DE4128604A1 - DATA TRANSFER METHOD FOR REMOTE CONTROLS USING PARITY BITS - Google Patents

Description

The present invention relates to a Data transmission method of a remote control grate for controlling an electronic system and in particular to a data transmission method of this type, the Parity bits are used which are the ends of each Subscriber codes and data codes can diminish to thereby the number of bits required for data transmission to diminish remote controlled system.

For the remote control of electrical systems, a master pulse must be given for information that the data code is being transmitted before the Transmission of the data code to be transmitted control electronic system.

Furthermore, the participant code is used to designate a predetermined function of the electrical system from Remote control and then the data code becomes Execution of the assigned function. This means, to remotely control the predetermined electrical system the lead pulse, the subscriber code and the data code required.

However, the participant code and the data code may be due external interference in data transmission from the remote control device be disturbed, causing a system malfunction occurs.

To cause the malfunction of the electrical system Preventing external interference transmits that Remote control device usually one to subscriber code  reverse signal once the subscriber code is transmitted and transmits an inverted signal from the Data codes as soon as the data code is transmitted.

In this case, the electrical system checks the malfunction of the Codes due to external interference by comparing the Participant codes and the data code with their respective reverse codes. If the code is not by outside Normal operation is carried out. However, if the code is disturbed by external interference, then operation is delayed until another code is received because the external disturbance is not just that entire code, but an extreme part of the transmitted Codes affected.

According to this conventional method, the Leitimpuls, the subscriber code, the reverse Participant code and the reverse data code together are transmitted so that the Code transmission increases power consumption, which increases the user forces the batteries of the remote control device to shut down frequently switch.

According to the present invention, a data transmission method for remote controls is proposed which uses parity bits and comprises the following steps:
Emitting a leading pulse after checking a keyboard input according to a keyboard query,
Generating a subscriber code and a parity bit according to the subscriber code,
Generating a data code and a parity bit according to the data code,
Generating a tail output,
Checking successive keystrokes through the keypad prompt after a predetermined delay
Repeating the test to deliver a lead pulse and subsequent codes in the event that successive keystrokes are checked in the fourth step, while the process is completed in the event that successive keystrokes are not checked.

The invention is described below with reference to the Drawings explained in more detail.

Fig. 1 shows a block diagram of the system according to the present invention;

Fig. 2 shows a flowchart of the data transmission method for remote control according to the present invention;

Fig. 3 shows a diagram of waveforms according to the present invention;

FIG. 4 shows a detailed flow diagram of a sequence 2 c in FIG. 2 according to the invention;

FIG. 5 shows a detailed flow diagram of a sequence 2 d in FIG. 2 according to the invention;

Fig. 6 shows a detailed flow diagram of processes 2 e and 2 g in Fig. 2 according to the invention;

Fig. 7 shows a detailed flow chart of output data "0" or "1" in Fig. 6 according to the invention;

Fig. 8 is a detailed flow diagram of a flow 2 f in Fig. 2 according to the invention; and

FIG. 9 is a detailed flow diagram of a flow 2 h in FIG. 2 according to the invention.

Fig. 1 shows a diagram for explaining the data transmission method for the remote control by using parity bits in accordance with the invention.

In Fig. 1, the system includes a keyboard matrix 4 for keyboard input, an external subscriber code setting circuit 3 for setting a subscriber code to eliminate mutual interference with other remote control devices, a microcomputer 1 for querying the keyboard inputs on the keyboard matrix 4 and the subscriber code, which is by the external setting circuit 3 has been set to exclude interference between devices and data codes, with parity bits that follow each subscriber and data code, a transmitter 2 for amplifying and transmitting the output data of the microcomputer 1 to the remote-controlled device, and a power supply device 5 for the power supply of the individual Components.

Fig. 2 shows a flow chart for explaining the method according to the present invention.

In Fig. 2, the method comprises a step P 1 for generating a pilot pulse by checking the keyboard input in accordance with the keyboard query, a step P 2 for generating a subscriber code and a parity bit corresponding to the subscriber code, a step P 3 for generating a data code and one Parity bits corresponding to the data code, a step P 4 for checking the presence of subsequent keystrokes by the keyboard query after generating a tail pulse that delays a predetermined time, and a step P 5 for generating a leading pulse and subsequent codes if the successive keystroke is present while the process is completed if there is no keyboard input.

