CN201188670Y - Network intelligent wireless control system - Google Patents

Abstract

The utility model discloses an active homing network intelligent wireless control system based on a ZigBee network control technology, which can realize automatic remote control in the fields of family numeralization, industries, intelligent traffic and the like. The active homing network intelligent wireless control system comprises a collector installed in a user unit, a wireless signal transmission unit connected to a collector power switch control relay, and a center base station which is arranged at a monitoring center and is connected with a warning unit and a user mobile phone signal through a mobile network for public,; the agreement between the wireless signal transmission unit and a center base station signal transceiver is a ZigBee wireless agreement. The utility model not only can intensively manage the monitoring information of the user unit, know about the conditions of the user unit in time, and perform process in the very first time, but also can initiatively search the collector, apparatuses and machine stations to realize fault monitor, and can remotely control various collectors and apparatuses; the utility model has low operation cost and, safe and reliable communication network, and warning by mistake, missort or interference can not happen.

Description

Network intelligent wireless control system

Technical field:

The utility model relates to a kind of network intelligent wireless control system, specifically be a kind of can active homing realization be the network intelligent wireless control system that alarm monitoring facility and each electric appliances are carried out remote automation control to all kinds of collectors.

Background technology:

At present, prior art radio alarming control system generally adopts the passive type receive mode of single base stations control, each base station is an isolated system, in other words, each subscriber unit is one and independently controls the base station, this is independently controlled the base station and is arranged in each subscriber unit, and it is to be connected or the wireless signal connection by wired RS485 of employings such as base station signal transceiver and all kinds of collectors such as smoke alarm, Fuel Gas Leak Alarm, door magnetic burglar alarms; Described base station signal transceiver is embedded with the GPRS module; GSM signal emission module separately is installed on the described all kinds of warning device, these GSM signaling modules can be initiatively to base station signal transceiver emission alarm signal when watch-dog is in alarm condition, and when warning device does not have alert, the signal level of signaling module is in nought state in the watch-dog, the base station signal transceiver of this moment can not receive alarm signal, in other words, the base station signal transceiver in the prior art radio alarming control system is passive reception alarm signal.Owing to send alarm signal to the base station signal transceiver when described GSM signal emission module all is in chance police state at equipment of itself, therefore, the base station signal transceiver that receives these alarm signals must be sat in the right seat by the signal that microcomputer is sent by all kinds of alarm monitoring equipment that inserted the processor chips in it when Installation and Debugging and be programmed, modulates and store, and described base station signal transceiver is by the GPRS module this warning message to be sent to user side (user mobile phone).There are following five weak points in actual applications in prior art radio alarming control system:

1, because the single base station in the prior art wireless alarm system only is arranged on the single watch-dog of each subscriber unit, so, though the user can in time understand the monitor message of family, but Property Management of residence or Surveillance center can't concentrate and unified management all users' monitor message, the situation in each user family can not be in time understood, thereby processing can not be in the very first time, reported to the police;

2, because prior art receives all kinds of collectors is that the base station signal transceiver of the alarm signal that sends of warning device must be sat in the right seat by the signal that microcomputer is sent by all kinds of alarm monitoring equipment that inserted the processor chips in it when Installation and Debugging and programmed, modulates and store every kind of alarm monitoring equipment and all need specific interface, so the prior art wireless alarm system exists operation cost height and the insecure defective of communication network.

3, because what the base station signal transceiver in the prior art radio alarming control system adopted is the mode of passive reception alarm signal, be that the base station signal transceiver itself does not have monitoring function, it could send to warning message user side and have only when alarm monitoring equipment sends alarm signal to the base station signal transceiver, so, when the alarm monitoring device fails in the prior art wireless alarm system such as alarm monitoring equipment lead or power line when being cut off, the base station signal transceiver will be in the blinding state, if alert takes place this moment, the base station signal transceiver will be known nothing, and user side also is difficult in time discover and carry out in-situ processing in real time by the base station signal transceiver; And the facility that it also can't insert the output of some no signals comprises household electrical appliance etc., can not implement Remotes operation to these facilities by user mobile phone.

Therefore 4, no matter the alarm monitoring equipment in the prior art radio alarming control system is by wired RS485 or wireless connections, all needs signal emission module, works as the alarm monitoring device fails that is connected or very easily causes false alarm when damaging.

5, because all kinds of warning devices in the prior art radio alarming control system are equipped with signal emission module, therefore when carrying out the every household installation in the sub-district, the signal of similar warning device emission will produce to be visited one house after another, disturbs.

The utility model content:

The technical problems to be solved in the utility model is, provide a kind of Property Management of residence or Surveillance center of not only can making to concentrate and unified management the monitor message of all resident families of sub-district, thereby in time understand the situation of each resident family and discover the warning system fault, and the processing of in the very first time, reporting to the police; And can the active searching alarm signal, and electric equipment is implemented Remote control, operation cost is low, communications network security, reliable, can not cause false alarm in the alarm monitoring device fails or when damaging, can not visit one house after another or the network intelligent wireless control system of interference phenomenon.

