CN203520629U

CN203520629U - Startup and shutdown control system

Info

Publication number: CN203520629U
Application number: CN201320642377.8U
Authority: CN
Inventors: 李伟东; 郝寅生
Original assignee: Chuangwei Quanxin Safety And Protection Science And Technology Co Ltd Shenzh
Current assignee: Shenzhen Skyworth Qunxin Security Technology Co Ltd
Priority date: 2013-10-17
Filing date: 2013-10-17
Publication date: 2014-04-02
Anticipated expiration: 2023-10-17

Abstract

The utility model belongs to the field of power switch control, and provides a startup and shutdown control system. The startup and shutdown control system is characterized in that an infrared receiving module is used for receiving startup and shutdown control signals of a remote controller so as to realize the short-distance startup and shutdown control on a main board, and a communication receiving module is used for receiving long-distance startup and shutdown control signals transmitted by a mobile terminal so as to realize the long-distance startup and shutdown control on the main board. The startup and shutdown control system provided by the utility model adopts a dual-control mode and is simple in structure as well as stable and reliable.

Description

A kind of on-and-off control system

Technical field

The utility model belongs to main-board on-off control field, relates in particular to a kind of on-and-off control system.

Background technology

Along with improving constantly of people's quality of life, intelligent mobile terminal (as mobile phone, panel computer etc.) has been broken through traditional these simple functions of just making a phone call, send short messages, surf the Net gradually as our part for life, a lot of people wish to go to change life by enough its, participate in study and work.

Intelligent mobile terminal Remote mainboard carries out switching on and shutting down applications exploiting telepilot remote-control computer main frame in the early time and carries out startup and shutdown.All the time, the remote control of host computer is adopted to wireless remote control, Bluetooth remote control, infra-red remote control, these modes need special gimmick and equipment conventionally, and shortcoming is can remote control but distance is limited, can not realize Remote; A kind of mode is in addition the WOM technology of computer of opening with MODEM, although can realize Remote, but equipment set must connect the mode switch machine by ring by handy telephone wire, shortcoming is that function is more single and when anyone throws phone into, all may trigger computer main board by ring and start shooting, if telephone wire fault, cannot normal boot-strap or more can cause start repeatedly, shutdown because getting lines crossed; Also having a kind of technology is to utilize network interface card arousal function WOL start, shortcoming be it to mainboard, power supply, the requirement of network interface card is all high especially, can only be realized Remote and be arranged loaded down with trivial details by LAN (Local Area Network).

Utility model content

The utility model provides a kind of on-and-off control system, and be intended to solve the control system that existing control mainboard carries out switching on and shutting down and only possess the single remote control control mode of short range telepilot, and the problem that system architecture is complicated, stability is low.

In order to solve the problems of the technologies described above, the utility model is achieved in that a kind of on-and-off control system, comprises the telepilot of transmitting infrared switch machine control signal, and described system is connected with power supply with described mainboard, and described system also comprises:

Receive the infrared receiving module of described infrared switch machine control signal;

Power end is connected with the voltage output end of described power supply, the communications reception module of the remote switch machine control signal that mobile terminal receive sends; And

First signal input end is connected with the output terminal of described communications reception module with the output terminal of described infrared receiving module respectively with secondary signal input end, output terminal is connected with the switching on and shutting down control end of described mainboard, according to the described infrared switch machine control signal receiving or the corresponding control module of controlling described mainboard execution switching on and shutting down operation of described remote switch machine control signal.

The utility model also provides a kind of computer, and described computer comprises as above arbitrary described on-and-off control system.

In the utility model, the switching on and shutting down control signal that receives telepilot by infrared receiving module reaches a kind of and closely mainboard is carried out to switching on and shutting down control, the remote switch machine control signal sending by communications reception module mobile terminal receive is realized the long-range control to main-board on-off, the on-and-off control system that the utility model provides possess dual control mode and simple and stable structure reliable.

Accompanying drawing explanation

Fig. 1 is the modular structure figure of the on-and-off control system that provides of the utility model embodiment;

Fig. 2 is the circuit structure diagram of the on-and-off control system that provides of the utility model embodiment;

Fig. 3 is the circuit structure diagram of the on-and-off control system that provides of another embodiment of the utility model.

Embodiment

In order to make the purpose of this utility model, technical scheme and advantage clearer, below in conjunction with drawings and Examples, the utility model is further elaborated.Should be appreciated that specific embodiment described herein is only in order to explain the utility model, and be not used in restriction the utility model.

