CN204721653U - For the wireless transmission anti-jamming circuit of intelligent building lamp-controlling circuit - Google Patents

Abstract

The utility model relates to a kind of wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit, comprise power module, zigbee processor module, radio-frequency module and wifi module, described zigbee processor module is connected by UART with wifi module, described zigbee processor module input is connected with radio-frequency module output, described zigbee processor module connects the equipment utilizing zigbee network to receive control command, described processor module, wifi module and radio-frequency module are all connected on power module, single-chip microcomputer is provided with in described zigbee processor module, this circuit is by the collaborative work of circuit module, wifi module, the set of zigbee processor module and radio-frequency module and the layout of circuit, effectively reduce the mutual interference problem of wireless signal.

Description

For the wireless transmission anti-jamming circuit of intelligent building lamp-controlling circuit

Technical field

The utility model relates to a kind of lamp-controlling circuit field, is specifically related to a kind of wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit.

Background technology

At present, the room lighting network system great majority as big-and-middle-sized office buildings, wired home are the cable networks adopting comprehensive wiring technology, rely on carry out the switch of supply line the control of all kinds of light of indoor.To the control and management concentrated light network, the material cost then brought by connecting up and time overhead will increase greatly, not only construct complexity, flexibility is inadequate, but also there is wiring confusion, aging circuit, maintenance difficulties is large, affects the application of intelligent lighting, again due to intelligent lighting aspect, the industry standard that all neither one is unified always, therefore also further increases the difficulty of later maintenance.

In recent years, modern short-distance wireless communication technology, computer technology obtain high speed development, and automatic control technology, sensing technology are widely used gradually on building automatic and wired home.Therefore, adopt wireless mode to build a kind of high-environmental, flexible new indoor lighting control networks easily, there is wide market prospects and application potential.But to there is antijamming capability in wireless-transmission network low in specific works, easy lost data packets, the dissatisfactory problem of safety and stability.

Utility model content

In order to overcome the defect existed in above-mentioned prior art, it is high that the purpose of this utility model is to provide a kind of antijamming capability, the wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit of steady signal transmission.

To achieve these goals, the utility model provides a kind of wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit, comprise power module, zigbee processor module, radio-frequency module and wifi module, described zigbee processor module is connected by a UART chip with wifi module, described zigbee processor module input is connected with radio-frequency module output, described zigbee processor module connects the equipment utilizing zigbee network to receive control command, described processor module, wifi module and radio-frequency module are all connected on power module, single-chip microcomputer is provided with in described zigbee processor module,

Described wifi module and radio-frequency module receive control command and pass to zigbee processor module, and the single-chip microcomputer in zigbee processor module controls other according to received control command by zigbee network and utilizes zigbee network to receive the equipment of control command.

The control of single-chip microcomputer to the operating state of load adopts technical controlling known in the field, by the set to wifi module, zigbee processor module and radio-frequency module, the collaborative work of circuit module, solve the mutual interference problem of wireless signal, achieve wifi module, zigbee processor module stable transfer signal separately, do not interfere with each other.

Further, described zigbee processor module also comprises zigbee chip module and an encoder, connects described encoder between described zigbee chip module and radio-frequency module.Zigbee chip module adopts existing chip, realizes transfer of data.

Encoder accepts also judges the control command that radio-frequency module transmits, and then performs this control command.

Further, described encoder comprises the 33 resistance, 34 resistance, 35 resistance, 36 resistance, 37 resistance, 38 resistance, 39 resistance, 40 resistance, 41 resistance, 42 resistance, 43 resistance, 44 resistance, 45 resistance, 46 resistance, 47 resistance, 48 resistance, 49 resistance, 50 resistance, 51 resistance, 52 resistance, 53 resistance, 54 resistance, 55 resistance, 56 resistance, 72 resistance, 6th electric capacity, 9th triode, tenth triode, 11 triode, 12 triode, first NOR gate, second NOR gate, 3rd NOR gate, four nor gate, first operational amplifier, second operational amplifier,

Described radio-frequency module comprises decoder module, 3 pin of described decoder module, 4 pin, 5 pin, 6 pin are connected with the base stage of described 12 triode, the 11 triode, the tenth triode, the 9th triode respectively respectively by described 51 resistance, the 47 resistance, the 44 resistance, the 40 resistance, the collector electrode of described 12 triode, the 11 triode, the tenth triode, the 9th triode all connects power supply