Technical solution of the present utility model is, a kind of network intelligent wireless control system with following structure is provided: it comprises all kinds of alarm monitoring equipment and the electric equipment that are installed in the subscriber unit, is arranged on the center base station of Property Management of residence center or Surveillance center and is arranged on to have in the subscriber unit and initiatively seek all kinds of alarm monitoring equipment and electric equipment, and can in time detect the operating state situation of all kinds of alarm monitoring equipment and electric equipment and in time detected data be sent to the wireless signal transmitter of center base station; Described center base station comprises center base station signal transceiver that is provided with the GPRS module and the central Computerized monitor system that is connected with the center base station signal transceiver; For the MANET signal is connected, and the agreement between them is the Zigbee wireless protocols between described wireless signal transmitter and the center base station signal transceiver; Described center base station signal transceiver is connected by mobile network for public and 110, warning unit and sub-district mobile phones on duty such as 119 or 120 or user mobile phone signal; Described wireless signal transmitter is connected on the power control relay of buzzer, alarm lamp and electric equipment of alarm monitoring equipment.

After adopting above structure, compared with prior art, the utlity model has following advantage:

1, because all kinds of alarm monitoring equipment in the utility model can be by being arranged on the center base station signal transceiver that wireless signal transmitter in the subscriber unit transfers to alarm signal on/off switching signal Property Management of residence center or Surveillance center when detecting alert, and the center base station signal transceiver not only can be by showing alert with literal and sound on the display of programming instruction in central Computerized monitor system of central Computerized monitor system, but also can alert be sent to mobile network for public by the GPRS module, by mobile network for public alert is distributed to corresponding warning unit and sub-district mobile phone on duty and user mobile phone again, thereby realized the concentrated and unified management of Property Management of residence or Surveillance center, in time understood the situation of each resident family and the processing of in the very first time, reporting to the police the monitor message of all resident families of sub-district.

2, unlike the prior art, the utility model only needs just alert to be sent to by mobile network for public on 110,119 or 120 warning units and sub-district mobile phone on duty and the resident family's mobile phone in GPRS module of installation on the center base station transceiver, and need not to be provided with in each subscriber unit a base station signal transceiver that is embedded with the GPRS module; In addition, what adopt between the utility model wireless signal transmitter and the center base station signal transceiver is the Zigbee wireless protocols, the Zigbee wireless protocols is a kind of communication protocol standard based on IEEE 802.15.4, its working frequency range comprises 2.4G, 868M/915M and 433MHz etc., its channel data transmission rate can reach 250Kbit/s, and support the starlike and multi-hop equity topologic network mode of single-hop, compare with other wireless communication protocols, the Zigbee wireless protocols has the support simple Devices, super low-power consumption, transfer of data is stable, the internet security advantages of higher; Also have, wireless signal transmitter is the buzzer that is connected alarm monitoring equipment in the utility model, on the power control relay of alarm lamp and electric equipment, be that all kinds of alarm monitoring equipment and electric equipment are all by on/off switching signal and wireless signal transmitter cooperating, it does not need specific interface to cooperate different alarm monitoring equipment and electric equipment, can arbitrarily be connected the arbitrary incoming end on the wireless signal transmitter, in sum, the utility model network intelligent wireless control system not only operation cost is low, and communication network is reliable.

3, because having, the wireless signal transmitter in the utility model initiatively seeks all kinds of alarm monitoring equipment and electric equipment, and can in time detect the operating state situation of all kinds of alarm monitoring equipment and electric equipment and in time detected data be sent to the function of center base station, so the utility model can the active searching alarm signal; And be connected for the MANET signal between wireless signal transmitter and the center base station signal transceiver in the utility model, and the agreement between them is the Zigbee wireless protocols, can realize remote double to Control on Communication, so the utility model can be implemented Remote control to electric equipment.

4, because wireless signal transmitter is the buzzer that is connected terminal alarm monitoring equipment (collector) described in the utility model, on the mains switch control relay or other Control Node of alarm lamp and electric equipment, in other words, all kinds of alarm monitoring equipment and electric equipment all are to adopt on/off switching signal and wireless signal transmitter to pass through wired connection mode cooperating, it does not need to use the used signal emission module of alarm monitoring equipment in the prior art wireless alarm system, so false alarm takes place when alarm monitoring device fails or damage the utility model;

5,, when therefore in the sub-district, carrying out every household and installing, can not produce between the signal of similar warning device emission and visit one house after another and interference phenomenon because the utility model does not need to use the GSM signal emission module to the collector of terminal.

As a kind of improvement of the present utility model, described wireless signal transmitter comprise have Flash flash memory and random access memory ram and simultaneously ground connection signal processing/Zigbee radio-frequency module I and the DC switch power module I that is connected with signal processing/Zigbee radio-frequency module I, be provided with universal asynchronous reception/dispensing device UART I, crystal oscillator I that is used for the data terminal equipment interface RS-232 that is connected with computer and the programmable I/O expansion module CPLD/FPGA that is provided with several I/O ports; Described signal processing/Zigbee radio-frequency module I also enlarges equipment PA I by the electronic system signal and connects with the antenna I that is used for being connected with center base station signal transceiver signal with low-noise wide-band amplifier LNA I; Described DC switch power module I is connected with programmable I/O expansion module CPLD/FPGA.Because wireless signal transmitter is provided with universal asynchronous reception/dispensing device UARTI, and UART I is provided with and is used for the data terminal equipment interface RS-232 that is connected with computer, so subscriber unit need not by the central Computerized monitor system in the center base station directly, and the unit Rigen at oneself is provided with wireless signal transmitter according to needs.