Below in conjunction with specific embodiment, specific implementation of the present utility model is described in detail:

Fig. 1 shows the modular structure of the on-and-off control system that the utility model embodiment provides, and for convenience of explanation, only lists the part relevant to the utility model embodiment.

As shown in Figure 1, the on-and-off control system that the utility model embodiment provides comprises the telepilot 201 of transmitting infrared switch machine control signal, this system is connected with power supply 300 with mainboard 100, power supply 300 is connected with alternating current AC, power supply 300 obtains operating voltage by alternating current AC and to mainboard 100, provides operating voltage simultaneously, and this system also comprises:

Receive the infrared receiving module 202 of this infrared switch machine control signal;

Power end is connected with the voltage output end of power supply 300, the communications reception module 203 of the remote switch machine control signal that mobile terminal receive 400 sends; And

First signal input end INT1 is connected with the output terminal of communications reception module 203 with the output terminal of infrared receiving module 202 respectively with secondary signal input end INT2, output terminal is connected with the switching on and shutting down control end PB1 of mainboard 100, according to this infrared switch machine control signal receiving or the corresponding mainboard 100 of controlling of this remote switch machine control signal, carries out the control module 204 that switching on and shutting down operate.

In the utility model embodiment, infrared receiving module 202 mates with the infrared transmission module in telepilot 201, for closely realizing mainboard 100 carried out to switching on and shutting down control by telepilot 201, the switching on and shutting down control signal sending by communications reception module 203 mobile terminal receives 400 is controlled mainboard 100 and is carried out start or power-off operation, in the utility model embodiment, the voltage output end of power supply 300 comprises standby voltage output terminal+VCC_STB0 and operating voltage output terminal+VCC0, in the utility model embodiment, mainboard 100 is arranged at host computer, air-conditioning, washing machine, in the equipment such as refrigerator, be that the on-and-off control system that the utility model embodiment provides both can closely be controlled host computer with telepilot, televisor, refrigerators etc. carry out switching on and shutting down operation, can also pass through mobile phone, the mobile terminals such as panel computer send remote switch machine control signal and control host computer, televisor, refrigerators etc. carry out switching on and shutting down operation.

As shown in Figure 2, as the utility model one embodiment, communications reception module 202 comprises:

The first diode D1, the second diode D2, light emitting diode D3, the first resistance R 1, the second resistance R 2, the 3rd resistance R 3, the 4th resistance R 4, the 5th resistance R 5, the 6th resistance R 6, the 7th resistance R 7, the 8th resistance R 8, the 9th resistance R 9, the first capacitor C 1, the second capacitor C 2, the 3rd capacitor C 3, the 4th capacitor C 4, the 5th capacitor C 5, the 6th capacitor C 6, the 7th capacitor C 7, the 8th capacitor C 8, the 9th capacitor C 9, the tenth capacitor C 10, the first crystal oscillator Y1, NPN type triode Q1, the first photoelectrical coupler U1, the second photoelectrical coupler U2, communication chip U3, the first single-chip microcomputer U4, power management chip U5 and sim card slot,

