the first sub-data 420 occurs. Since the number of bits of the first sub data 420 is smaller than the number of bits of the second sub data 430 , the possibility of an error occurring in the process of transmitting and receiving the first sub data 420 is higher than that of the second sub data 430 . It is lower than the possibility of errors occurring in the process of sending and receiving. Therefore, the optical signal transmission apparatus minimizes the possibility of errors by modulating data of relatively high importance into an optical signal based on the first sub data 420 having a relatively low probability of transmission/reception errors and a small number of bits, Even if an error occurs, the impact on the entire data can be minimized.

The optical signal transmission apparatus may modulate the first sub data 420 and the second sub data 430 into an optical signal including a start pulse, an intermediate pulse, and an end pulse. The interval 440 between the start pulse and the middle pulse may be determined based on the first sub data 420 , and the interval 450 between the middle pulse and the end pulse may be determined based on the second sub data 430 . After receiving the start pulse, the optical signal receiving device may wait for a time corresponding to the first reception threshold until receiving the intermediate pulse, and at the second reception threshold until receiving the end pulse after receiving the intermediate pulse. You can wait for the corresponding time.

When the optical signal receiving device fails to receive the intermediate pulse or any pulse before the time corresponding to the first reception threshold has elapsed after receiving the start pulse, it is determined that an error has occurred in receiving the intermediate pulse, and an end pulse Can wait to receive. In addition, when the optical signal receiving device does not receive any end pulse or any pulse before the time corresponding to the second reception threshold elapses after receiving the intermediate pulse, it is determined that an error has occurred in receiving the end pulse and wait to receive the start pulse of the next optical signal.

5 is a diagram for describing an optical signal according to an exemplary embodiment.

Referring to FIG. 5 , the width of each of the start pulse 510 , the middle pulse 520 , and the end pulse 530 may be different. Here, the width of the pulse may be at least one of a time interval in which a signal value is maintained, a time interval in which the logic level is maintained at 1, and a time interval in which the optical signal transmission device outputs light. Since the widths of each of the start pulse 510, the middle pulse 520, and the end pulse 530 are different, the optical signal receiving apparatus performs the start pulse 510, the middle pulse based on the width of the pulse included in the optical signal. A pulse 520 and an end pulse 530 can be identified. When the optical signal receiving apparatus receives the start pulse 510 or the end pulse 530 in a state in which one intermediate pulse 520 is not received after the optical signal receiving apparatus receives the start pulse 510, the optical signal receiving apparatus starts Without mistaking the pulse 510 or the end pulse 530 as an intermediate pulse, it may be determined that an error has occurred in the reception of the intermediate pulse. The optical signal receiving apparatus determines that an error has occurred in reception of the intermediate pulse without mistaking another pulse as an intermediate pulse, so that even if an error occurs, the error does not have an effect on a subsequently received optical signal.

6 is a diagram for explaining a section in which the same value of biosignals is maintained.

The optical signal communication system described herein may transmit/receive input data 610 based on biometric data (or biosignal) collected by a medical device implanted inside the body. In general, since the period 620 in which the input data based on biometric data maintains the same value may occur, the optical signal communication system described in the present specification provides a period in which the input data maintains the same value in order to minimize energy consumption. 620), the process of dividing, modulating, and transmitting the input data may be omitted. A description of omitting the process of division, modulation, and transmission of input data by the optical signal transmission apparatus in the section 620 in which the input data maintains the same value may be described in the detailed description corresponding to FIGS. 3 and 7 . .

7 is a flowchart illustrating an optical signal communication method performed between entities according to another exemplary embodiment.

Referring to FIG. 7 , the optical signal transmission apparatus 700 may receive first input data from a medical device implanted inside a patient's or user's body. The optical signal transmission apparatus 700 may be implanted inside the user's body together with the medical device, or may be outside the user's body according to an embodiment.

The optical signal transmission apparatus 700 may transmit an optical signal to the optical signal reception apparatus 705 based on predetermined transmission periods 785 , 790 , and 795 . Accordingly, the optical signal receiving apparatus 705 may receive the optical signal from the optical signal transmitting apparatus 700 based on the predetermined transmission periods 785 , 790 , and 795 . For example, the optical signal transmission device 700 transmits the first optical signal to the optical signal reception device 705 and then sends the first optical signal to the optical signal reception device 705 after a predetermined transmission period 785 elapses. 2 can transmit optical signals.