As another improvement of the present utility model, be connected with the relay base station signal amplifier that can play relaying, amplification, error correction and buffer memory effect between described wireless signal transmitter and the center base station signal transceiver to signal.The network that can't cover for center base station is that network channel is poor, a little less than the signal or the place of data congestion, the relay base station signal amplifier can carry out collection, processing, buffering and the relaying of signal and data, thereby guarantee the unimpeded and reliability of network, and as the buffering area of data, the relay base station signal amplifier can also reduce the packet loss of data.Therefore, after the utility model is provided with the relay base station signal amplifier, can further improve the reliability of the utility model communication network.

Description of drawings:

Fig. 1 is the basic structure framework schematic diagram of the utility model network intelligent wireless control system.

Fig. 2 is the circuit block diagram of wireless signal transmitter in the utility model network intelligent wireless control system.

Fig. 3 is used for the circuit catenation principle figure of the signal processing/Zigbee radio-frequency module I of wireless signal transmitter for the utility model;

Fig. 4 is used for the circuit catenation principle figure of the programmable I/O expansion module CPLD/FPGA of wireless signal transmitter for the utility model;

Fig. 5 is used for the circuit catenation principle figure of the DC switch power module I of wireless signal transmitter for the utility model;

Fig. 6 is the circuit block diagram of center base station signal transceiver in the utility model network intelligent wireless control system.

Fig. 7 is used for the circuit catenation principle figure of the signal processing/Zigbee radio-frequency module II of center base station signal transceiver for the utility model.

Fig. 8 is used for the circuit catenation principle figure of the microprocessor AXIS of center base station signal transceiver for the utility model.

Fig. 9 is used for the circuit catenation principle figure of the DC switch power module II of center base station signal transceiver for the utility model.

Figure 10 is used for the circuit catenation principle figure of the GPRS SMS module of center base station signal transceiver for the utility model.

Figure 11 is the circuit block diagram of relay base station signal amplifier in the utility model network intelligent wireless control system.

Figure 12 is for being used for the circuit catenation principle figure of the signal processing/Zigbee radio-frequency module III of relay base station signal amplifier in the utility model.

Figure 13 is for being used for the circuit catenation principle figure of the DC switch power module III of relay base station signal amplifier in the utility model.

Figure 14 is the workflow schematic diagram that is in wireless signal transmitter in from bottom to top the data transmission procedure at the utility model.

Figure 15 is the workflow schematic diagram that is in center base station in from bottom to top the data transmission procedure at the utility model.

Figure 16 is the workflow schematic diagram that is in center base station in the top-down data transmission procedure at the utility model.

Figure 17 is the workflow schematic diagram that is in wireless signal transmitter in the top-down data transmission procedure at the utility model.

Figure 18 is the workflow schematic diagram of relay base station in the utility model intelligent radio alarm monitoring system.

Specific embodiment:

The utility model is described in further detail below in conjunction with the drawings and specific embodiments:

As shown in Figure 1, the utility model network intelligent wireless control system comprises all kinds of alarm monitoring equipment and the electric equipment that are installed in the subscriber unit, is arranged on the center base station of Property Management of residence center or Surveillance center and is arranged on to have in the subscriber unit and initiatively seek all kinds of alarm monitoring equipment and electric equipment, and can in time detect the operating state situation of all kinds of alarm monitoring equipment and electric equipment and in time detected data be sent to the wireless signal transmitter of center base station; Described center base station comprises center base station signal transceiver that is provided with the GPRS module and the central Computerized monitor system that is connected with the center base station signal transceiver; For the MANET signal is connected, and the agreement between them is the Zigbee wireless protocols between described wireless signal transmitter and the center base station signal transceiver; Described center base station signal transceiver is connected by mobile network for public and 110, warning unit and sub-district mobile phones on duty such as 119 or 120 or user mobile phone signal; Described wireless signal transmitter is connected on the power control relay of buzzer, alarm lamp and electric equipment of alarm monitoring equipment.

In the utility model, as shown in Figure 2, wireless signal transmitter described in the utility model comprise have Flash flash memory and random access memory ram and simultaneously ground connection signal processing/Zigbee radio-frequency module I and the DC switch power module I that is connected with signal processing/Zigbee radio-frequency module I, be provided with universal asynchronous reception/dispensing device UART I, crystal oscillator I 1 that is used for the data terminal equipment interface RS-232 that is connected with computer and the programmable I/O expansion module CPLD/FPGA that is provided with several I/O ports; Described signal processing/Zigbee radio-frequency module I also enlarges equipment PA I by the electronic system signal and is connected with antenna I with low-noise wide-band amplifier LNA I, and described antenna I is used for center base station signal transceiver signal and connects; Described DC switch power module I is connected with programmable I/O expansion module CPLD/FPGA.