The emitter of described 12 triode is connected with the inverting input of the first operational amplifier by least one resistance, the emitter of described 11 triode is connected with the inverting input of the first operational amplifier by least one resistance, the emitter of described tenth triode is connected with the inverting input of the first operational amplifier by the 45 resistance, and the emitter of described 9th triode is connected with the inverting input of the first operational amplifier by the 41 resistance;

The emitter of described 12 triode is by the 54 grounding through resistance, the emitter of described 11 triode is by the 50 grounding through resistance, the emitter of described tenth triode is by the 46 grounding through resistance, and the emitter of described 9th triode is by the 42 grounding through resistance;

The emitter of described 12 triode connects the input of described 3rd NOR gate, the emitter of described 12 triode is connected to the P06 pin of described zigbee chip module by the 36 resistance, the emitter of described 11 triode connects the input of four nor gate, the emitter of described 11 triode is connected to the P05 pin of described zigbee chip module by the 35 resistance, the emitter of described tenth triode connects the input of the second NOR gate, the emitter of described tenth triode is connected to the P04 pin of described zigbee chip module by the 34 resistance, the emitter of described 9th triode connects the input of the second NOR gate, the emitter of described 9th triode is connected to the P20 pin of described zigbee chip module by the 33 resistance,

The output of described second NOR gate connects the input of four nor gate, the output of described four nor gate connects the input of the 3rd NOR gate, the output of described 3rd NOR gate connects the input of described first NOR gate, another input of described first NOR gate is by described 39 grounding through resistance, the output of described first NOR gate connects the P20 pin of described zigbee chip module by described 37 resistance

The normal phase input end of described first operational amplifier connects two branch roads, article one, by described 55 grounding through resistance, another article connects power supply by the 56 resistance, the described output of the first operational amplifier is connected by the 6th electric capacity and the 43 resistance with the inverting input of this operational amplifier, described 6th electric capacity and the 43 resistance parallel with one another, the output of described first operational amplifier also connects the normal phase input end of described second operational amplifier, the inverting input of described second operational amplifier is by described 72 grounding through resistance, the output of described second operational amplifier is connected with the inverting input of the second operational amplifier by described 38 resistance, the output of described second operational amplifier is also connected on the P06 pin of described zigbee chip module.

This circuit structure is simple, and with low cost, signal transmission effect is good, and decoder module adopts existing decoding chip.

Further, described wifi module comprises wifi chip, the 16 electric capacity, the 17 electric capacity, the 22 electric capacity, the 23 electric capacity, the 57 resistance, the 60 resistance, the 63 resistance, the 67 resistance, the 69 resistance, the 70 resistance, the 71 resistance, the tenth diode, the 11 diode, the first light-emitting diode, the 3rd light-emitting diode, reset button and factory reset parameter button

1 pin ground connection of described wifi chip, 2 pin connect power supply, described 16 electric capacity, 17 Capacitance parallel connection be connected to and power supply between, 3 pin of described wifi chip connect two branch roads, article one, be connected to power supply by described 67 resistance, article one, by described reset button, tenth diode and the 22 capacity earth, described reset button, tenth diode and the 22 electric capacity interrelated, the plus earth of described tenth diode, 4 pin of described wifi chip connect three branch roads, Article 1, be connected to zigbee processor module by described 70 resistance, one end of described 69 resistance is connected with the tie point place of zigbee processor module at the 70 resistance, this resistance other end connects power supply, Article 2 connects power supply by the 71 resistance, Article 3 is by factory reset parameter button, 11 diode and the 23 capacity earth, described factory reset parameter button, 11 diode and the 23 electric capacity parallel with one another, the plus earth of described 11 diode, 7 pin of described wifi chip connect power supply by described 63 resistance, 9 pin of described wifi chip are connected to power supply by described 57 resistance and the first light-emitting diode, described 57 resistance and the series connection of the first light-emitting diode, the positive pole of described first light-emitting diode connects and is connected with power supply, 10 pin of described wifi chip are connected to power supply by described 60 resistance and the 3rd light-emitting diode, described 60 resistance and the series connection of the 3rd light-emitting diode, the positive pole of described 3rd light-emitting diode connects and is connected with power supply.