Fig. 3 is a diagram of waveforms according to the present invention, in which reference numeral 3 is A, the total code course of the remote controller 3 B is a data waveform of 3 A, 3 C shows in expanded form the conduction pulse and the subscriber code from 3 B; and D 3 is a waveform of a subsequent transmission.

FIG. 4 is a detailed flow diagram of flow 2 c in FIG. 2 according to the present invention.

In Fig. 4, the process 2 c includes a process L 1 for setting a delay counter to a predetermined value and for setting the transmitter output to a high state, a process L 2 for checking whether the value of the delay counter is zero or not, one Process L 3 for decelerating by decreasing the predetermined delay counter value step by step when the value of the delay counter in the second process is not zero, a process L 4 for setting the transmitter output to a low state and for resetting the delay counter when the value of the delay counter is in second operation is zero, and an operation L 5 to check whether the delay counter value is zero or not, to decrease the delay counter value step by step after a predetermined time delay if the checked result is not zero, and to output the data if the test result is zero.

FIG. 5 is a detailed flow diagram of flow P 2 in FIG. 2 in accordance with the present invention.

In FIG. 5, the process P 2 contains an operation L 6 for setting a shift counter to a predetermined value as high as the shift number after reading and storing the subscriber code set in the code setting circuit 3 in a subscriber code buffer, an operation L 7 for checking whether is the value of the shift counter is zero or not a process L 8 to complete the operation when the value of the shift counter is equal to zero, while it is checked whether the least significant bit of the subscriber buffer is zero or not when the value of the shift counter is not zero , a process L 9 for incrementing the value of the parity counter step by step after giving the data "0" when the least significant bit of the subscriber counter is zero, while giving data "1" and increasing the parity counter by one when the least significant bit of the subscriber buffer is not zero, and an operation L 10 for shifting the total in the subscriber code buffer stored subscriber buffer data to the right by one digit and to decrease the value of the shift counter.

FIG. 6 is a detailed flow diagram of operations 2 e and 2 g in FIG. 2 in accordance with the present invention.

In Fig. 6, the process 2 e includes an operation L 11 for checking whether the value of the parity counter is odd or not, and an operation L 12 for outputting the data "0" if the value of the parity counter is odd while the data "1" if the value of the parity counter is an even number.

Fig. 7 is a detailed flow chart of operations 6 b and 6 c in Fig. 6 according to the present invention.

In Fig. 7, the flow includes a step 7 a for setting the transmitter output to a high state, a step 7 b for delaying by a predetermined time, a step 7 c for setting the transmitter output to a low state, and a step 7 d for Delay by a predetermined time.

FIG. 8 is a detailed flow diagram of flow 2 f in FIG. 2 in accordance with the present invention.

In Fig. 8, the process 2 f includes an operation L 13 for setting the shift counter to a predetermined value, as well as shift numbers after reading and storing corresponding keyboard data from a table in the data buffer when the keyboard is pressed, an operation L 14 for completing of the process when the value of the shift counter is zero after checking the value of the shift counter, an operation L 15 to output the data "0" when the least significant bit of the data buffer is zero while the data is "1" and the value of the Parity counter is increased if the least significant bit of the data buffer is not zero, and an operation L 16 to shift the stored value of the data to the right and to decrease the shift counter value.

The operation of the present invention will now be explained in more detail with reference to FIGS. 1 to 9.

The microcomputer 1 checks the state of the input / output channels at time intervals and queries the key input state of the keyboard matrix 4 at a predetermined interval in the course 2 a. If during the course of 2 b no button is pressed, the keyboard state is re-queried, is determined to a keyboard input. When the keyboard input has been determined, the master pulse is generated in a time interval T 1 in FIG. 3 ( 3 b) in sequence 2 c.

To give a more detailed description with reference to FIG. 4, the delay counter is set to a predetermined value of the delay time in a process 4 a, and the transmitter output of the microcomputer 1 is set to the high state in a process 4 b.