When the optical signal receiving apparatus 705 fails to receive the optical signal from the optical signal transmitting apparatus 700 based on the predetermined transmission periods 785 , 790 , and 795 , the optical signal receiving apparatus 705 transmits and receives the optical signal It may be determined that an error has occurred or that the current input data and the previous input data are determined to be the same.

The predetermined transmission periods 785 , 790 , and 795 may all be the same time interval. The predetermined transmission periods 785 , 790 , and 795 may be predetermined and shared between the optical signal transmission apparatus 700 and the optical signal reception apparatus 705 . For example, the optical signal transmission apparatus may share the predetermined transmission period with the optical signal reception apparatus by transmitting the predetermined transmission period to the optical signal reception apparatus.

The optical signal transmission apparatus 700 may divide the first input data into a plurality of sub data and may modulate the divided sub data into a first optical signal. The optical signal transmission apparatus 700 may transmit the first optical signal to the optical signal reception apparatus 705 in operation 715 . The optical signal receiving apparatus 705 may receive first input data based on the first optical signal in operation 720 . That is, the optical signal receiving apparatus 705 may determine the first input data based on the first optical signal. The optical signal receiving device 705 may transmit the first input data to the receiving data processing device 710 in operation 725 .

The optical signal transmission apparatus 700 may receive second input data. In operation 730 , the optical signal transmission apparatus 700 may calculate whether a difference between the values of the first input data and the second input data is greater than a threshold value. When the difference between the values of the first input data and the second input data is greater than the threshold value, the optical signal transmitting apparatus 700 transmits a second optical signal based on the second input data to the optical signal receiving apparatus 705 in step 735 . ) can be transmitted. The optical signal receiving apparatus 705 may receive second input data based on the second optical signal in operation 740 . The optical signal receiving device 705 may transmit the second input data to the receiving data processing device 710 in operation 745 .

The optical signal transmission apparatus 700 may receive third input data. In operation 750 , the optical signal transmission apparatus 700 may calculate whether a difference between the values of the second input data and the third input data is greater than a threshold value. When the difference between the values of the second input data and the third input data is equal to or less than the threshold value, the optical signal transmission apparatus 700 omits the process of dividing and modulating the third input data, and the third input data corresponding to the third input data is omitted. Transmission of an optical signal can also be omitted. The optical signal receiving apparatus 705 may recognize that there is no data received in step 755 based on the predetermined transmission period 790 . The optical signal receiving device 705 may recognize that the third input data is determined to be the same as the second input data, and transmit the second input data as the third input data to the receiving data processing device 710 in step 760 . have.

The optical signal transmission apparatus 700 may receive fourth input data. In operation 765 , the optical signal transmission apparatus 700 may calculate whether a difference between the fourth input data and the third input data is greater than a threshold value. When the difference between the values of the fourth input data and the third input data is greater than the threshold value, the optical signal transmitting apparatus 700 transmits a fourth optical signal based on the fourth input data to the optical signal receiving apparatus 705 in step 770 . ) can be transmitted. The optical signal receiving apparatus 705 may receive fourth input data based on the fourth optical signal in operation 775 . The optical signal receiving device 705 may transmit the fourth input data to the receiving data processing device 710 in operation 780 .

8 and 9 are diagrams for explaining an optical signal according to the first embodiment.

8 and 9 , the optical signal may include a start pulse and an end pulse. The optical signal transmission apparatus may determine a time interval between a time point at which a start pulse is transmitted and a time point at which an end pulse is transmitted, based on the data value of the input data. The optical signal transmitted by the optical signal transmission device may include only a start pulse and an end pulse. In addition, the optical signal transmission apparatus may minimize power consumption by outputting light only when transmitting the start pulse and at the time of transmitting the end pulse. The optical signal receiving apparatus may determine data corresponding to the optical signal based on a time interval between a time point at which the start pulse is received and a time point at which the end pulse is received.