This circuit structure is simple, and with low cost, signal transmission effect is good, and wifi chip adopts existing chip.

Preferably, described radio-frequency module adopts 315MHz wireless communication module, and described wifi module and zigbee processor module all adopt 2.4GHz wireless signal.

The invention has the beneficial effects as follows: the layout of wifi module, zigbee processor module and radio-frequency module set and circuit, effectively reduces the mutual interference problem of wireless signal; Wifi module, zigbee processor module are 2.4GHz wireless signal, reduce mutual air interference; By the collaborative work of circuit module, realize wifi module, zigbee processor module stable transfer signal separately, do not interfere with each other.

Additional aspect of the present utility model and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by practice of the present utility model.

Accompanying drawing explanation

Above-mentioned and/or additional aspect of the present utility model and advantage will become obvious and easy understand from accompanying drawing below combining to the description of embodiment, wherein:

Fig. 1 is theory diagram of the present utility model;

Fig. 2 is zigbee chip module interface diagram;

Fig. 3 is encoder circuit figure;

Fig. 4 is the interface diagram of decoder module;

Fig. 5 is the interface diagram of wifi chip.

Embodiment

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Being exemplary below by the embodiment be described with reference to the drawings, only for explaining the utility model, and can not being interpreted as restriction of the present utility model.

In description of the present utility model, unless otherwise prescribed and limit, it should be noted that, term " installation ", " being connected ", " connection " should be interpreted broadly, such as, can be mechanical connection or electrical connection, also can be the connection of two element internals, can be directly be connected, also indirectly can be connected by intermediary, for the ordinary skill in the art, the concrete meaning of above-mentioned term can be understood as the case may be.

The utility model provides a kind of wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit, as shown in Figure 1, comprise power module, zigbee processor module, radio-frequency module and wifi module, described zigbee processor module is connected by UART with wifi module, described zigbee processor module input is connected with radio-frequency module output, described zigbee processor module connects the equipment utilizing zigbee network to receive control command, described processor module, wifi module and radio-frequency module are all connected on power module, single-chip microcomputer is provided with in described zigbee processor module,

Described wifi module and radio-frequency module receive control command and pass to zigbee processor module, and the single-chip microcomputer in zigbee processor module controls other according to received control command by zigbee network and utilizes zigbee network to receive the equipment of control command.

The control of single-chip microcomputer to the operating state of load adopts technical controlling known in the field, and radio-frequency module adopts 315MHz wireless communication module, and wifi module and zigbee processor module all adopt 2.4GHz wireless signal.

Wifi module is connected by serial communication with zigbee processor module, wifi module, zigbee processor module and radio-frequency module set, solves the mutual interference problem of wireless signal; Wifi module, zigbee processor module are 2.4GHz wireless signal, reduce mutual air interference;

Wherein, zigbee processor module also comprises zigbee chip module U4 and an encoder, connects described encoder between described zigbee chip module U4 and radio-frequency module.

Zigbee processor module also comprises the first electric capacity C1 and the second electric capacity C2.

As shown in Figure 2, the earth terminal ground connection of zigbee chip module U4, power end connects 3.3V power supply, the first electric capacity C1, the second electric capacity C2 be connected in parallel in and 3.3V power supply between, connect encoder between zigbee chip module U4 and radio-frequency module.

Encoder accepts also judges the control command that radio-frequency module transmits, and then performs this control command.

As shown in Figure 3, encoder comprises the 33 resistance R33, 34 resistance R34, 35 resistance R35, 36 resistance R36, 37 resistance R37, 38 resistance R38, 39 resistance R39, 40 resistance R40, 41 resistance R41, 42 resistance R42, 43 resistance R43, 44 resistance R44, 45 resistance R45, 46 resistance R46, 47 resistance R47, 48 resistance R48, 49 resistance R49, 50 resistance R50, 51 resistance R51, 52 resistance R52, 53 resistance R53, 54 resistance R54, 55 resistance R55, 56 resistance R56, 72 resistance R72, 6th electric capacity C6, 9th triode Q9, tenth triode Q10, 11 triode Q11, 12 triode Q12, first NOR gate U1A, second NOR gate U1B, 3rd NOR gate U1C, four nor gate U1D, first operational amplifier U2A, second operational amplifier U2B,

