CN201716854U

CN201716854U - Learning transponder and remote controller and integrated control system provided with same

Info

Publication number: CN201716854U
Application number: CN2010202624628U
Authority: CN
Inventors: 王志良; 彭海银
Original assignee: Individual
Current assignee: Individual
Priority date: 2010-07-19
Filing date: 2010-07-19
Publication date: 2011-01-19
Anticipated expiration: 2020-07-19

Abstract

The utility model discloses a learning transponder and a remote controller and an integrated control system which are provided with the learning transponder, wherein the learning transponder is used for receiving and learning as well as restoring and transponding of infrared remote control signals and comprises a main control chip, a signal receiving circuit, a signal transmitting circuit and a memory, wherein the signal receiving circuit and the signal transmitting circuit are both connected with the main control chip and used for receiving and transmitting the infrared remote control signals; the memory is arranged in or externally connected with the main control chip so as to store high-low level width data; the main control chip consists of a control module used for controlling the learning and transponding, and a learning module for detecting the infrared remote control signals of external equipment, received by the signal receiving circuit, when receiving a learning instruction, measuring the level width data and storing the measured level width data in the memory; and when receiving the transponding instruction, a transponding module reads level width data, and generates and transmits the infrared remote control signals by the signal transmitting circuit so as to control the external equipment. The utility model realizes the integrated control on different external equipment by learning the infrared remote control signals of different external equipment.

Description

Study transponder and have the telepilot and the integrated control system of this study transponder

Technical field

The utility model relates to a kind of infrared remote-control device of external unit, relates in particular to a kind of telepilot and integrated control system of learning transponder and having this study transponder.

Background technology

Along with the raising of living standards of the people, the external unit of band infrared remote control, for example household electrical appliance are of a great variety, such as TV, air-conditioning, VCD, intelligent electric light, fish jar etc.But, because various device all carries telepilot, the infrared remote coding form difference of following, make that the telepilot of various products can not be compatible, the user in use often need operate different telepilots all kinds of household electrical appliances are controlled, not only cause obscuring of telepilot easily, and the easier telepilot that causes of the telepilot of One's name is legion loses, this has brought inconvenience to daily life.

At present, so-called " universal remote control " that occurs on the market, be the remote control mode or the coding rule of storage part brand electrical equipment in advance mostly in telepilot inside, need strict during use to realizing control after the sign indicating number coupling, complicated operation not only, and the external unit that can control is limited, and poor compatibility is not real " omnipotent "; These telepilots lack data-interface, and extendability is not strong; Carrier modulation and data memory module adopt the peripheral hardware circuit to realize that cost is higher.

The utility model content

Can not compatible deficiency for the telepilot that overcomes prior art, the purpose of this utility model is to provide a kind of reception study of infrared remote-controlled signal and study transponder that reduction is transmitted of being used for, and realizes low-cost, high reliability and compatibility.

Another purpose of the present utility model is to provide a kind of telepilot with the utility model study transponder.

The 3rd purpose of the present utility model is to provide a kind of integrated control system with the utility model study transponder.

For achieving the above object, the technical solution of the utility model is as follows:

A kind of study transponder, the reception study and the reduction that are used for infrared remote-controlled signal are transmitted, and this study transponder comprises: a main control chip; One signal receiving circuit is connected in described main control chip, is used to receive described infrared remote-controlled signal; One signal transmission circuit is connected in described main control chip, is used to launch described infrared remote-controlled signal; One storer is built in or is external in described main control chip, is used to store the high-low level width data of many group infrared remote-controlled signals; Described main control chip comprises: a control module is used to control the study and the forwarding of described study transponder; One study module when receiving the learn command that described control module transmits, detects the described infrared remote-controlled signal of the external unit that described signal receiving circuit receives, and measures the high-low level width data of described infrared remote-controlled signal and is stored in described storer; One forwarding module, when receiving the forwarding instruction that described control module transmits, read and generate the infrared emission signal, launch described infrared remote-controlled signal to control described external unit by described signal transmission circuit according to the described high-low level width data that described storer is stored.

Study transponder of the present utility model, preferred, described study transponder also comprises a condition indication circuit, is connected in described main control chip, this indicating circuit comprises that at least one is in order to indicate the LED light of described study repeater operation state.

