JPH0560705B2 - - Google Patents

Description

Detailed Description of the Invention [Industrial Application Field] The present invention distinguishes between information "0" and "1" based on the length of the interval between two pulses, and transmits the pulse by modulating it at a specific frequency. The present invention relates to digital remote control methods, and particularly to digital remote control methods that use custom coded transmission codes.

[Conventional technology] A general remote control system is
As shown in the figure. In FIG. 2, 1 is a transmission circuit for modulating a transmission code at a specific frequency and transmitting it;
2 is a receiving circuit that processes the received signal; 3 is a light emitting unit consisting of a light emitting element such as a light emitting diode that receives the output of the transmitting circuit 1; 4 is a light emitting unit that receives the optical signal a from the light emitting unit 3 and receives the output. This is a light receiving section consisting of a light receiving element such as a photodiode that sends out light to the circuit 2.

In the remote control system configured in this way, first, the transmission circuit 1 encodes and modulates the information to be sent, and the light emitting section 3 converts it into an optical signal a and transmits it. Next, the transmitted optical signal a is received by the light receiving section 3, demodulated by the receiving circuit 2, and the command is decoded.

In a remote control system with such a configuration and function, the distinction between information "0" and "1" is made by two consecutive This is done with two pulse intervals. That is, in Figure 3,
The short pulse interval 5 shown in a corresponds to "0", and the long pulse interval 6 shown in b corresponds to "1".

Conventionally, a method has been adopted in which a number of bits of these "0" and "1" are combined in a transmission code format as shown in FIG. 4, and the type of instruction is distinguished according to the data code of one word 7. It was getting worse.
Additionally, in order to avoid interference with other remote control systems, some bits of the transmission code were assigned to the custom code, and the remaining bits were assigned to the instruction code. For example, if 3 bits of a 10-bit transmission code are custom code and 7 bits are instruction code, there are 8 (=2 ³ ) independent types with 128 (= 2 ⁷ ) instructions per system. system can be configured. In addition,
In FIG. 4, 8 indicates the repetition period of the transmission code.

When the transmitting side transmits a transmission code as shown in FIG. 4, the receiving side first decodes the custom code part of the received transmission code, and then decodes the instruction code part. That is, on the receiving side, when receiving a 10-bit transmission code, for example, the first 3 bits are decoded as a custom code, and the remaining 7 bits are decoded as an instruction code. If the decoded custom code is the code given to your system, execute the command that decoded the instruction code.

[Problems to be Solved by the Invention] In the conventional digital remote control method as described above, on the receiving side, the criteria for determining information "0" and "1" happen to be similar, and the custom code in the transmission code If the number of bits in the sum of the system and the instruction code match, even if the transmission code is for another system, it may be recognized as its own transmission code, causing interference and making it impossible to use it as a remote control. It had the problem of being lost.
In other words, even if the custom code given to two systems is different, for example, the custom code for one system is composed of 3 bits, and the custom code for the other system is different. If the custom code and instruction code are composed of 4 bits (the first 3 bits are the same as the custom code for one system), the custom code and instruction code Since the code is continuous and the pulses indicating information "0" and "1" are continuous, even if the transmission code is for the other system, it can be transmitted by one system. Also, even if the transmission code is for one system, the 4th bit of the transmission code (the first bit of the instruction code) is the same as the 4th bit of the custom code of the other system. If you become
A transmission code for one system may be judged as a transmission code for the other system's own system.

In addition, in the conventional digital remote control method, the custom code and instruction code are continuous, and the pulses indicating information "0" and "1" are continuous, so the custom code,
When attempting to expand the instruction code, there was a problem in that interference with the current system and other systems was likely to occur.

The present invention has been made in view of these points, and aims to provide a digital remote control method that can prevent misrecognition of custom codes in transmission codes on the receiving side of the system. As a result, there is less interference between remote control systems, and
This allows for many independent remote control systems.