Radio-frequency module comprises decoder module U8, as shown in Figure 4, decoder module U8 selects chip SC2272,3 pin of decoder module U8,4 pin, 5 pin, 6 pin are connected with the base stage of the 12 triode Q12, the 11 triode Q11, the tenth triode Q10, the 9th triode Q9 respectively respectively by the 51 resistance R51, the 47 resistance R47, the 44 resistance R44, the 40 resistance R40, the collector electrode of the 12 triode Q12, the 11 triode Q11, the tenth triode Q10, the 9th triode Q9 all connects power supply

The emitter of the 12 triode Q12 is connected with the inverting input of the first operational amplifier U2A with the 53 resistance R53 by the 52 resistance R52 of series connection, the emitter of the 11 triode Q11 is connected with the inverting input of the first operational amplifier U2A with the 49 resistance R49 by the 48 resistance R48 of series connection, the emitter of the tenth triode Q10 is connected with the inverting input of the first operational amplifier U2A by the 45 resistance R45, the emitter of the 9th triode Q9 is connected with the inverting input of the first operational amplifier U2A by the 41 resistance R41,

The emitter of the 12 triode Q12 is by the 54 resistance R54 ground connection, the emitter of the 11 triode Q11 is by the 50 resistance R50 ground connection, the emitter of the tenth triode Q10 is by the 46 resistance R46 ground connection, and the emitter of the 9th triode Q9 is by the 42 resistance R42 ground connection;

The emitter of the 12 triode Q12 connects the input of the 3rd NOR gate U1C, the emitter of the 12 triode Q12 is connected to the P06 pin of zigbee chip module U4 by the 36 resistance R36, the emitter of the 11 triode Q11 connects the input of four nor gate U1D, the emitter of the 11 triode Q11 is connected to the P05 pin of zigbee chip module U4 by the 35 resistance R35, the emitter of the tenth triode Q10 connects the input of the second NOR gate U1B, the emitter of the tenth triode Q10 is connected to the P04 pin of zigbee chip module U4 by the 34 resistance R34, the emitter of the 9th triode Q9 connects the input of the second NOR gate U1B, the emitter of the 9th triode Q9 is connected to the P20 pin of zigbee chip module U4 by the 33 resistance R33,

The output of the second NOR gate U1B connects the input of four nor gate U1D, the output of four nor gate U1D connects the input of the 3rd NOR gate U1C, the output of the 3rd NOR gate U1C connects the input of the first NOR gate U1A, another input of first NOR gate U1A is by the 39 resistance R39 ground connection, the output of the first NOR gate U1A connects the P20 pin of zigbee chip module U4 by the 37 resistance R37

The normal phase input end of the first operational amplifier U2A connects two branch roads, article one, by the 55 resistance R55 ground connection, another article connects power supply by the 56 resistance R56, the output of the first operational amplifier U2A is connected by the 6th electric capacity C6 and the 43 resistance R43 with the inverting input of this operational amplifier, 6th electric capacity C6 and the 43 resistance R43 is parallel with one another, the output of the first operational amplifier U2A also connects the normal phase input end of the second operational amplifier U2B, the inverting input of the second operational amplifier U2B is by the 72 resistance R72 ground connection, the output of the second operational amplifier U2B is connected with the inverting input of the second operational amplifier U2B by the 38 resistance R38, the output of the second operational amplifier U2B is also connected on the P06 pin of zigbee chip module U4.

Wifi module comprises wifi chip U6, 16 electric capacity C16, 17 electric capacity C17, 22 electric capacity C22, 23 electric capacity C23, 57 resistance R57, 60 resistance R60, 63 resistance R63, 67 resistance R67, 69 resistance R69, 70 resistance R70, 71 resistance R71, tenth diode D10, 11 diode D11, first light-emitting diode LD1, 3rd light-emitting diode LD3, reset button K5 and factory reset parameter button K8.Here wifi chip U6 selects chips W IFI232-T.