Study transponder of the present utility model, preferred, described study module comprises: initial recognition unit, in order to the initial low level of the identification described infrared remote-controlled signal of expression; The pulse width measure unit, detect after the described low level finish to described infrared remote-controlled signal before, measure the high-low level width data of described infrared remote-controlled signal, and be temporary among the RAM; Finish identifying unit, current high level width data and the setting threshold of storing among the described RAM compared, when described width data is judged described infrared remote-controlled signal end during greater than described setting threshold; Storage unit after described end identifying unit judges that described infrared remote-controlled signal finishes, is stored in described storer with the described high-low level width data of storing among the described RAM.

Study transponder of the present utility model, preferably, described forwarding module, comprise reading unit, modulating unit, carrier wave generation unit and output unit, described reading unit reads the high-low level pulse-width data of described memory stores, generate square wave by described carrier wave generation unit, be modulated to the high-low level pulse signal, export to described signal transmission circuit by output unit by modulating unit; Described signal transmission circuit comprises first current-limiting resistance, second current-limiting resistance, triode and infraluminescence diode, the high-low level pulse signal that described forwarding module is transmitted, through the described first current-limiting resistance current limliting, amplify through described triode, the described high-low level pulse signal after the amplification is launched through the described infrared transmitting tube of the described second current-limiting resistance current limliting rear drive again.

Study transponder of the present utility model, preferred, described main control chip is a STC Series chip, an ARM chip or a fpga chip.

Study transponder of the present utility model, preferred, described main control chip is the STC89C58RD+ single-chip microcomputer, and described signal receiving circuit and signal transmission circuit are connected to the pin of described STC89C58RD+ single-chip microcomputer, and described storer is the built-in E of described single-chip microcomputer ²Prom memory, described setting threshold are and the corresponding high level width data of duration 49ms.

Study transponder of the present utility model, preferably, described main control chip also comprises serial ports monitoring module, described study transponder also comprises a serial communication circuit, described serial communication circuit is connected in described serial ports and monitors module, and described serial ports is monitored module and monitored the control command that transmits by described serial communication circuit.

A kind of telepilot, has a shell, has button on the described shell, be provided with study transponder of the present utility model in the described shell, in the described button, have a button at least, be used to control the study of described study transponder, and described telepilot is by different buttons, at least two external units of remote control.

A kind of integrated control system, described integrated control system comprises: a study transponder, it is a study transponder of the present utility model; One host computer is connected in described study transponder, controls the study and the forwarding of described study transponder.

Integrated control system of the present utility model, preferably, described study transponder has a serial communication circuit, described serial communication link tester crosses Serial Port Line or wireless serial equipment is connected with described host computer, described host computer is PC, hand held controller, palm PC or mobile phone, and described host computer has by wireless access way or has line access mode to insert the access device of internet.

The beneficial effects of the utility model are, adopt study to receive the mode of transmitting with reduction, the control function of numerous Infrared remote controller can be concentrated on a telepilot or an integrated control system, reach the purpose of " control is many ", and the reliability height is compatible strong; Study transponder of the present utility model adopts software to produce modulated square wave and adopts internal memory access high-low level pulse-width data, and cost is low, access speed is fast; Study transponder of the present utility model can have data communication interface, and extensibility is strong; The chaotic worry of easily losing of telepilot in the modern digital family can not only be effectively solved, and the concentrated controling management of household electrical appliances can be realized.

Below in conjunction with drawings and Examples the utility model is further specified.

Description of drawings

Fig. 1 is the modular structure figure of the study transponder of the utility model embodiment.

Fig. 2 A is the condition indication circuit figure of the study transponder of the utility model embodiment.

Fig. 2 B is the crystal oscillating circuit figure of the study transponder of the utility model embodiment.

Fig. 2 C is the serial communication circuit figure of the study transponder of the utility model embodiment.

Fig. 2 D is the power circuit diagram of the study transponder of the utility model embodiment.

Fig. 2 E is the signal receiving circuit figure of the study transponder of the utility model embodiment.

Fig. 2 F is the signal transmission circuit figure of the study transponder of the utility model embodiment.

Fig. 2 G is the serial ports synoptic diagram of the study transponder of the utility model embodiment.

Fig. 3 is the modular structure figure of the integrated control system of the utility model embodiment.

Fig. 4 is the control flow chart of the integrated control system of the utility model embodiment.

Fig. 5 is the workflow diagram of study module of the study transponder of the utility model embodiment.

Fig. 6 is the workflow diagram of forwarding module of the study transponder of the utility model embodiment.