[Means for solving the problem] The digital remote control method according to the invention recited in claim 1 of the present invention distinguishes between information "0" and "1" based on the length of two pulse intervals. and the first pulse indicating the beginning of the transmission code,
Transmission with a custom code consisting of multiple bits of information ``0'' and ``1'' to avoid interference between different systems, and an instruction code consisting of multiple bits of information ``0'' and ``1.'' In a device that modulates a code at a specific frequency and transmits it, the transmission order is the first pulse, custom code, and instruction code, and pulses indicating information "0" and "1" are placed between the first pulse and the custom code. A first discriminator is provided to recognize the end of the leading pulse and the start of the custom code, and information "0" is provided between the custom code and the instruction code.
and a pulse interval different from the pulse interval indicating "1", and is transmitted by providing a second discriminator for recognizing the end of the custom code and the start of the instruction code.

In the digital remote control method according to the invention described in claim 5 of the present invention, the transmission order is a first pulse, an instruction code, and a custom code, and information "0" is placed between the first pulse and the instruction code. ” and a pulse interval that is different from the pulse interval indicating “1”, and a first discriminator is provided to recognize the end of the first pulse and the start of the instruction code, and the transmission is performed between the instruction code and the custom code. A second discriminator is provided to recognize the end of the instruction code and the start of the custom code, which has a pulse interval different from the pulse interval indicating information "0" and "1".

[Operation] In each of the inventions recited in claims 1 and 5 of the present invention, the first discrimination section and the second discrimination section distinguish between the leading pulse in the transmission code, the custom code, and the instruction. Accurately recognize each code.

[Example] An example of the digital remote control method according to the present invention will be described with reference to FIGS. 1 and 2. In FIG. 1, 10 and 11 are bit intervals of t (=1 ms) and 2t, respectively, indicating 1 bit of information "0" and "1" of information "1".
2 consists of 7 bits of information "0" and "1", and is a custom code to avoid interference between different systems, 13 consists of 8 bits of information "0" and "1"
The instruction code consists of bits, 14 is the first pulse with a pulse width of 8t, 15 is a space as a pulse interval to provide an interval between the first pulse 14 and the custom code 12, and information "0" and "1". The pulse interval is different from the pulse interval indicating , and constitutes a first discriminator for recognizing the end of the leading pulse and the beginning of the custom code. 16 is a space as a pulse interval to provide an interval between the custom code 12 and the instruction code 13, and is composed of a pulse interval different from the pulse interval indicating information "0" and "1",
This constitutes a second discriminator for recognizing the end of the custom code and the start of the instruction code. 17 is the repetition period of the transmission code, the transmission code has a leading pulse of 14 and a custom code of 15.
and instruction code 16.

Next, the operation of the above embodiment will be explained. When transmitting a transmission code as a remote control signal on the transmitting side, first the first pulse 14 is transmitted, then the 7-bit custom code 12 and the 8-bit instruction code 13 are transmitted, and the combination of the first pulse and the custom code is transmitted in that order. A first discrimination section is provided between the custom code and the instruction code, and a second discrimination section is provided between the custom code and the instruction code.

Next, on the receiving side, the first pulse 14 is received in a reception standby state, and the width of this first pulse 14 is
8ms with 14 leading pulses and 12 custom codes
If the space (first discriminator) 15 is 4 ms, the signal being received is considered valid, and the next custom code 12 and instruction code 13 are read.
If the width of the leading pulse 14 or the space 15 does not satisfy the above conditions, the device returns to the reception standby state.

The receiving side that has read the custom code 12 and instruction code 13 determines that the pulse interval is 1 ms (=t) as information "0", and when 2 ms = (2t) as information "1", and that the pulse interval is information "1". ”, for example, 2.5ms or more, this pulse interval is determined by custom code 12 and instruction code 13.
The code before this space 16 is identified as the custom code 12, and the code after the space 16 is identified as the instruction code 13. Then, on the receiving side, if the custom code 12 of, for example, a 7-bit configuration located after the space 16 is the code designated for the receiver, the instruction code 13 of, for example, an 8-bit configuration located after the space 16 is decoded and decoded. Execute instructions according to the results.