In the next process, counting continues until the value of the delay counter is "0". That is, the value of the delay counter is gradually reduced when the predetermined value is not "0" in a process c 4, and the predetermined time delay is performed in a process 4 d.

If the delay counter is equal to "0" while the count of the value of the transmitter output of the microcomputer 1 in the process 4 f low is set, and the delay count of the delay time is reset to a predetermined value, which designates a constant time delay in one operation 4 g.

Then the value of the delay counter is checked whether it is "0" or not. This takes place in the process for 4 hours. If the value of the delay counter is "0", the data "0" are output in process 4 k.

If the delay counter is not zero, then the value of the delay counter is gradually decreased until the value "0" is reached after the predetermined time delay in operations 4 i and 4 j.

At this time, the data "0" and "1" are distinguished from each other by the time interval of the low level state, as shown in Fig. 3C.

After the generation of the master pulse in process 2 c, the microcomputer 1 generates the subscriber code, as shown in the time interval T 2 in process 2 d in FIG. 3B.

According to FIG. 5, in order to generate the subscriber code according to FIG. 3B, the predetermined subscriber code, which is supplied by the outer subscriber code setting circuit 3 , is stored in an internal subscriber code buffer in the microcomputer 1 in a process 5 a. The shift counter is as much as the number of shifts set in the predetermined shift value b in a process 5, and the predetermined value of the shift counter is checked whether it is zero or not, in one operation c. 5

If the value of the shift counter in operation 5 c is zero, the process is completed, while if the value of the shift counter is not zero, the least significant bit of the subscriber code is checked whether it is "0" or not, in operation 5 d.

If the least significant bit of the subscriber code is "0", the data will be given "0" while if it is not "0" is then the data "1" is given to the value of the To gradually increase the parity counter.  

After the delivery of the subscriber code bit data and the parity data during the time intervals T 2 and T 3 in FIG. 3 in processes 5 e and 5 i, the subscriber code buffer which stores the subscriber code is shifted to the right by one step in process 5 f, and the The value of the shift counter is reduced.

After the delivery of the subscriber code in process 2 d, the parity data is generated during the interval T 3 in FIG. 3B.

To explain this in detail with reference to FIG. 6:

The parity counter is checked in operation 6a on whether its content is odd or even and if it is odd, then data "1" supplied c in operation 6, while if it is even, the products delivered in this operation, data "0 " are. The parity counter is cleared in process 6 d after the completion of processes 6 b and 6 c.

The detailed process flow for supplying the data "1" or "0" and in processes 6 b and 6 c is shown in FIG. 7.

The transmitter output is set high in process 7 a and the predetermined time is delayed in process 7 b. The transmitter output is then set to low in process 7 c and the predetermined time is delayed again in process 7 d.

After delivery of the parity data in process e 2 of the data code in the process 2 is generated f.

To describe this in more detail with reference to FIG. 8: when the keyboard on the keyboard matrix 4 is pressed in operation 8 a, the microcomputer 1 reads the corresponding keyboard data of the pressed keyboard from the table and stores the read data in the internal data buffer. Subsequently, the shift count to the predetermined value is set to the shift times in the process 8 to determine b, and the value of the shift counter is checked to see if it is the "0" or not, which is done in the process c. 8

If the value of the shift counter is "0", the process is completed. On the other hand, if the value of the shift counter is not "0", the least significant bit of the data buffer is checked for whether it is "0" or not, in operation 8 d.

If the least significant bit is "0", the data is output "0", but if the least significant bit is not "0", the data is output "1" to increase the value of the parity counter in operation 8 i, so that the Number of data "1" is counted thereby.

Then the stored data of the data buffer are shifted to the right by one step in operation 8 f, and the value of the shift counter is reduced.

As a result, the data code parity in the process is 2 g in the time interval T 5 in Fig. 3b generated after the data code for the time interval T 4 in Figure 3B has been delivered..

The detailed flow of data code parity generation is as shown in Figs. 6 and 7.

After the generation of the subscriber code, the data code and each parity code, a tail pulse is delivered in process 2 h and the predetermined delay time is carried out in process 2 i. After a predetermined time, they are checked whether the data input has been successively supplied by the keyboard query or not, in process 2 j.