The voltage input end VIN of power management chip U5 is connected with the standby voltage output terminal+VCC_STB0 of power supply 300 with the first end of the tenth capacitor C 10, the second end ground connection of the tenth capacitor C 10, the first end of the tenth capacitor C 10 is the standby voltage input end+VCC_STB of communications reception module 203, the voltage output end VOUT of power management chip U5 is connected with the first end of the first end of the 9th capacitor C 9 and the 9th resistance R 9, the second end ground connection of the 9th capacitor C 9, the tenth resistance R 10 is connected between second end and ground of the 9th resistance R 9, the second end of the 9th resistance R 9 is also connected with the adjustable side ADJ of power management chip U5, the first end of the 9th resistance R 9 is the operating voltage input end+VCC of communications reception module 203, the first end of the 8th resistance R 8 is connected with the operating voltage output terminal+VCC0 of power supply 300, the anodic bonding of light emitting diode in the second end of the 8th resistance R 8 and the second photoelectrical coupler U2, the negative electrode of light emitting diode and the output head grounding of light-receiving device in the second photoelectrical coupler U2, in the second photoelectrical coupler U2, the input end of light-receiving device is connected with the first input/output terminal I/O1 of the first single-chip microcomputer U4, in the first photoelectrical coupler U1, the anode of light emitting diode is connected with standby voltage input end+VCC_STB, the 5th resistance R 5 is connected between the negative electrode of light emitting diode in the first photoelectrical coupler U1 and the second input/output terminal I/O2 of the first single-chip microcomputer U4, the output head grounding of the light-receiving device in the first photoelectrical coupler U1, in the first photoelectrical coupler U1, the startup pin IGT of the input end of light-receiving device and the first end of the 6th resistance R 6 and communication chip U3 is connected, the second end of the 6th resistance R 6 is connected with operating voltage input end+VCC, the anode of the first diode D1 is connected with the data transmission pin TXD of communication chip U3, the negative electrode of the first diode D1 is connected with the data receiver RXD of the first single-chip microcomputer U4 with standby voltage input end+VCC_STB, the data transmission terminal TXD of the first single-chip microcomputer U4 and the anodic bonding of the second diode D2, the negative electrode of the second diode D2 is connected with the data receiver pin RXD of operating voltage input end+VCC and communication chip U3, the power end VIN of the first single-chip microcomputer U4 is connected with the first end of the first capacitor C 1 with standby voltage input end, the second end ground connection of the first capacitor C 1, the first end of the first end of the first crystal oscillator Y1 and the 5th capacitor C 5 is connected with the 3rd input/output terminal I/O3 of the first single-chip microcomputer U4, the second end of the first crystal oscillator Y1 is connected with the first external crystal oscillator pin XTAL1 of the first single-chip microcomputer U4 with the first end of the 6th capacitor C 6, the second end of the second end of the 5th capacitor C 5 and the 6th capacitor C 6 is connected to ground altogether, the first end of the 7th resistance R 7 is connected with the second external crystal oscillator pin XTAL2 of the first single-chip microcomputer U4, the second end of the 7th resistance R 7 is the signal output part B of communications reception module 203, the second capacitor C 2 and the 3rd capacitor C 3 and the 4th capacitor C 4 be connected in parallel and the first end of the first resistance R 1 between, the power end VIN of the first end of the first resistance R 1 and communication chip U3 is connected with operating voltage input end+VCC, the 4th resistance R 4 is connected between the base stage of NPN type triode Q1 and the control pin SYNC of communication chip U3, the anode of light emitting diode D3 is connected with the second end of the first resistance R 1, the negative electrode of light emitting diode D2 is connected with the collector of NPN type triode Q1, the grounded emitter of NPN type triode Q1, pin in sim card slot and the corresponding connection of SIM pin in communication chip U3, the 7th C7 electric capacity and the 8th capacitor C 8 are connected in parallel between the 28 pin and the 29 pin of communication chip U3.

In the utility model embodiment, preferably, communication chip U3 is that model is the communication chip of TC351, the model of the first single-chip microcomputer U4 is STC11F04E, the model of power management chip U5 is AMS1117-ADJ, these are only the chip selection scheme of the utility model embodiment the best, can also adopt other chips with similar functions to replace, in the utility model embodiment, the first end of the 8th resistance R 8 is connected with the operating voltage output terminal+VCC0 of power supply 300, the duty of the operating voltage detecting master plate 100 of exporting by power supply 300, power supply 300 still has and is connected and provides standby voltage to communications reception module 203 and mainboard 100 with alternating current AC in the situation that of mainboard 100 shutdown.

In the utility model embodiment, when writing remote controller key rule, the start of infrared receiving module 202 outputs or pass machine control signal are arranged to specific binary coded format, such as start is set to 01101010, shutdown is set to 10010101, after control signal is input in control module 204, after control module 204 is processed, export to mainboard 100 so, control corresponding start or the power-off operation carried out of mainboard 100.

As shown in Figure 3, as the utility model one embodiment, control module 204 comprises:

Second singlechip U6, the 11 capacitor C the 11, the 12 capacitor C the 12, the 13 capacitor C the 13, the 14 capacitor C the 14, the 15 capacitor C the 15, the 11 resistance R 11 and the second crystal oscillator Y2;

The 11 first end of capacitor C 11 and the first end of the 12 capacitor C 12 are connected with the power end VIN of standby voltage input end+VCC_STB and second singlechip U6, the second end of the 11 capacitor C 11 and the second end of the 12 capacitor C 12 are connected to ground altogether, the second first end of crystal oscillator Y2 and the first end of the 13 capacitor C 13 are connected with the first external crystal oscillator pin XTAL1 of second singlechip U6, the second end of the second crystal oscillator Y2 and the first end of the 14 capacitor C 14 are connected with the second external crystal oscillator pin XTAL2 of second singlechip U6, the second end of the 13 capacitor C 13 and the second end of the 14 capacitor C 14 are connected to ground altogether, the first signal input end INT1 of second singlechip U6 is connected with the signal output part of infrared receiving module 202, the secondary signal input end INT2 of second singlechip U6 is connected with the second end of the 7th resistance R 7, the 14 resistance R 14 is connected in series in restarting between end RESET of standby voltage input end+VCC_STB and second singlechip U6, the 15 capacitor C 15 is connected to restarting between end RESET and ground of second singlechip U6, the control signal output terminal of second singlechip U6 is connected with the switching on and shutting down control end PB1 of mainboard 100.