Embodiment

Some exemplary embodiments that embody the utility model feature and advantage will be described in detail in the following description.Be understood that the utility model can have various variations on different embodiment, its neither disengaging protection domain of the present utility model, and explanation wherein and accompanying drawing be when the usefulness that explain in itself, but not in order to restriction the utility model.

The utility model has been realized an opertaing device (as telepilot) or a control system (as integrated control system), controls the infrared remote-controlled signal control (described external unit includes but not limited to: TV, air-conditioning, VCD, DVD, infrared remote control light fixture etc. can by the equipment of infrared remote-controlled signal control) of a plurality of external units.

Study transponder of the present utility model can be used for telepilot of the present utility model and integrated control system of the present utility model, but is not limited to this, also can be used for other opertaing device and control system.

Below introduce the integrated control system of the utility model embodiment earlier.

The integrated control system of the utility model embodiment comprises the study transponder of host computer and the utility model embodiment, and described study transponder is provided with serial communication circuit, be used for and described host computer between communicate.Wherein, described host computer can be PC (comprising desktop computer, notebook computer), palm PC, hand held controller (handheld device that promptly has control function) or mobile phone etc.

As shown in Figure 1, the study transponder of the utility model embodiment comprises main control chip, storer, signal receiving circuit, signal transmission circuit and serial communication circuit.Infrared receiving circuit is selected infrared integrated reception head for use, and the infrared integrated head that receives is with the detection of infrared remote-controlled signal process, shaping, amplification, the demodulation carrier signal that receive, and final output signal is the TTL high-low level.

Described main control chip, STC89C58RD+ single-chip microcomputer preferably also can be selected other single-chip microcomputer of STC series certainly for use, also can select ARM chip or fpga chip for use.

Described signal receiving circuit and signal transmission circuit are connected to the pin of described STC89C58RD+ single-chip microcomputer, and described storer is the built-in E of described STC89C58RD+ single-chip microcomputer ²Prom memory.Inner integrated E ²Prom memory is used for storing the high-low level width data of the infrared remote-controlled signal of learning, and not only access speed is fast, and compares with outer extension memory, and cost is lower.

Shown in Fig. 2 A-Fig. 2 F, output terminal as the infrared integrated receiving tube HS0038B of signal receiving circuit links to each other with the pin P3.5 of STC89C58RD+ single-chip microcomputer, signal transmission circuit comprises current-limiting resistance R7, triode 9012, current-limiting resistance R8, infrared transmitting tube SE303, the pin P2.3 of STC89C58RD+ single-chip microcomputer links to each other with current-limiting resistance R7 one end, the current-limiting resistance R7 other end links to each other with triode 9012 base stages, 9012 emitters connect positive source, 9012 collectors link to each other with current-limiting resistance R8 one end, the current-limiting resistance R8 other end links to each other the SE303 minus earth with infrared transmitting tube SE303 is anodal.Wherein, current-limiting resistance R7 gets hundreds of ohm, and for example 300,500,700 ohm, current-limiting resistance R8 gets tens ohm, for example 10,20 ohm.

Shown in Fig. 2 C, the electrifying of serial communication circuit flatted turn and changed and (Transistor-Transistor Logic level of STC89C58RD+ single-chip microcomputer output be converted to the RS232 level that the serial ports of serial communication circuit can be used, prevent that serial ports from burning) effect

conversion chip MAX232

9,10 pins respectively with the pin P3.0 of STC89C58RD+ single-chip microcomputer, P3.1 links to each other, 7 of conversion chip MAX232,8 pins respectively with 2 of the serial ports of serial communication circuit, 3 pins link to each other, 1 and 3 of conversion chip MAX232,4 are connected electrochemical capacitor CD1 respectively with 5 pins, the positive pole of CD2 and negative pole, the 15 pin ground connection of conversion chip MAX232,6 pins of conversion chip MAX232 connect the positive pole of electrochemical capacitor CD3, the CD3 minus earth, shown in Fig. 2 D, 16 pins of conversion chip MAX232 meet power supply VCC, 2 pins of conversion chip MAX232 connect electrochemical capacitor CD4 positive pole, electrochemical capacitor CD4 minus earth.7 and 8 pins of conversion chip MAX232 connect 2 and 3 pins of serial ports respectively.Shown in Fig. 2 B, crystal oscillator X1 two ends connect capacitor C 1 respectively, the pin of C2, another pin ground connection of capacitor C 1, C2.