Referring to FIG. 8 , in the first embodiment, when the optical signal transmitting apparatus transmits a start pulse or the optical signal receiving apparatus receives a start pulse, the optical signal transmitting apparatus transmits an end pulse, or the optical signal receiving apparatus The time interval between the time points at which the end pulse is received may be four spaces. Here, each cell existing between the start pulse and the end pulse may mean a predetermined predetermined time interval according to an embodiment. In this case, the data value of the data corresponding to the optical signal may be 4, and the optical signal receiving apparatus may determine the data value as 4 based on a time interval between when the start pulse and the end pulse are received. According to an embodiment, the optical signal receiving apparatus may demodulate and process the data value into an 8-bit binary number.

Referring to FIG. 9 , in the first embodiment, when the optical signal transmitting apparatus transmits a start pulse or the optical signal receiving apparatus receives a start pulse, the optical signal transmitting apparatus transmits an end pulse, or the optical signal receiving apparatus The time interval between when the end pulse is received may be 13 spaces. In this case, the data value of the data corresponding to the optical signal may be 13, and the optical signal receiving apparatus may determine the data value as 13 based on a time interval between when the start pulse and the end pulse are received.

10 is a diagram for explaining an optical signal according to the second embodiment.

10 is a diagram for explaining an optical signal having a threshold value according to the second embodiment.

Referring to FIG. 10 , in the second embodiment, the optical signal transmission apparatus may set a threshold value for the optical signal and share it with the optical signal reception apparatus. Here, the threshold value for the optical signal may mean a maximum value of a time interval between pulses corresponding to one optical signal. The maximum value of the time interval between the start pulse 1010 and the intermediate pulse 1020 may be a first threshold value, and the maximum value of the time interval between the intermediate pulse 1020 and the end pulse 1030 may be the second threshold value. The first threshold value and the second threshold value may be the same value, and according to an embodiment, the first threshold value may be smaller than the second threshold value.

Referring to FIG. 10 , in the above embodiment, the optical signal transmission apparatus may determine a threshold value including the first threshold value and the second threshold value and share it with the optical signal reception apparatus. The optical signal receiving apparatus may receive a start pulse 1010 corresponding to the first optical signal, and then receive an intermediate pulse 1020 corresponding to the first optical signal. After receiving the start pulse 1010 corresponding to the first optical signal, the optical signal receiving apparatus receives the intermediate pulse 1020 corresponding to the first optical signal before the time count by the first threshold value is The first sub data of one optical signal may be normally received. After receiving the intermediate pulse 1020, the optical signal receiving apparatus receives the end pulse 1030 corresponding to the first optical signal before the time count by the second threshold value is reached, and the second of the first optical signal Sub data can be normally received.

After receiving the end pulse 1030 corresponding to the first optical signal, the optical signal receiving apparatus may receive a start pulse corresponding to the second optical signal. The optical signal receiving apparatus may wait for reception of an intermediate pulse and an end pulse corresponding to the second optical signal in order to normally receive the second optical signal.

If the start pulse 1010 , the middle pulse 1020 , and the end pulse 1030 have the same widths so that the optical signal receiving apparatus cannot distinguish the start pulse, the middle pulse, and the end pulse only by the width of the pulse, one pulse If an error occurs in receiving the optical signal, one error may affect the reception of the next optical signal by the optical signal receiving device. In particular, if the threshold value does not exist, when the optical signal receiving apparatus fails to receive the intermediate pulse 1020 corresponding to the first optical signal after receiving the start pulse 1010 corresponding to the first optical signal , the optical signal receiving apparatus may extract erroneous data from the first optical signal, and the error may also have an effect on identifying a subsequently received optical signal.

On the other hand, when the threshold value exists as in the second embodiment, the optical signal receiving apparatus starts counting the time after receiving the start pulse 1010 corresponding to the first optical signal, and the time is equal to the first threshold value. If the intermediate pulse 1020 corresponding to the first optical signal is not received even after counting, the optical signal receiving apparatus has an error in receiving the first sub data of the first optical signal based on the first threshold value. can be considered to have occurred. In addition, after the optical signal receiving apparatus receives the intermediate pulse 1020 corresponding to the first optical signal, the time counting starts, and even after the second threshold time count is reached, the end pulse corresponding to the first optical signal ( 1030), the optical signal receiving apparatus may determine that an error has occurred in receiving the second sub data of the first optical signal based on the second threshold value. When it is determined that an error has occurred, the optical signal receiving apparatus may determine not to demodulate the optical signal corresponding to the pulse that has not been received.