As shown in Figure 5, the 1 pin ground connection of wifi chip U6, 2 pin connect power supply, 16 electric capacity C16, 17 electric capacity C17 be connected in parallel in and power supply between, 3 pin of wifi chip U6 connect two branch roads, article one, be connected to power supply by the 67 resistance R67, article one, by reset button K5, tenth diode D10 and the 22 electric capacity C22 ground connection, reset button K5, tenth diode D10 and the 22 electric capacity C22 is interrelated, the plus earth of the tenth diode D10, 4 pin of wifi chip U6 connect three branch roads, Article 1, be connected to zigbee module by the 70 resistance R70, one end of the 69 resistance R69 is connected with the tie point place of zigbee module at the 70 resistance R70, this resistance other end connects power supply, Article 2 connects power supply by the 71 resistance R71, Article 3 is by factory reset parameter button K8, 11 diode D11 and the 23 electric capacity C23 ground connection, factory reset parameter button K8, 11 diode D11 and the 23 electric capacity C23 is parallel with one another, the plus earth of the 11 diode D11, 7 pin of wifi chip U6 connect power supply by the 63 resistance R63, 9 pin of wifi chip U6 are connected to power supply by the 57 resistance R57 and the first light-emitting diode LD1, 57 resistance R57 and the first light-emitting diode LD1 connects, the positive pole of the first light-emitting diode LD1 connects and is connected with power supply, 10 pin of wifi chip U6 are connected to power supply by the 60 resistance R60 and the 3rd light-emitting diode LD3, 60 resistance R60 and the 3rd light-emitting diode LD3 connects, the positive pole of the 3rd light-emitting diode LD3 connects and is connected with power supply.

By the collaborative work of circuit module, realize wifi module, zigbee processor module stable transfer signal separately, do not interfere with each other.

In the description of this specification, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, identical embodiment or example are not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.

Although illustrate and described embodiment of the present utility model, those having ordinary skill in the art will appreciate that: can carry out multiple change, amendment, replacement and modification to these embodiments when not departing from principle of the present utility model and aim, scope of the present utility model is by claim and equivalents thereof.

Claims (6)

1. for the wireless transmission anti-jamming circuit of intelligent building lamp-controlling circuit, it is characterized in that, comprise power module, zigbee processor module, radio-frequency module and wifi module, described zigbee processor module is connected by UART with wifi module, described zigbee processor module input is connected with radio-frequency module output, described zigbee processor module connects the equipment utilizing zigbee network to receive control command, described processor module, wifi module and radio-frequency module are all connected on power module, single-chip microcomputer is provided with in described zigbee processor module,

Described wifi module and radio-frequency module receive control command and pass to zigbee processor module, and the single-chip microcomputer in zigbee processor module controls other according to received control command by zigbee network and utilizes zigbee network to receive the equipment of control command.

2. the wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit according to claim 1, it is characterized in that, described zigbee processor module also comprises zigbee chip module and an encoder, connects described encoder between described zigbee chip module and radio-frequency module.

3. the wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit according to claim 2, it is characterized in that, described encoder comprises the 33 resistance, 34 resistance, 35 resistance, 36 resistance, 37 resistance, 38 resistance, 39 resistance, 40 resistance, 41 resistance, 42 resistance, 43 resistance, 44 resistance, 45 resistance, 46 resistance, 47 resistance, 48 resistance, 49 resistance, 50 resistance, 51 resistance, 52 resistance, 53 resistance, 54 resistance, 55 resistance, 56 resistance, 72 resistance, 6th electric capacity, 9th triode, tenth triode, 11 triode, 12 triode, first NOR gate, second NOR gate, 3rd NOR gate, four nor gate, first operational amplifier, second operational amplifier,

Described radio-frequency module comprises decoder module, 3 pin of described decoder module, 4 pin, 5 pin, 6 pin are connected with the base stage of described 12 triode, the 11 triode, the tenth triode, the 9th triode respectively respectively by described 51 resistance, the 47 resistance, the 44 resistance, the 40 resistance, the collector electrode of described 12 triode, the 11 triode, the tenth triode, the 9th triode all connects power supply

The emitter of described 12 triode is connected with the inverting input of the first operational amplifier by least one resistance, the emitter of described 11 triode is connected with the inverting input of the first operational amplifier by least one resistance, the emitter of described tenth triode is connected with the inverting input of the first operational amplifier by the 45 resistance, and the emitter of described 9th triode is connected with the inverting input of the first operational amplifier by the 41 resistance;