Shown in Fig. 2 A, the LED light negative pole of condition indication circuit connects the corresponding pin of STC89C58RD+ single-chip microcomputer, and positive pole meets VCC by resistance.The study transponder of the utility model embodiment, its condition indication circuit can comprise study pilot lamp, emission pilot lamp, storage pilot lamp and power light, but are not limited to this.

As shown in Figure 3, integrated manipulator of the present utility model, when needing the described infrared remote-controlled signal of study, by host computer by serial ports transmitting control commands signal to main control chip, carry out the study of described infrared remote-controlled signal by main control chip control study module; In the time of need transmitting described infrared remote-controlled signal (when needing certain external unit of remote control), pass through serial ports transmitting control commands signal to main control chip by host computer, carry out the forwarding of described infrared remote-controlled signal by main control chip control forwarding module, with the infrared remote control equipment action of control appointment.Adopt universal intelligent control protocol (GICP) to communicate between described host computer and the serial ports, can stop to disturb, prevent maloperation.

The study transponder of the utility model embodiment, study module comprises initial recognition unit, the pulse width measure unit, finish identifying unit and storage unit, after control module is sent learn command, study module promptly enters learning state, the study pilot lamp of on-state indicating circuit, described pilot lamp for example is a LED light, the initial recognition unit of study module, begin to detect whether the infrared remote-controlled signal input is arranged (whether an infrared integrated reception output terminal that promptly detects as infrared receiving circuit has the initial low level of the described infrared remote-controlled signal of expression to produce), can set, if there is not the infrared remote-controlled signal input in 1 second, then withdraw from learning state, close the study pilot lamp.If detected the infrared remote-controlled signal input in 1 second, then begun described infrared remote-controlled signal to be measured by the pulse width measure unit.

The pulse width measure unit adopts the method for width counting to measure pulsewidth and temporary to the high-low level of described infrared remote-controlled signal, when study module recognizes the low level of the described infrared remote-controlled signal initial code of expression, described low level is gathered, begin the low level pulsewidth of being gathered is counted by for circulation accumulated counts, when described low level finishes, in RAM, (store a series of pwm values with current low-level pulse width count value is temporary with the array form, first identification label that is set at the pairing external unit of the described infrared remote-controlled signal of storage of array), the pulsewidth counter O reset also begins counting to the high level that and then arrives, and the pulse width data value of the described infrared remote-controlled signal that will collect successively is temporary in RAM then; (described setting threshold both can be the duration data if the current high level pulse width value of the described infrared remote-controlled signal of storing among the RAM that collects (value of last storage of array just) is greater than setting threshold, also can be pulse width data, before comparing, do corresponding conversion according to circumstances), just think that described infrared remote-controlled signal finishes, close the study pilot lamp, enter high-low level width data (also can be described as pulse-width data) store status, open the storage pilot lamp, storage unit writes the high-low level pulse-width data among the RAM E of single-chip microcomputer inside ²Prom memory, these data write with the array form, with 0 ending; Close the storage pilot lamp after data write and finish, study module finishes the study of described infrared remote-controlled signal.

Study transponder of the present utility model, its forwarding module comprises reading unit, modulating unit, carrier wave generation unit, output unit, and when the control command of main control chip was " forwarding ", the study transponder entered forwarding state, the emission pilot lamp lights, and reading unit is from E ²Take out corresponding high-low level pulse-width data in the prom memory successively, the carrier wave generation unit starts timer to interrupt producing square-wave pulse signal, and modulating unit goes the output of modulated square wave pulse signal by low level.The working time of timer this moment determined by corresponding infrared remote-controlled signal low level width count value, if when promptly needing the remote signal of emission to be high level, closes regularly and interrupts; If be low level, then to open regularly and interrupt, output modulation signal in modulation back amplifies the rear drive infrared transmitting tube through triode and launches described infrared remote-controlled signal to the infrared emission circuit, and forwarding module is promptly finished the forwarding to described infrared remote-controlled signal.