After the optical signal receiving apparatus receives the start pulse 1010 corresponding to the first optical signal, the time count may be started. At this time, if the optical signal receiving device does not receive the intermediate pulse 1020 corresponding to the first optical signal within the time count corresponding to the first threshold value, the optical signal receiving device stops counting the time corresponding to the first threshold value, , while waiting for the end pulse 1030 , a time count corresponding to the second threshold value may be counted, or it may be determined not to demodulate the optical signal corresponding to the start pulse 1010 .

11 is a diagram for explaining an optical signal according to the third embodiment.

11 may be a diagram for explaining an optical signal having different wavelength lengths of a start pulse, an intermediate pulse, and an end pulse.

Referring to FIG. 11 , in the third embodiment, the optical signal may include a start pulse, an intermediate pulse, and an end pulse. Here, the wavelength length of the start pulse, the wavelength length of the intermediate pulse, and the wavelength length of the end pulse may be different from each other.

In the above embodiment, the optical signal transmitting apparatus may transmit a start pulse 1110 corresponding to the optical signal, an intermediate pulse 1120 corresponding to the optical signal, and an end pulse 1130 corresponding to the optical signal to the optical signal receiving apparatus. have. After receiving the start pulse 1110 corresponding to the optical signal, the optical signal receiving apparatus may wait until the intermediate pulse 1120 is received. The optical signal receiving apparatus may receive the intermediate pulse 1120 corresponding to the optical signal, and may start counting until the end pulse 1130 is received in response to the reception.

In the above embodiment, the wavelength lengths of the start pulse 1110 , the middle pulse 1120 , and the end pulse 1130 may be different. For example, the optical signal transmission apparatus may set the wavelength length of the start pulse 1110 to 700 nm (nanometers), set the wavelength length of the intermediate pulse 1120 to 900 nm, and the wavelength of the end pulse 1130 . The length can be set to 800 nm. The optical signal receiving apparatus identifies the start pulse 1110, the middle pulse 1120, and the end pulse 1130 based on the characteristic that the wavelength lengths of the start pulse 1110, the middle pulse 1120, and the end pulse 1130 are different. able, recognizable, and distinguishable.

When the optical signal receiving apparatus receives the start pulse 1110 corresponding to the optical signal based on the characteristic that the wavelength lengths of the start pulse 1110 , the middle pulse 1120 , and the end pulse 1130 are different, the optical signal reception starts. can be recognized Upon recognizing the start of optical signal reception, the optical signal receiving apparatus may start time counting. When the optical signal receiving apparatus receives the end pulse 1130 while waiting for the reception of the intermediate pulse 1120 corresponding to the optical signal, the optical signal receiving apparatus has an error in the reception of the intermediate pulse 1120 can be determined to have occurred.

Since the optical signal receiving apparatus can distinguish the start pulse 1110, the middle pulse 1120, and the end pulse 1130 based on the wavelength length of each signal pulse 1110, 1120, and 1130, one optical signal is transmitted and received. Even if an error occurs in the process, the effect of the error can be minimized in processing the next optical signal received by the optical signal receiving apparatus.

12 is a diagram illustrating a configuration of an optical signal transmission apparatus according to an embodiment.

Referring to FIG. 12 , an optical signal transmission apparatus according to an embodiment may include a communication unit 1210 , an input data division unit 1220 , and a modulator 1230 . The optical signal transmission device described herein may correspond to the optical signal transmission device described with reference to FIG. 2 .

The communication unit 1210 may receive current input data to be modulated into an optical signal, and may transmit the optical signal to the optical signal receiving apparatus.

The input data dividing unit 1220 may divide the received current input data into a plurality of sub data including the first sub data and the second sub data. The modulator 1230 may modulate the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data.

13 is a diagram showing the configuration of an optical signal transmission apparatus according to another embodiment.