In other words, on the receiving side, the first pulse 14, custom code 12, and instruction code 13 that are received one after another are detected by the spaces (first and second discriminator) 15, 16 as pulse intervals between the respective pulses and codes. It recognizes them as separate, and also recognizes each one based on the order in which they are received.This allows it to accurately recognize the transmission code given to its own system, and to distinguish between it and other systems. This prevents interference and crosstalk. For example, unlike the transmission code shown in Figure 1, the custom code is 6 bits, the instruction code is 9 bits, and the first
If there is a remote control system using the same 15-bit transmission code as shown in the figure, even if the information in the first 7 bits of the 6-bit custom code and 9-bit instruction code is the same as shown in Figure 1. 7 bit custom code 1
Even if the information in 2 is the same, the space (second discriminator) 15 distinguishes between the custom code and the instruction code and the transmission code is transmitted, so there will be no interference between the two systems. be. In other words, in the conventional example described above, the custom code and instruction code were continuous, and the transmission code was a continuous pulse indicating information "0" and "1", so the 7-bit custom code When the receiving side receives a transmission code consisting of a 6-bit custom code and a 9-bit instruction code,
If the information in the first 7 bits of a 9-bit custom code and a 9-bit instruction code is the same as the 7-bit custom code, the programmer will recognize it as the code specified for itself, and the 6-bit custom code When the receiving side receives a transmission code consisting of a 7-bit custom code and an 8-bit instruction code, the information in the first 6 bits of the 7-bit custom code is If it is the same as the custom code of the bit, it will be mistaken as the code specified for you, whereas in the example shown in the above example, the information "0", " Since there is a space (second discriminator) that is a pulse interval different from the pulse interval indicating "1", if this space is recognized, the code located before this space is a custom code, and the code located after this space is a command. It can be identified as a code.
Therefore, for example, if a receiving side receives a transmission code consisting of a 7-bit custom code and an 8-bit instruction code, and receives a transmission code consisting of a 6-bit custom code and a 9-bit instruction code, the 6-bit custom Even if the information in the first 7 bits of the code and the 9-bit instruction code is the same as the 7-bit custom code, it will not be recognized as the code specified for you.
When the receiving side receives a transmission code consisting of a 7-bit custom code and an 8-bit instruction code, the first 6 bits of the 7-bit custom code are Even if the information is the same as the 6-bit custom code, it will not be recognized as the code specified for itself, so no interference will occur.

In the above embodiment, the custom code 12 and the instruction code 13 have different numbers of bits, but they may have the same number of bits.

Further, in the above embodiment, the pulse (bit) interval indicating information "0" is nt, the pulse (bit) interval indicating information "1" is mt, and the space between the leading pulse 14 and the custom code 12 (the first (discrimination part) 1
5 is 1t, the space (second discriminator) 16 between the custom code 12 and the instruction code 13 is kt, and the width of the first pulse 14 is jt, then n=1, m=2,
Although the case where l=k=4 and j=8 has been shown, these values may be taken in any way as long as n<m<l≦k≦j.

In addition, in the above embodiment, the first pulse 1 is
The received signal was considered valid if the width of 4 was 8 ms and the space 15 between the leading pulse 14 and the custom code 12 was 4 ms, but the condition of the length of space 15 was determined to be information "1". The pulse interval may be greater than or equal to the pulse interval, for example, 2.5 ms or greater.

Further, in the above embodiment, the transmission code was shown to be transmitted in the order of the leading pulse 14, the custom code 12, and the instruction code 13, but the same effect can be obtained by transmitting the leading pulse 14, the instruction code 13, and the custom code 12 in this order. can get.

[Effects of the Invention] As explained above, the invention described in claim 1 of the present invention modulates and transmits a transmission code having a leading pulse, a custom code, and an instruction code at a specific frequency. In this case, the transmission order is the first pulse, the custom code, and the instruction code, and between the first pulse and the custom code, there is a pulse interval different from the pulse interval indicating information "0" and "1", and the end of the first pulse A first discriminator is provided to recognize the start end of the custom code, and a pulse interval different from the pulse interval indicating information "0" and "1" is provided between the custom code and the instruction code. , a second discriminator is provided to recognize the end of the custom code and the start of the instruction code, so that the receiving side of the system can accurately recognize the custom code in the transmitted code, and This has the effect of preventing recognition errors.

As a result, interference between remote control systems can be reduced, and moreover, the pulse interval in the first discriminator between the first pulse and the custom code or the second pulse interval between the custom code and the instruction code can be reduced.
It is possible to expand custom codes and instruction codes by adjusting the pulse interval in the discrimination section of
By properly configuring the custom code, it can be expanded without interfering with other systems, and many independent remote control systems can be created.

