JPH01119145A - Remote control transmission equipment - Google Patents

Abstract

PURPOSE:To reduce power consumption and to perform transmission even from plural transmitters to a reception side without generating collision simultaneously by deciding a time to the transmission corresponding to an address inherent in the transmitter set by an address input circuit. CONSTITUTION:A clock always oscillated by a second oscillation circuit 15 is frequency-divided to a clock of 100-500ms at a fixed frequency division circuit 14, and a control circuit is operated intermittently by starting up a first oscillation circuit 16. An output interval in the transmission is decided by counting the number (n) of times of the operation of the control circuit by output from the fixed frequency division circuit 14, if the number of times is set constant, the collision is always generated for a long time when plural remote control transmitters start the transmission simultaneously. Therefore, it is possible to generate each different time by changing the number (n) of times of the operation of the control circuit 11 corresponding to an address value set from the outside. In such a way, it is possible to reduce the power consumption and to evade the collision of the transmission.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a remote control transmitting device, and more particularly to a device that transmits data intermittently wirelessly.

Conventional technology Conventionally, when attempting to transmit data from multiple remote control transmitters (hereinafter referred to as remote control transmitters) at the same time, it was common for them to transmit data intermittently and to operate on batteries. Therefore, in order to reduce the transmission power, it is necessary to lengthen the intermittent cycle time, and the intermittent cycle time is generally created by dividing the frequency of a built-in oscillator.

Problems to be Solved by the Invention However, if this intermittent cycle time is created by dividing the frequency using a crystal or ceramic oscillator, the oscillation accuracy is too high, so if - when measuring, multiple remote control transmitters transmit If you start, the intermittent transmission data will match for a long time and will remain in conflict. Therefore, there is a drawback that the receiving side cannot transmit these data.

This oscillator is also used as the controller's system clock, so the oscillation frequency is 400KHz to I
The frequency is as high as MHz, and keeping it oscillating all the time is unsuitable from the standpoint of power consumption.

According to the present invention, a data input circuit that manually inputs data to be transmitted, a control circuit that receives transmission data from the data input circuit and generates an output signal code, and a control circuit that generates an output signal code by receiving transmission data from the data input circuit. a modulation circuit that modulates an output signal code from the circuit; a first oscillation circuit that is controlled by the control circuit and outputs a system clock to the control circuit; a second oscillation circuit that constantly oscillates; In the remote control transmitting device, the control circuit includes a fixed frequency dividing circuit which divides a main clock from an oscillation circuit in a fixed frequency, and the control circuit operates based on the fixed frequency divided clock. A remote control transmitting device characterized by comprising an address input circuit for outputting an address value that determines the number of operations until the control circuit actually outputs an output, to the control circuit that operates according to the provided.

Operation First, an address value n is set in advance in the address input circuit for setting the number of control operations until an output is produced. The clock output from the second oscillation circuit, which always oscillates, is frequency-divided by a fixed frequency divider circuit into a clock having a predetermined frequency.

The control circuit responsive to the frequency-divided clock operates the first oscillation circuit to oscillate the clock.

In this way, the control circuit receives the clock output from the first oscillation circuit and becomes ready for transmission. Each time, the control circuit counts by one. Repeat this action,
When the control circuit counts up to the address value n set in the address input circuit, it outputs a transmission output. As mentioned above, in the remote control transmitter according to the present invention, the output interval for transmission depends on the address value. Therefore, by changing the address value n for each remote control transmitting device, transmission collisions can be avoided.

Embodiment FIG. 1 shows an embodiment of the present invention. The control circuit 11 is RO
This is a software-controlled controller using MSRAM and ALU. The first oscillation circuit 16 is an oscillation circuit for the system clock of this control circuit, and can stop oscillation by the output of the control circuit. The second oscillation circuit 15 is constantly oscillating, and is designed to operate at 32KH so that the operating current is normally 10 to 30 μ8 or less so that it can operate for 1 to 3 years on battery operation.
Z crystal oscillators are commonly used.

The fixed frequency divider circuit 14 is a circuit that divides the frequency of the clock of the second oscillation circuit in advance, and is composed of 10 to 15 stages of flip-flops. As for the output, clocks are output at intervals of 100 to 500 m5. The control circuit activates the oscillation circuit using this output to operate the control circuit. The address input circuit 12 is a circuit for manually inputting a unique address number that each remote control transmitter has, and can be set from the outside. The data input circuit 13 is the data to be transmitted, and the control circuit can also be activated by this input.

Control circuit 11 receives address value n from address input circuit 12 and data from data input circuit 13 . Further, the control circuit 11 operates the first oscillation circuit 16 intermittently in response to the fixed frequency-divided clock from the fixed frequency division circuit 14, and operates the first oscillation circuit 16 in response to the clock from the first oscillation circuit 16. do. As a result, the control circuit 11 controls the modulation circuit 1
7, the transmission data to be modulated is output. The modulation circuit 17 converts the transmission data output of the control circuit 11 into
It modulates to M or AM and outputs it. FIG. 3 shows an example of an output code in the case of MSK modulation.

The present invention will be explained in detail with reference to FIG. The clock constantly oscillated by the second oscillation circuit is divided into 100 by the fixed frequency divider circuit 14.
The frequency is divided down to ~500m5 clock.

The first oscillation circuit is activated by this clock, and the control circuit is operated intermittently. This operating time is 1
It is around ms. This reduces the average power consumption to 1
It has been lowered to a level that allows it to operate for ~3 years.

The output interval for transmission is determined by counting the number of times n of operation of the control circuit based on the output from this fixed frequency dividing circuit. If this number of times is set constant, if multiple remote control transmitters start transmitting at the same time, collisions will always occur over a long period of time.

Therefore, by changing the number of times n of operation of the control circuit until producing an output according to an address value set from the outside, different times can be created for each.

As described in detail, the remote control transmitting device according to the present invention has an oscillation circuit separate from the system clock oscillation circuit used in the control circuit, and uses an output obtained by fixed frequency division of this oscillation circuit to perform intermittent control. The control circuit and the system clock oscillation circuit are operated automatically, and at the same time, the time until transmission is determined according to the unique address of the transmitter set by the address input circuit. This system constitutes a remote control transmitter with extremely low power consumption that is optimal for battery operation, and has the effect that even if multiple transmitters transmit at the same time, the data can be sent to the receiving side without collision.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment of the remote control transmitting device of the present invention, FIG. 2 is a timing diagram of each part of FIG. 1, and FIG. This is an example of the transmission output used, and MSK
Modulation is performed by (Main reference numbers) 11... Control circuit 12... Address input circuit 13... Data input circuit 14... Fixed frequency divider circuit 15... Second oscillation circuit 16... First oscillation circuit 17... Modulation circuit

Claims (1)

[Claims] a data input circuit that inputs data to be transmitted; a control circuit that receives transmission data from the data input circuit and generates an output signal code; a modulation circuit that modulates the output signal code from the control circuit; a first oscillation circuit that is controlled and outputs a system clock to the control circuit;
The control circuit includes a second oscillation circuit that constantly oscillates, and a fixed frequency division circuit that divides the main clock from the second oscillation circuit into the control circuit, and the control circuit operates based on the fixed frequency division clock. In the remote control transmitting device that operates, the control circuit operates in accordance with the fixed frequency divided clock,
A remote control transmitting device comprising an address input circuit for outputting an address value that determines the number of operations until the control circuit actually outputs an output.