If the input data have not been supplied in succession by the keyboard query, the process is completed, while if the data are supplied in succession, the lead pulse and the subsequent pulse, as shown in FIG. 3D, are generated again in process 21, comparable to process 2 c to repeat process 2 i. In this case, even after the subsequent pulse has been delivered, the tail pulse is additionally delivered to the receiver in order to inform about the end of the subsequent pulse output. At this point, the subsequent impulses cause the electronic system to continue operating in accordance with the subscriber and data codes already transmitted.

To summarize, the whole process, so far described as follows:

The microcomputer 1 determines the data input from the keyboard matrix 4 by the keyboard interrogation, and when keyboard input is supplied, the microcomputer 1 delivers the lead pulse. After the master pulse has been given, the subscriber code and the parity bit are given in accordance with the subscriber code in order to rule out interference between addressed devices.

For example, if the data number of the subscriber code is "1" is, d. H. is odd, the parity bit becomes "1" while if the data number of the subscriber code is "0", i.e. H. is even, the parity bit becomes "0". It will alternatively in accordance with the requirements of the Selected. After submitting the data code, this will be  Parity bit corresponding to the data code also generated. In Similarly, the parity bit is "0" if the number the data code "1", i.e. H. is odd while that Parity bit is "0" when the number of data code is "0", i.e. H. is an even number. The parity bit is "1" or "0" as Alternative depending on the fact that the data code "0", d. H. is even, depending on the requirements of the transmitter and receiver.

The transmission time between a leading pulse and the next leading pulse must be constant.

By adding each parity bit to the subscriber code and Data code, the present invention can power consumption reduce, so that the remote control for a long time without Battery replacement can be used.

Claims (4)

1. Data transmission method for a remote-controlled system using parity bits, comprising the steps:
Generating a pilot pulse by checking keyboard input in accordance with a keyboard query;
Generating a subscriber code and a parity bit corresponding to the subscriber code;
Generating a data code and a parity bit corresponding to the data code;
Generating a tail pulse;
Checking successive keystrokes with the keypad prompt for a predetermined time delay; and
Repeating the test step of successive keystrokes to deliver a lead pulse and subsequent pulses in the event that the successive keystrokes are detected while the process is completed in the event that successive keystrokes are not detected. 2. The method of claim 1, wherein generating the master pulse comprises the following steps:
Setting a delay counter to determine the value of the delay time and setting a transmit output to a predetermined state;
Check whether the value of the delay counter is zero or not;
Incrementally decreasing the value of the delay counter and delaying the predetermined value if the value of the delay counter is not zero;
Setting the transmit output low and setting the delay counter to another predetermined value of the delay time when the value of the delay counter is zero; and
Determine whether or not the further predetermined value of the delay counter is zero and incrementally decrease the value of the delay value if the value of the delay counter is not zero, while outputting data "0" if the value of the delay counter is zero. 3. The method of claim 1, wherein generating a subscriber code and its parity bit comprises the following steps:
Setting a counter to a predetermined value of shift numbers after reading a subscriber code from an outer subscriber code setting circuit and storing the read code in a register;
Check whether the value of the counter is zero or not;
Completing the process if the value of the counter is zero while checking whether or not a least significant bit of the subscriber code is zero if the value of the counter is not zero;
Incrementally increase the value of the parity counter after the delivery of data "0" if the least significant bit of the subscriber code is zero, while data "1" are issued if the least significant bit of the subscriber code is not zero;
Shifting the register data in which the subscriber code is stored and to decrease the counter value;
Check whether the parity counter value is odd or even; and
Output data "0" if the value of the parity counter is odd, and output data "1" if the value of the parity is even. 4. The method of claim 1, wherein generating a data code and its parity bit comprises the following steps:
Setting a shift counter to a predetermined value of shift numbers after reading its corresponding data from a table and storing the read data in a data buffer when a key is pressed;
Completing the process when the value of the shift counter is zero after checking the value of the shift counter;
Outputting data "0" when a least significant bit of the data buffer is zero, while outputting data "1" to increase the value of the parity counter when the least significant bit of the data buffer is not "0" but "1", and
Shift the value of the data stored in the data buffer to the right to decrease the value of the shift counter.