In the utility model embodiment, the model of second singlechip U6 is ATmega8, and second singlechip U6 can also select other to have the singlechip chip of similar functions.

Especially, in the utility model embodiment, in communications reception module 203, the first single-chip microcomputer U4 is identical through start or the pass machine control signal binary coded format of the start of the 7th resistance R 7 outputs or the binary coded format of pass machine control signal and infrared receiving module 202 outputs, if the switching on and shutting down control signal of infrared receiving module 202 outputs is A, the switching on and shutting down control signal of communications reception module 203 outputs is B, when signal A and signal B are input to respectively in control module 204, by priority level default in second singlechip U6, signal A and signal B are selected, due to the sequencing in sequential, when signal A then first, second singlechip U6 exports a-signal, when signal B then first, second singlechip U6 output B signal, when signal A and signal B then simultaneously, according to default priority level, for example preset signals A's is superior to signal B, binary coding corresponding to output signal A, also can signalization A priority level lower than signal B, now, binary coding corresponding to second singlechip U6 output signal B.Because signal A and signal B signal have identical coding rule, so second singlechip U6 output signal A or signal B are to time mainboard 100 switching on and shutting down control ends, all can realize start or shut-off function, the on-and-off control system that the utility model adopts is more intelligent, operation is human nature more also, can purchase and at a distance the equipment that will control (mainboard) carried out to switching on and shutting down control.

The principle of work of the Long-distance Control mainboard start below the utility model embodiment being provided or the system of shutdown describes, and details are as follows:

The remote switch machine control signal that communications reception module 203 sends for mobile terminal receive (such as mobile phone etc.), telepilot 201 also can be to infrared receiving module 202 transmit button machine control signals, control module 204 receives the binary coding corresponding with switching on and shutting down control signal from communications reception module 203 and infrared receiving module 202 outputs, through control module 204, carry out exporting after processed output, in mainboard 100, processor chips receive this binary coding corresponding start or the power-off operation carried out.

The utility model embodiment also provides a kind of computer, comprises on-and-off control system as above.

In the utility model embodiment, what be provided with above-mentioned on-and-off control system also includes but not limited to it is the equipment such as televisor, refrigerator, air-conditioning.

In the utility model embodiment, the switching on and shutting down control signal that receives telepilot by infrared receiving module reaches a kind of closely control to main-board on-off, the remote switch machine control signal sending by communications reception module mobile terminal receive is realized the long-range control to main-board on-off, the on-and-off control system that the utility model provides possess dual control mode and simple and stable structure reliable.

The foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all any modifications of doing within spirit of the present utility model and principle, be equal to and replace and improvement etc., within all should being included in protection domain of the present utility model.

Claims

1. an on-and-off control system, comprises the telepilot of launching infrared switch machine control signal, and described system is connected with power supply with mainboard, it is characterized in that, described system also comprises:

2. on-and-off control system as claimed in claim 1, is characterized in that, described communications reception module comprises:

The first diode, the second diode, light emitting diode, the first resistance, the second resistance, the 3rd resistance, the 4th resistance, the 5th resistance, the 6th resistance, the 7th resistance, the 8th resistance, the 9th resistance, the first electric capacity, the second electric capacity, the 3rd electric capacity, the 4th electric capacity, the 5th electric capacity, the 6th electric capacity, the 7th electric capacity, the 8th electric capacity, the 9th electric capacity, the tenth electric capacity, the first crystal oscillator, NPN type triode, the first photoelectrical coupler, the second photoelectrical coupler, communication chip, the first single-chip microcomputer, power management chip and sim card slot,