Study transponder of the present utility model, its study module do not take the interruption sum counter resource of single-chip microcomputer to the study of described infrared remote-controlled signal, and these resources can be used for realizing the function that other are possible, and therefore certain extendability is arranged.In addition, can be by dummy instruction correction pulsewidth counter, the reduction cycle of the sampling period when making study when transmitting is identical, the consistance of assurance recovering signal and institute's learning signal.The study transponder of the utility model embodiment, by the pulse width measure unit level width is measured storage, owing to only need the high-low level width of measuring-signal, and do not consider its coding rule, so can measure study to the infrared remote-controlled signal of any electrical equipment, realize real " omnipotent ", compatible strong; The square-wave pulse of the carrier wave generation unit of forwarding module is interrupted producing by the timer of single-chip microcomputer internal processes control single chip computer, reliability height not only, and compare with extending out square-wave generator, cost is lower.

Below specifically introduce control module, the study module of study transponder of the present utility model, the concrete workflow of forwarding module.

As shown in Figure 4, after system powered on, at first count initialized device T0, T1, LED light and serial ports were monitored serial ports then.When in the serial ports data being arranged (control command that the host computer of integrated control system sends), read serial data, and postback checking data (for preventing wrong identification) to control command, the data that the monitoring module parses serial ports of main control chip transmits, if not control command, then abandon these data, the initialization serial ports returns the monitoring com-state; If control command, then further resolving these data is study order or firing order, if the study of described infrared remote-controlled signal is then carried out in the study order by study module, the initialization serial ports returns the monitoring com-state; If forward command then carries out the forwarding of described infrared remote-controlled signal by forwarding module, after forwarding finished, the initialization serial ports returned the monitoring com-state.

As shown in Figure 5, carry out described infrared remote-controlled signal when learning by study module, at first Guan always interrupts, open the study pilot lamp, whether have infrared remote-controlled signal input, if there is not the infrared remote-controlled signal input in 1 second, then open total interruption if detecting then, close the study pilot lamp, return then; If receive infrared remote-controlled signal, carry out pulsewidth degree counting when then gathering high-low level, adopting single step to increase progressively the while circulation counts, when treating level saltus step (by high step-down, or uprise by low), recording gauge numerical value, the zero clearing counting variable, again count, so circulate, just write down the pulse-width data of the high-low level of described infrared remote-controlled signal.When high level lasting time during greater than 49ms, think that promptly learning process finishes, open total interruption, close the study pilot lamp, pulse-width data is write E ²Prom memory, the study that study module carries out described infrared remote-controlled signal promptly comes to an end.

As shown in Figure 6, when carrying out the emission subroutine, at first from E ²Take out corresponding pulse-width data in the prom memory, start regularly the carrier signal that T0 produces 38kHz then, get first pulse-width data and assignment to the single step for loop variable i that successively decreases, when i is decremented to 0, timeing closing device T0, get next pulse-width data and assignment to the single step for loop variable i that successively decreases, when i is decremented to 0, start timer T0, get next pulse-width data and assignment to the single step for loop variable i that successively decreases, when i is decremented to 0, timeing closing device T0, and check whether next pulse-width data value is 0, be 0 and think that described infrared remote-controlled signal forwarding finishes, and returns, otherwise, continue to get next pulse-width data, so circulation realizes the emission of 38kHz Pulse Width Carrier Modulation.

Introduce the telepilot of the utility model embodiment below again.

The telepilot of the utility model embodiment, has a shell, has button on the described shell, be provided with the study transponder of the utility model embodiment in the described shell, in the described button, have a button at least, be used to control the study of described study transponder, and described telepilot is by different buttons, at least two external units of remote control.

Described button can have a plurality of, and control study transponder is to the study and the forwarding of the infrared remote-controlled signal of different external units respectively.Described button its essence is the action by button, to the connection and the shutoff of the control circuit of study module and forwarding module, for example presses the study button, and control circuit is connected, and can make study module begin described infrared remote-controlled signal is learnt.

Introduce the expanded function of the integrated control system of the utility model embodiment below again.

When described host computer was mobile phone, by the mobile access of mobile phone, the user can realize the control of host computer to the study transponder by sending way of short messages, and then realizes the remote control to external unit.For example when the user is about to get home,, can open the equipment such as air-conditioning in the family in advance, bring convenience to life staying idle at home by sending note.With respect to install the mixed-media network modules mixed-media realization additional on single remote the mode of the Long-distance Control of household electrical appliances is compared, integrated control system of the present utility model has been saved cost, has improved reliability.

When described host computer was PC, by the internet access of computer, the user can realize the control of host computer to the study transponder in long-range mode by webpage control, and then realizes the remote control to external unit.For example the user when going out, by landing network, can carry out remote control, for example to the open and close of monitoring camera to corresponding external unit.