As Fig. 3 and shown in Figure 5, in this specific embodiment, described signal processing/Zigbee radio-frequency module I comprises chip I P1221, chip SMD, chip ADM3222 10 and chip ADM485 11; The P3.5 pin of described chip I P1221, P3.4 pin, RX0 pin and TX0 pin are connected with T2OUT pin, T2-IN pin, TIOUT pin and the T1-IN pin of chip ADM3222 10 respectively; The TMS pin of described chip I P1221, TCK pin, TDI pin and TDO pin are connected with 5 pin, 4 pin, 7 pin and 6 pin of chip SMD respectively; 2 pin of described chip SMD, 3 pin and 9 pin are ground connection after inductance L 1 simultaneously; All RF-GND pin ground connection of described chip I P1221; All the D-GND pin of described chip I P1221 and A-GND pin be ground connection after inductance L 1 simultaneously; The ANT-OUT pin of described chip I P1221 enlarges equipment PA I by the electronic system signal and is connected with antenna I with low-noise wide-band amplifier LNA I; Be connected with capacitor C 6 between the C1+ pin of described chip ADM3222 10 and the C1-pin; Be connected with capacitor C 7 between the C2+ pin of described chip ADM3222 10 and the C2-pin; The R1OUT pin of described chip ADM3222 10, R2OUT pin, R1-IN pin and R2-IN pin are connected with 2 pin, 8 pin, 3 pin and 7 pin of data terminal equipment interface RS-232 14 respectively; The EN pin of described chip ADM3222 10 and GND pin are respectively through inductance L 1 ground connection; The V+ pin of described chip ADM3222 10 is by capacitor C 8 and inductance L 1 ground connection; Its V-pin is by capacitor C 9 and inductance L 1 ground connection; Be connected with resistance R 9 and R8 between the D1 pin of described chip ADM485 11 and the DE pin; The GND pin of described chip ADM485 11 is through inductance L 1 ground connection; The B pin of described chip ADM485 11 is connected with 1 pin with 2 pin of RS485 interface 15 with resistance R 12 by resistance R 13 respectively with the A pin; 4 pin of described chip SMD are connected with the OUT pin of 1 pin with DC switch power module I chips LM2954; The VCC pin of described chip I P1221 is connected with the OUT pin of DC switch power module I chips LM2954; The VCC pin of described chip ADM3222 10 is connected with the OUT pin of DC switch power module I chips RT9179; The VCC pin of described chip ADM485 11 is connected with an end of inductance L 2 among the DC switch power module I; The DE pin of described chip ADM485 11 is connected with an end of inductance L 2 among the DC switch power module I through resistance R 8 with the RE pin simultaneously; The A pin of described chip ADM485 11 is connected with an end of inductance L 2 among the DC switch power module I with resistance R 10 through resistance R 12.