The first end of the voltage input end of described power management chip and described the tenth electric capacity is connected with the standby voltage output terminal of described power supply, the second end ground connection of described the tenth electric capacity, the first end of described the tenth electric capacity is the standby voltage input end of described communications reception module, the voltage output end of described power management chip is connected with the first end of described the 9th electric capacity and the first end of described the 9th resistance, the second end ground connection of described the 9th electric capacity, the tenth resistance is connected between second end and ground of described the 9th resistance, the second end of described the 9th resistance is also connected with the adjustable side of described power management chip, the first end of described the 9th resistance is the operating voltage input end of described communications reception module, the first end of described the 8th resistance is connected with the operating voltage output terminal of described power supply, the anodic bonding of light emitting diode in the second end of described the 8th resistance and described the second photoelectrical coupler, the negative electrode of light emitting diode and the output head grounding of light-receiving device in described the second photoelectrical coupler, in described the second photoelectrical coupler, the input end of light-receiving device and the first input/output terminal of described the first single-chip microcomputer are connected, in described the first photoelectrical coupler, the anode of light emitting diode is connected with described standby voltage input end, described the 5th resistance is connected in described the first photoelectrical coupler between the negative electrode of light emitting diode and the second input/output terminal of described the first single-chip microcomputer, the output head grounding of the light-receiving device in described the first photoelectrical coupler, in described the first photoelectrical coupler, the startup pin of the input end of light-receiving device and the first end of described the 6th resistance and described communication chip is connected, the second end of described the 6th resistance is connected with described operating voltage input end, the anode of described the first diode is connected with the data transmission pin of described communication chip, the negative electrode of described the first diode is connected with the data receiver of described the first single-chip microcomputer with described standby voltage input end, the anodic bonding of the data transmission terminal of described the first single-chip microcomputer and described the second diode, the negative electrode of described the second diode is connected with the data receiver pin of described operating voltage input end and described communication chip, the power end of described the first single-chip microcomputer is connected with the first end of described the first electric capacity with described standby voltage input end, the second end ground connection of described the first electric capacity, the first end of the first end of described the first crystal oscillator and described the 5th electric capacity is connected with the 3rd input/output terminal of described the first single-chip microcomputer, the second end of described the first crystal oscillator is connected with the first external crystal oscillator pin of described the first single-chip microcomputer with the first end of described the 6th electric capacity, the second end of the second end of described the 5th electric capacity and described the 6th electric capacity is connected to ground altogether, the first end of described the 7th resistance is connected with the second external crystal oscillator pin of described the first single-chip microcomputer, the second end of described the 7th resistance is the signal output part of described communications reception module, described the second electric capacity and described the 3rd electric capacity and described the 4th Capacitance parallel connection be connected to and the first end of described the first resistance between, the first end of described the first resistance is connected with described operating voltage input end with the power end of described communication chip, described the 4th resistance is connected between the base stage of described NPN type triode and the control pin of described communication chip, the anode of described light emitting diode is connected with the second end of described the first resistance, the negative electrode of described light emitting diode is connected with the collector of described NPN type triode, the grounded emitter of described NPN type triode, pin in described sim card slot and the corresponding connection of SIM pin in described communication chip, described the 7th electric capacity and described the 8th Capacitance parallel connection are connected between the 28 pin and the 29 pin of described communication chip.

3. on-and-off control system as claimed in claim 2, is characterized in that, described control module comprises:

Second singlechip, the 11 electric capacity, the 12 electric capacity, the 13 electric capacity, the 14 electric capacity, the 15 electric capacity, the 11 resistance and the second crystal oscillator;

Described the 11 first end of electric capacity and the first end of described the 12 electric capacity are connected with the power end of described standby voltage input end and described second singlechip, the second end of described the 11 electric capacity and the second end of described the 12 electric capacity are connected to ground altogether, the first end of described the second crystal oscillator is connected with the first external crystal oscillator pin of described second singlechip with the first end of described the 13 electric capacity, the second end of described the second crystal oscillator and the first end of described the 14 electric capacity are connected with the second external crystal oscillator pin of described second singlechip, the second end of described the 13 electric capacity and the second end of described the 14 electric capacity are connected to ground altogether, the first signal input end of described second singlechip is connected with the signal output part of described infrared receiving module, the secondary signal input end of described second singlechip is connected with the second end of described the 7th resistance, described the 14 resistance is connected in series in restarting between end of described standby voltage input end and described second singlechip, described the 15 electric capacity is connected to restarting between end and ground of described second singlechip, the control signal output terminal of described second singlechip is connected with the switching on and shutting down control end of described mainboard.

4. a computer, is characterized in that, described computer comprises the on-and-off control system as described in as arbitrary in claim 1-3.