The emitter of described 12 triode is by the 54 grounding through resistance, the emitter of described 11 triode is by the 50 grounding through resistance, the emitter of described tenth triode is by the 46 grounding through resistance, and the emitter of described 9th triode is by the 42 grounding through resistance;

The emitter of described 12 triode connects the input of described 3rd NOR gate, the emitter of described 12 triode is connected to the P06 pin of described zigbee chip module by the 36 resistance, the emitter of described 11 triode connects the input of four nor gate, the emitter of described 11 triode is connected to the P05 pin of described zigbee chip module by the 35 resistance, the emitter of described tenth triode connects the input of the second NOR gate, the emitter of described tenth triode is connected to the P04 pin of described zigbee chip module by the 34 resistance, the emitter of described 9th triode connects the input of the second NOR gate, the emitter of described 9th triode is connected to the P20 pin of described zigbee chip module by the 33 resistance,

The output of described second NOR gate connects the input of four nor gate, the output of described four nor gate connects the input of the 3rd NOR gate, the output of described 3rd NOR gate connects the input of described first NOR gate, another input of described first NOR gate is by described 39 grounding through resistance, the output of described first NOR gate connects the P20 pin of described zigbee chip module by described 37 resistance

The normal phase input end of described first operational amplifier connects two branch roads, article one, by described 55 grounding through resistance, another article connects power supply by the 56 resistance, the described output of the first operational amplifier is connected by the 6th electric capacity and the 43 resistance with the inverting input of this operational amplifier, described 6th electric capacity and the 43 resistance parallel with one another, the output of described first operational amplifier also connects the normal phase input end of described second operational amplifier, the inverting input of described second operational amplifier is by described 72 grounding through resistance, the output of described second operational amplifier is connected with the inverting input of the second operational amplifier by described 38 resistance, the output of described second operational amplifier is also connected on the P06 pin of described zigbee chip module.

4. the wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit according to claim 1, it is characterized in that, described wifi module comprises wifi chip, the 16 electric capacity, the 17 electric capacity, the 22 electric capacity, the 23 electric capacity, the 57 resistance, the 60 resistance, the 63 resistance, the 67 resistance, the 69 resistance, the 70 resistance, the 71 resistance, the tenth diode, the 11 diode, the first light-emitting diode, the 3rd light-emitting diode, reset button and factory reset parameter button

1 pin ground connection of described wifi chip, 2 pin connect power supply, described 16 electric capacity, 17 Capacitance parallel connection be connected to and power supply between, 3 pin of described wifi chip connect two branch roads, article one, be connected to power supply by described 67 resistance, article one, by described reset button, tenth diode and the 22 capacity earth, described reset button, tenth diode and the 22 electric capacity interrelated, the plus earth of described tenth diode, 4 pin of described wifi chip connect three branch roads, Article 1, be connected to zigbee processor module by described 70 resistance, one end of described 69 resistance is connected with the tie point place of zigbee processor module at the 70 resistance, this resistance other end connects power supply, Article 2 connects power supply by the 71 resistance, Article 3 is by factory reset parameter button, 11 diode and the 23 capacity earth, described factory reset parameter button, 11 diode and the 23 electric capacity parallel with one another, the plus earth of described 11 diode, 7 pin of described wif i chip connect power supply by described 63 resistance, 9 pin of described wif i chip are connected to power supply by described 57 resistance and the first light-emitting diode, described 57 resistance and the series connection of the first light-emitting diode, the positive pole of described first light-emitting diode connects and is connected with power supply, 10 pin of described wifi chip are connected to power supply by described 60 resistance and the 3rd light-emitting diode, described 60 resistance and the series connection of the 3rd light-emitting diode, the positive pole of described 3rd light-emitting diode connects and is connected with power supply.

5. the wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit according to claim 1, is characterized in that, described radio-frequency module adopts 315MHz wireless communication module.

6. the wireless transmission anti-jamming circuit for intelligent building lamp-controlling circuit according to claim 1, is characterized in that, described wifi module and zigbee processor module all adopt 2.4GHz wireless signal.