As shown in Figure 4 and Figure 5, in this specific embodiment, described programmable I/O expansion module CPLD/FPGA comprises chip 24LC02, chip LCMXO256/TQFP100, jtag interface, interface chip IO-1TO10, interface chip IO-11TO20, five chip block ULN2803C U1, U3, U5, U6, U7 and five chip block 8P4R-22K RP1, RP2, RP3, RP4, RP5; The A0 pin of described chip 24LC02, A1 pin, A2 pin, GDN pin and WP pin are through inductance L 1 ground connection; The SCL pin of described chip 24LC02 and SDA pin simultaneously with signal processing/also be connected with the PT3D pin with the PCLKT0-0/PT4A pin of chip LCMXO256/TQFP100 respectively when Zigbee radio-frequency module I is connected; 2 pin of described jtag interface, 3 pin, 6 pin and 8 pin are connected with TD0 pin, TD1 pin, TMS pin and the TCK pin of chip LCMXO256/TQFP100 respectively; 7 pin of described jtag interface are through inductance L 1 ground connection; The PL2B pin of described chip LCMXO256/TQFP100, the PL3B pin, the PL3D pin, the PL4B pin, the PL5B pin, the PL5D pin, the PL6B pin, the PL7B pin, the PL7D pin, the PL8B pin, the PB2B pin, the PB4B pin, the PB4D pin, the PR9A pin, the PR7B pin, the PR6B pin, the PR4A pin, the PR3C pin, PT5A pin and PT4D pin respectively with the I1 pin of chip ULN2803C U1, the I2 pin, the I3 pin, the I4 pin, the I5 pin, the I6 pin, the I7 pin, the I8 pin, the I1 pin of chip ULN2803C U3, the I2 pin, the I3 pin, the I4 pin, the I5 pin, the I6 pin, the I7 pin, the I8 pin, the I1 pin of chip ULN2803C U5, the I2 pin, I3 pin and I4 pin connect; The PL2A pin of described chip LCMXO256/TQFP100, the PL3A pin, the PL3C pin, the PL4A pin, the PL5A pin, the PL5C pin, the PL6A pin, the PL7A pin, the PL7C pin, the PL8A pin, the PB2A pin, the PB4A pin, the PB4C pin, the PR9B pin, the PR7C pin, the PR7A pin, the PR4B pin, the PR3D pin, PT5B pin and PT4E pin respectively with the O5 pin of chip ULN2803C U5, the O6 pin, the O7 pin, the O8 pin, the O1 pin of chip ULN2803C U6, the O2 pin, the O3 pin, the O4 pin, the O5 pin, the O6 pin, the O7 pin, the O8 pin, the O1 pin of chip ULN2803C U7, the O2 pin, the O3 pin, the O4 pin, the O5 pin, the O6 pin, the O7 pin, the O8 pin connects; The VCCIO3 foot meridian capacitor C3 of described chip LCMXO256/TQFP100 and inductance L 1 ground connection; All GNDIO1 pin, GND pin and the GNDIO0 pin of described chip LCMXO256/TQFP100 are through inductance L 1 ground connection; The O1 pin of described chip ULN2803CU1, O2 pin, O3 pin, O4 pin, O5 pin, O6 pin, O7 pin, O8 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin of 8 pin, 7 pin, 6 pin, 5 pin and the 8P4R-22K RP2 of 8P4R-22K RP1 respectively; The O1 pin of described chip ULN2803C U3, O2 pin, O3 pin, O4 pin, O5 pin, O6 pin, O7 pin, O8 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin of 8 pin, 7 pin, 6 pin, 5 pin and the 8P4R-22K RP4 of 8P4R-22K RP3 respectively; The O1 pin of described chip ULN2803C U5, O2 pin, O3 pin, O4 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin of 8P4R-22K RP5 respectively; 1 pin of described chip 8P4R-22KRP1,2 pin, 3 pin, 4 pin are connected with I5 pin, I6 pin, I7 pin, the I8 pin of chip ULN2803C U5 respectively; 1 pin of described chip 8P4R-22K RP2,2 pin, 3 pin, 4 pin are connected with I1 pin, I2 pin, I2 pin, the I4 pin of chip ULN2803C U6 respectively; The I5 pin of described chip ULN2803C U6, I6 pin, I7 pin, I8 pin respectively with 1 pin, 2 pin, 3 pin, 4 pin of chip 8P4R-22KRP3; 1 pin of described chip 8P4R-22K RP4,2 pin, 3 pin, 4 pin are connected with I1 pin, I2 pin, I2 pin, the I4 pin of chip ULN2803C U7 respectively; The I5 pin of described chip ULN2803C U7, I6 pin, I7 pin, I8 pin are connected with 1 pin, 2 pin, 3 pin, 4 pin of chip 8P4R-22K RP5 respectively; 1 pin of described interface chip IO-1TO10,2 pin, 3 pin, 4 pin, 5 pin, 7 pin, 8 pin, 9 pin, 10 pin, 11 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin, 8 pin of chip 8P4R-22K RP2,7 pin, 6 pin, 5 pin, 8 pin of chip 8P4R-22K RP3,7 pin of described chip 8P4R-22K RP1 respectively; 1 pin of described interface chip IO-1TO20,2 pin, 3 pin, 4 pin, 5 pin, 7 pin, 8 pin, 9 pin, 10 pin, 11 pin are connected with 6 pin, 5 pin, 8 pin of chip 8P4R-22K RP4,7 pin, 6 pin, 5 pin, 8 pin of chip 8P4R-22K RP5,7 pin, 6 pin, 5 pin of described chip 8P4R-22K RP3 respectively; 6 pin of described interface chip IO-1TO10 and 6 pin of interface chip IO-11TO20 are respectively through inductance L 1 ground connection; The GND pin of described five chip block ULN2803C U1, U3, U5, U6, U7 is respectively through inductance L 1 ground connection; 12 pin of the 12 pin interface chip IO-11TO20 of described interface chip IO-1TO10 are connected with the COM pin of chip ULN2803C U1, U3, U5 simultaneously; Be connected with resistance R 21 between the VCC pin of described chip LCMXO256/TQFP100 and the SLEEPN pin; The PB5C pin of described chip LCMXO256/TQFP100, PB5D pin, PR8A pin, PR5C pin, PR5B pin and PR5A pin are connected with P2.4 pin, RX0 pin, the TX0 pin of DE pin, DI pin, RO pin and the chip I P1221 of chip AMDADM485 11 respectively; The SCL pin of the P3.1 pin of described chip I P1221, P3.2 pin chip 24LC02 is connected with the SDA pin; The PR3B pin of described chip LCMXO256/TQFP100, PR3A pin and PR2B pin are connected with the OUT pin of DC switch power module I chips RT9179 by LED 1, LED2 and LED3 respectively; The VCC pin of described chip 24LC02 is connected with the OUT pin of DC switch power module I chips RT9179; The PCLKT0-0/PT4A pin of described chip LCMXO256/TQFP100 is connected with the OUT pin of resistance R 1 with DC switch power module I chips RT9179 through resistance R 2 respectively with the PT3D pin; 1 pin of described jtag interface is connected with the OUT pin of DC switch power module I chips RT9179; The VCCIO1 pin of described chip LCMXO256/TQFP100 is connected with the OUT pin of DC switch power module I chips RT9179.Owing in the utility model 20 I/O input/output end ports are arranged, therefore the user can connect 20 alarm monitoring equipment or electrical equipment, and can freely select and be provided with 20 I/O manually and input or output state, also can send address instruction and carry out state configuration by the daemon software mode.

In the utility model, as Fig. 6, Fig. 8 and shown in Figure 9, described center base station signal transceiver comprises and has Flash flash memory and random access memory ram and the signal processing/Zigbee radio-frequency module II of ground connection and DC switch power module II, crystal oscillator II 2 and the microprocessor AXIS that is connected with signal processing/Zigbee radio-frequency module II simultaneously; Described signal processing/Zigbee radio-frequency module I enlarges equipment PA I by the electronic system signal and connects with the antenna II that is used for being connected with the wireless signal transmitter signal with low-noise wide-band amplifier LNA I; Described signal processing/Zigbee radio-frequency module I is by GPRS SMS module and the antenna III that is used for being connected with the mobile network for public signal; As shown in figure 10, the circuit catenation principle and the prior art of GPRS SMS module are similar, so do not give unnecessary details at this; Described DC switch power module I is connected with microprocessor AXIS; Be connected with crystal oscillator III3 on the described microprocessor AXIS, be used to connect the Ethernet modular converter and the data terminal equipment interface RS-232 of Ethernet interface.