Referring to FIG. 13 , an optical signal transmission apparatus 1300 according to another embodiment may include a communication unit 1310 , an input data division unit 1320 , a processing unit 1330 , and a modulator 1340 . Here, the optical signal transmission apparatus 1300 may correspond to the optical signal transmission apparatus described with reference to FIG. 3 .

The communication unit 1310 may receive current input data to be modulated into an optical signal, and transmit the optical signal to the optical signal receiving apparatus. The processing unit 1330 may calculate whether a difference between the current input data and the previous input data is greater than a threshold value. When the difference between the current input data and the previous input data is equal to or less than a threshold value, the processor 1330 may determine not to transmit the current input data.

The input data dividing unit 1320 may divide the current input data into a plurality of sub data when a difference between the current input data and the previous input data is greater than a threshold value.

The modulator 1340 may modulate a plurality of sub data into an optical signal including a plurality of pulses. When the difference between the current input data and the previous input data is greater than a threshold value, the modulator 1340 converts the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data. can be tampered with.

According to an embodiment, the optical signal transmission apparatus of FIG. 12 may perform the optical signal communication method described with reference to FIG. 3 , and the optical signal transmission apparatus 1300 of FIG. 13 may perform the optical signal communication method described with reference to FIG. 2 . can

The hardware devices described above may be configured to operate as one or a plurality of software modules to perform the operations of the embodiments, and vice versa.

As described above, although the embodiments have been described with reference to the limited drawings, a person skilled in the art may apply various technical modifications and variations based thereon. For example, the described techniques are performed in a different order than the described method, and/or the described components of the system, structure, apparatus, circuit, etc. are combined or combined in a different form than the described method, or other components Or substituted or substituted by equivalents may achieve an appropriate result.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

110, 700, 1300: optical signal transmission device
120, 705: optical signal receiving device
710: receiving data processing device
1210, 1310: communication department
1220, 1320: input data division unit
1230, 1340: modulator

Claims (5)

An optical signal communication method performed in an optical signal transmission device, comprising:
receiving current input data to be modulated into an optical signal;
dividing the received current input data into a plurality of sub data including first sub data and second sub data;
modulating the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub-data; and
transmitting the optical signal to an optical signal receiving device;
The optical signal receiving device,
After receiving the start pulse, if at least one of the intermediate pulse and the end pulse is not received from the optical signal transmission device after a time count corresponding to a threshold value, the received optical signal is not demodulated decide,
The first sub data includes a high-order bit of the current input data,
The second sub data includes a lower bit of the current input data,
The number of bits of the first sub data is less than the number of bits of the second sub data,
The interval between the start pulse and the intermediate pulse is determined based on a data value of the first sub data,
The interval between the middle pulse and the end pulse is determined based on a data value of the second sub data,
Optical signal communication method. delete An optical signal communication method performed in an optical signal transmission device, comprising:
receiving current input data to be modulated into an optical signal;
When the difference between the value between the current input data and the previous input data is less than or equal to a threshold value, the current input data is not transmitted, and when the difference between the current input data and the previous input data is greater than the threshold value, the modulating the current input data into an optical signal; and
transmitting the optical signal to the optical signal receiving apparatus based on a predetermined transmission period shared between the optical signal transmitting apparatus and the optical signal receiving apparatus;
The modulating step is
dividing the current input data into a plurality of sub data including first sub data and second sub data when a difference between the current input data and the previous input data is greater than a threshold value;
modulating the current input data into an optical signal including a start pulse, an intermediate pulse, and an end pulse based on the divided sub data;
including,
The first sub data includes a high-order bit of the current input data,
The second sub data includes a lower bit of the current input data,
The number of bits of the first sub data is less than the number of bits of the second sub data,
The interval between the start pulse and the intermediate pulse is determined based on a data value of the first sub data,
The interval between the middle pulse and the end pulse is determined based on a data value of the second sub data,
Optical signal communication method. 4. The method of claim 3,
The optical signal receiving device,
receiving a current optical signal from the optical signal transmission device based on the predetermined transmission period;
determining current input data based on a previous optical signal when the current optical signal is not received from the optical signal transmission device based on the predetermined transmission period;
Optical signal communication method. delete

Images