Further, in the invention described in claim 5 of the present invention, the transmission order is the first pulse, the instruction code, and the custom code, and the information "0" and "1" are provided between the first pulse and the instruction code. '' and a pulse interval that is different from the pulse interval indicating ``'', a first discrimination section is provided to recognize the end of the leading pulse and the beginning of the instruction code, and the information ``'' is transmitted between the instruction code and the custom code. 0” and “1”
consists of a pulse interval indicating and a different pulse interval,
Since the second discrimination section for recognizing the end of the instruction code and the start of the custom code is provided for transmission, the same effect as that of the invention described in claim 1 can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a waveform diagram showing a transmission code for explaining an embodiment of the digital remote control method according to the present invention, and FIG. 2 is a system diagram showing a remote control system for explaining the method.
FIG. 3 is a waveform diagram showing pulse intervals (bit intervals) of information "0" and "1", and FIG. 4 is a waveform diagram showing transmission codes for explaining the conventional digital remote control method. 1... Transmission circuit, 2... Receiving circuit, 3... Light emitting section, 4... Light receiving section, 10 and 11... Bit interval, 12... Custom code, 13... Instruction code, 14... Leading pulse, 15...Space (first discrimination section), 16...Space (second discrimination section), 17...Repetition period.

Claims (1)

[Claims] 1. Information “0” depending on the length of the two pulse intervals,
A custom code consisting of a leading pulse that distinguishes "1" and indicates the beginning of the transmission code, multiple bits of information "0" and "1", and prevents interference between different systems, and information "0". In a digital remote control method in which a transmission code having a command code consisting of a plurality of bits of "1" is modulated at a specific frequency and transmitted, the transmission order is the first pulse, the custom code, and the command code, Between the leading pulse and the custom code, a first pulse interval is provided between the leading pulse and the custom code, the pulse interval being different from the pulse interval indicating information "0" and "1", and for recognizing the end of the leading pulse and the beginning of the custom code. A discriminator is provided for transmission, and between the custom code and the instruction code there is a pulse interval different from the pulse interval indicating information "0" and "1", and the end of the custom code and the instruction code are A digital remote control method characterized in that a second discriminator is provided to recognize the starting end. 2 The interval between the two pulses is nt for information "0", mt for information "1", 1t for the first discrimination section, and 1t for the second discrimination section.
kt, the width of the leading pulse is jt, the n, m,
l, k and j are integers, and n<m<l≦k
The digital remote control method according to claim 1, characterized in that the relationship is ≦j. 3 The interval between the two pulses is t for information "0", 2t for information "1", 4t for the first discrimination section, and 4t for the second discrimination section.
4t, and the width of the leading pulse is 8t. The digital remote control method according to claim 1. 4. The digital remote control method according to claim 2 or 3, characterized in that t=1ms. 5 Information “0” depending on the length of the two pulse intervals,
A custom code consisting of a leading pulse that distinguishes "1" and indicates the beginning of the transmission code, multiple bits of information "0" and "1", and prevents interference between different systems, and information "0". In a digital remote control method in which a transmission code having a command code consisting of a plurality of bits of "1" is modulated at a specific frequency and transmitted, the transmission order is the first pulse, the command code, and the custom code, Between the leading pulse and the instruction code, there is a first pulse interval that is different from the pulse interval indicating information "0" and "1", and for recognizing the end of the leading pulse and the beginning of the command code. A discriminator is provided for transmission, and between the instruction code and the custom code there is a pulse interval different from the pulse interval indicating information "0" and "1", and the end of the instruction code and the custom code are A digital remote control method characterized in that a second discriminating section is provided to recognize the starting end. 6 The interval between the two pulses is nt for information "0", mt for information "1", 1t for the first discrimination section, and 1t for the second discrimination section.
kt, the width of the leading pulse is jt, the n, m,
l, k and j are integers, and n<m<l≦k
The digital remote control method according to claim 5, characterized in that the relationship is ≦j. 7 The interval between the two pulses is t for information “0”, 2t for information “1”, 4t for the first discrimination section, and 4t for the second discrimination section.
4t, and the width of the leading pulse is 8t. The digital remote control method according to claim 5. 8. The digital remote control method according to claim 6 or 7, characterized in that t=1ms.