As shown in Figure 7, in this specific embodiment, described signal processing/Zigbee radio-frequency module II comprises chip SMD4 and chip I P1220 8; 4 pin of described chip SMD4,6 pin, 7 pin, 5 pin are connected with TCK pin, TD0 pin, TDI pin, the TMS pin of chip I P1220 8 respectively; 2 pin of described chip SMD 4,3 pin and 9 pin are ground connection simultaneously; 1 pin of described chip SMD 5 is connected with the VCC pin of DC switch power module II chips ZT3243F; 4 pin of described chip SMD 4 are connected with the VCC pin of DC switch power module II chips ZT3243F with SMD 4 through resistance R 45; The RF-GND pin of described chip I P1220 8 is all through inductance L 4 ground connection; The ANT-OUT pin of described chip I P1220 8 enlarges equipment PA I by the electronic system signal and is connected with antenna IIANT1/NC1 with low-noise wide-band amplifier LNA I; The P2.4 pin of described chip I P1220 8 is connected through the base stage of resistance R 50 with triode Q1; The grounded emitter of described triode Q1; The collector electrode of described triode Q1 is connected with the VCC pin of resistance R 47 with DC switch power module II chips ZT3243F through LED 4; The equal ground connection of D-GND pin of described chip I P1220 8; The RX0 pin of described chip I P1220 8 is connected through the base stage of resistance R 6 with triode Q4; The grounded emitter of described triode Q4; The collector electrode of described triode Q4 is connected through the VCC pin of resistance R 5 with DC switch power module II chips ZT3243F; The Vav+ pin of described chip I P1220 8 is connected with the VCC pin of VCC pin with DC switch power module II chips ZT3243F; The TX0 pin of described chip I P1220 8 is connected through the base stage of resistance R 62 with triode Q5; The grounded emitter of described triode Q5; The collector electrode of described triode Q5 is connected through the VCC pin of resistance R 8 with DC switch power module II chips ZT3243F.

In the utility model, as shown in figure 11, described relay base station comprise have Flash flash memory and random access memory ram and simultaneously ground connection signal processing/Zigbee radio-frequency module III and the DC switch power module III that is connected with signal processing/Zigbee radio-frequency module III, be provided with and be used for the data terminal equipment interface RS-232 that is connected with computer and universal asynchronous reception/dispensing device UART II and the crystal oscillator III 5 of RS484; Described signal processing/Zigbee radio-frequency module III also enlarges equipment PAIII by the electronic system signal and connects with the antenna IV that is used for being connected with the wireless signal transmitter signal with the center base station signal transceiver with low-noise wide-band amplifier LNAIII.

In this specific embodiment, as Figure 12 and shown in Figure 13, described signal processing/Zigbee radio-frequency module III comprises chip SMD 6, chip I P1220 7, chip ADM485 8 and chip ADM3222 9; 5 pin of described chip SMD 6,7 pin, 4 pin and 6 pin are connected with TMS pin, TDI pin, TCK pin and the TD0 pin of chip I P1220 7 respectively; 2 pin of described chip SMD 6,3 pin and 9 pin are ground connection simultaneously; 1 pin of described chip SMD 6 is connected with the OUT pin of DC switch power module III chips LM2954 with 4 pin simultaneously; All RF-GND pin of described chip I P1220 7, all A-GND pin and all D-GND pin ground connection; The ANT-OUT pin of described chip I P1220 7 is connected with antenna IV; The P2.4 pin of described chip I P1220 7 is connected with the base stage of triode Q6 by resistance R 12; The grounded emitter of described triode Q6, its collector electrode is connected with the IN pin of resistance R 21 with DC switch power module III chips LM2954 by LED 7; The RX0 pin of described chip I P1220 7 is connected with the OUT pin of DC switch power module III chips LM2954 by resistance R 5; The TX0 pin of described chip I P1220 7 is connected with the OUT pin of DC switch power module III chips LM2954 by resistance R 2; The RESET pin of described chip I P1220 7 is connected with the OUT pin of DC switch power module III chips LM2954 by resistance R 6; Described chip I P1220 7Vav+ pin is connected with the OUT pin of VCC pin with DC switch power module III chips LM2954; The VCC pin of described chip ADM3222 9 is connected with the IN pin of DC switch power module III chip LM2954; Be connected capacitor C 1 between the C1+ pin of described chip ADM3222 9 and the C1-pin; Be connected capacitor C 2 between the C2+ pin of described chip ADM3222 9 and the C1-pin; The T1-IN pin of described chip ADM32229 is connected with 3 ends of NAND gate U2A; 1 end of described NAND gate U2A also is connected with the collector electrode of triode Q9 when being connected with DC switch power module III by resistance R 3 with 2 ends; The grounded emitter of described triode Q9, its base stage is connected with the TX0 pin of chip I P1220 by resistance R 4; The T1-IN pin of described chip ADM3222 9 also 9 ends of NAND gate U2C and the DI pin of 10 ends and chip ADM485 8 is connected; The T1-OUT pin of described chip ADM3222 9 is connected with 4 ends of NAND gate U2B; 6 ends of described NAND gate U2C also are connected with the collector electrode of triode Q10 when being connected with the IN pin of DC switch power module III chip LM2954 by resistance R 5; The grounded emitter of described triode Q10, its base stage also are connected with the RX0 pin of chip I P1220; When being connected with the RO pin of chip ADM485 8,5 ends of described NAND gate U2B also are connected with DC switch power module III by resistance R 8; 8 ends of described NAND gate U2C are connected with the RE pin simultaneously with the DE pin of chip ADM485 8; The GND pin ground connection of described chip ADM485 8; The VCC pin of described chip ADM485 8 is connected with the IN pin of DC switch power module III chip LM2954; The R1OUT pin of described chip ADM3222 9, R2OUT pin, R1-IN pin and R2-IN pin are connected with 2 pin, 8 pin, 3 pin and 7 pin of data terminal equipment interface RS-232 12 respectively; The EN pin of described chip ADM3222 9 and GND pin be ground connection respectively; The V+ pin of described chip ADM3222 9 is by capacitor C 3 ground connection; Its V-pin is by capacitor C 4 ground connection; The B pin of described chip ADM485 11 is connected with 1 pin with 2 pin of RS485 interface 13 with resistance R 12 by resistance R 13 respectively with the A pin; 1 pin of described RS485 interface 13 is connected through the IN pin of resistance R 24 with DC switch power module III chip LM2954 with 3 pin simultaneously; 2 pin of described RS485 interface 13 are through resistance R 22 ground connection.