Those skilled in the art should recognize change and the retouching of being done under the situation that does not break away from the appended scope and spirit of the present utility model that claim disclosed of the utility model, all belong within the protection domain of claim of the present utility model.

Claims

1. a study transponder is used for the reception study and the reduction forwarding of infrared remote-controlled signal, it is characterized in that this study transponder comprises:

One main control chip;

One signal receiving circuit is connected in described main control chip, is used to receive described infrared remote-controlled signal;

One signal transmission circuit is connected in described main control chip, is used to launch described infrared remote-controlled signal;

One storer is built in or is external in described main control chip, is used to store the high-low level width data of many group infrared remote-controlled signals;

Described main control chip comprises:

One control module is used to control the study and the forwarding of described study transponder;

One study module when receiving the learn command that described control module transmits, detects the described infrared remote-controlled signal of the external unit that described signal receiving circuit receives, and measures the high-low level width data of described infrared remote-controlled signal and is stored in described storer;

One forwarding module, when receiving the forwarding instruction that described control module transmits, read and generate the infrared emission signal, launch described infrared remote-controlled signal to control described external unit by described signal transmission circuit according to the described high-low level width data that described storer is stored.

2. study transponder as claimed in claim 1, it is characterized in that, described study transponder also comprises a condition indication circuit, is connected in described main control chip, and this indicating circuit comprises that at least one is in order to indicate the LED light of described study repeater operation state.

3. study transponder as claimed in claim 1 is characterized in that, described study module comprises:

Initial recognition unit is in order to the initial low level of the identification described infrared remote-controlled signal of expression;

The pulse width measure unit, detect after the described low level finish to described infrared remote-controlled signal before, measure the high-low level width data of described infrared remote-controlled signal, and be temporary among the RAM;

Finish identifying unit, current high level width data and the setting threshold of storing among the described RAM compared, when described width data is judged described infrared remote-controlled signal end during greater than described setting threshold;

Storage unit after described end identifying unit judges that described infrared remote-controlled signal finishes, is stored in described storer with the described high-low level width data of storing among the described RAM.

4. study transponder as claimed in claim 1 is characterized in that,

Described forwarding module, comprise reading unit, modulating unit, carrier wave generation unit and output unit, described reading unit reads the high-low level pulse-width data of described memory stores, generate square wave by described carrier wave generation unit, be modulated to the high-low level pulse signal by modulating unit, export to described signal transmission circuit by output unit;

Described signal transmission circuit comprises first current-limiting resistance, second current-limiting resistance, triode and infraluminescence diode, the high-low level pulse signal that described forwarding module is transmitted, through the described first current-limiting resistance current limliting, amplify through described triode, the described high-low level pulse signal after the amplification is launched through the described infrared transmitting tube of the described second current-limiting resistance current limliting rear drive again.

5. study transponder as claimed in claim 1 is characterized in that, described main control chip is a STC Series chip, an ARM chip or a fpga chip.

6. study transponder as claimed in claim 5, it is characterized in that, described main control chip is the STC89C58RD+ single-chip microcomputer, and described signal receiving circuit and signal transmission circuit are connected to the pin of described STC89C58RD+ single-chip microcomputer, and described storer is the built-in E of described single-chip microcomputer ²Prom memory, described setting threshold are and the corresponding high level width data of duration 49ms.

7. study transponder as claimed in claim 6, it is characterized in that, described main control chip also comprises serial ports monitoring module, described study transponder also comprises a serial communication circuit, described serial communication circuit is connected in described serial ports and monitors module, and described serial ports is monitored module and monitored the control command that transmits by described serial communication circuit.

8. telepilot, has a shell, has button on the described shell, it is characterized in that, be provided with the arbitrary described study transponder of claim 1-7 in the described shell, in the described button, at least has a button, be used to control the study of described study transponder, and described telepilot is by different buttons, at least two external units of remote control.

9. an integrated control system is characterized in that, described integrated control system comprises:

One study transponder, it is the arbitrary described study transponder of claim 1-6;

One host computer is connected in described study transponder, controls the study and the forwarding of described study transponder.

10. integrated control system as claimed in claim 9, it is characterized in that, described study transponder has a serial communication circuit, described serial communication link tester crosses Serial Port Line or wireless serial equipment is connected with described host computer, described host computer is PC, hand held controller, palm PC or mobile phone, and described host computer has by wireless access way or has line access mode to insert the access device of internet.