The utility model network intelligent wireless control system mainly comprises two courses of work, one is that from bottom to top data transmission procedure is about to warning message and sends to user mobile phone, another is that top-down data transmission procedure is that the user will handle note by mobile phone and send on the wireless signal transmitter by the center base station signal transceiver, thereby realizes the Remote to household electrical appliance.

When the utility model was in from bottom to top data transmission procedure, as shown in figure 14, the workflow of wireless signal transmitter was:

1., after the beginning initialization, wireless signal transmitter carries out the operating state self check, so whether detected wireless signals transmitter interface and system health normal, exists unusually, then sends alarm signal:

If 2. System self-test is normal, then scan for wireless signals transmitter I/O port signal detects whether there is alarm signal, if there is not alarm signal, then again at scan for wireless signals transmitter I/O port signal;

If 3. there is the I/O port signal, then examine alarm signal again, after be sure oing to have alarm signal, then enter the preparation of reporting to the police, store alarms information;

4., then search the address, base station,, then enter further work if search local center base station transceiver; Whether if do not search local center base station transceiver, then searching is local relay base station, if, then enter next step, if the address, base station does not all search, then return and continue to search;

5., determine the base station object of required transmission after, then communicate and shake hands, if success then sends alarm signal,, then return to communicate again and shake hands if unsuccessful;

6., successfully after sending alarm signal, then transfer of data is finished, otherwise returns the preparation of reporting to the police.

When the utility model was in from bottom to top data transmission procedure, as shown in figure 15, the workflow of center base station was:

1., center base station at first carries out system initialization, needs the working condition of scan for networks then, if normal words enter next step, otherwise sends network unusual condition alarm signal;

2., if the network work situation is normal, the warning interrupting information of scan for wireless signals transmitter and relay base station then interrupts if exist to report to the police, and then need examine alarm signal, if there is not alarm signal, then need rescan warning;

3., after be sure oing there is alarm signal, entering and report to the police receiving preparation;

4., whether be local network alarm signal, if then communication handshake receives network alarming information if detecting; Otherwise need rescan the network alarming signal;

5., receive alarm signal after, center base station is handled warning message;

6., handle warning message after, center base station sends to warning unit or resident family mobile phone with the warning message of handling well by GPRS note form with center base station no signal transceiver.

When the utility model was in top-down data transmission procedure, as shown in figure 16, the workflow of center base station was:

1., center base station at first begins to carry out system initialization, searches the short message of resident family then by the GPRS module, if there is the GPRS of the resident family note signal of local network, then receives note; If there is no, then continue to search GPRS note signal;

2., receive resident family's note by the GPRS module, receive successfully after, with information stores; If unsuccessful, then continue to receive again the GPRS note signal of resident family;

3., handle short message, and behind the wireless signal transmitter object of instruction that definite note comprised and transmission, entry instruction sends preparation;

4., search the corresponding wireless signal transmitter of local network, if exist then enter next step; If do not search, then search local relay base station, if search, then enter next step operation, otherwise, return previous step search;

5., determine that good instruction sends object after, carry out intercommunication to shake hands, unsuccessful then return continuation;

6., shake hands successfully, then the short message instruction is sent to corresponding relay base station or wireless signal transmitter as intercommunication.

When the utility model was in top-down data transmission procedure, as shown in figure 17, the workflow of wireless signal transmitter was:

1., wireless signal transmitter at first begins to carry out system initialization, searches the command information from the upper layer network base station then, if there is the information from center base station or relay base station, then enters next step operation;

2., judge whether instruction into the local network base station, if, then enter and receive preparation, otherwise return, continue etc. to be searched;

3., receive preparation after, communicate the both hands handshake operation, if shake hands successfully, then receive base station command information, shake hands otherwise return again;

4., successfully receive after; Data are stored, and by the microprocessor in the wireless signal transmitter unpack, processing such as decoding, address assignment, instruction analysis, receive otherwise return again;

5., handle information after, carry out the dependent instruction operation, drive with respect to the I/O port operation, finish the remote auto controlled function;

6., will instruct the data transfer mode of final result by from bottom to top, send to center base station, resident family's mobile phone and warning unit, thereby realize remote man-machine control.

In the utility model intelligent radio alarm monitoring system, as shown in figure 18, the data processing work flow process of described relay base station is:

1., after the relay base station work, search the wireless signal transmitter of local network or the message interrupts request of center base station;

2., if existing interrupt request singal, relay base station then to enter relaying prepares, continue search and wait for otherwise return;

3., enter relaying preparation after, then communicate and shake hands with the wireless signal transmitter of required relaying or center base station, if native wireless signals transmitter or center base station and shake hands successfully then enter next step operation, otherwise, return again and shake hands;

4., after the communication handshake success, receive repeating signal information, receive successfully after, information is stored; Otherwise return, receive again;

5., the processor by relay base station carries out required trunk information processing such as error correction, fractionation, packing, amplification, and determines good relay object;

6., with relay object communicate shake hands after, send required relayed information, after success, the relay base station data processing finishes.

The utility model is not limited to use in the digitized home; it also is adapted at industrial circle or intelligent transportation field etc. industrial electrical equipment equipment or traffic route warning device etc. is carried out Long-distance Control, therefore uses the utility model to fall into protection range of the present utility model too at industrial circle or intelligent transportation field.

Claims (9)

1, a kind of network intelligent wireless control system, comprise all kinds of alarm monitoring equipment and the electric equipment that are installed in the subscriber unit, it is characterized in that: it also comprises the center base station that is arranged on Property Management of residence center or Surveillance center and is arranged on to have in the subscriber unit initiatively seeks all kinds of alarm monitoring equipment and electric equipment, and can in time detect the operating state situation and the timely wireless signal transmitter that detected data is sent to center base station of all kinds of alarm monitoring equipment and electric equipment; Described center base station comprises center base station signal transceiver that is provided with the GPRS module and the central Computerized monitor system that is connected with the center base station signal transceiver; For the MANET signal is connected, and the agreement between them is the Zigbee wireless protocols between described wireless signal transmitter and the center base station signal transceiver; Described center base station signal transceiver is connected by mobile network for public and 110, warning unit and sub-district mobile phones on duty such as 119 or 120 or user mobile phone signal; Described wireless signal transmitter is connected on the power control relay of buzzer, alarm lamp and electric equipment of alarm monitoring equipment.

2, network intelligent wireless control system according to claim 1 is characterized in that: described wireless signal transmitter comprise have Flash flash memory and random access memory ram and simultaneously ground connection signal processing/Zigbee radio-frequency module I and the DC switch power module I that is connected with signal processing/Zigbee radio-frequency module I, be provided with universal asynchronous reception/dispensing device UART I, crystal oscillator I (1) that is used for the data terminal equipment interface RS-232 that is connected with computer and the programmable I/O expansion module CPLD/FPGA that is provided with several I/O ports; Described signal processing/Zigbee radio-frequency module I also enlarges equipment PA I by the electronic system signal and connects with the antenna I that is used for being connected with center base station signal transceiver signal with low-noise wide-band amplifier LNA I; Described DC switch power module I is connected with programmable I/O expansion module CPLD/FPGA.

3, network intelligent wireless control system according to claim 2 is characterized in that: described signal processing/Zigbee radio-frequency module I comprises chip I P1221, chip SMD, chip ADM3222 (10) and chip ADM485 (11); The P3.5 pin of described chip I P1221, P3.4 pin, RXO pin and TXO pin are connected with T2OUT pin, T2-IN pin, T1OUT pin and the T1-IN pin of chip ADM3222 (10) respectively; The TMS pin of described chip I P1221, TCK pin, TDI pin and TDO pin are connected with 5 pin, 4 pin, 7 pin and 6 pin of chip SMD respectively; 2 pin of described chip SMD, 3 pin and 9 pin are ground connection after inductance L 1 simultaneously; All RF-GND pin ground connection of described chip I P1221; All the D-GND pin of described chip I P1221 and A-GND pin be ground connection after inductance L 1 simultaneously; The ANT-OUT pin of described chip I P1221 enlarges equipment PA I by the electronic system signal and is connected with antenna I with low-noise wide-band amplifier LNA I; Be connected with capacitor C 6 between the C1+ pin of described chip ADM3222 (10) and the C1-pin; Be connected with capacitor C 7 between the C2+ pin of described chip ADM3222 (10) and the C2-pin; The R1OUT pin of described chip ADM3222 (10), R2OUT pin, R1-IN pin and R2-IN pin are connected with 2 pin, 8 pin, 3 pin and 7 pin of data terminal equipment interface RS-232 (14) respectively; The EN pin of described chip ADM3222 (10) and GND pin are respectively through inductance L 1 ground connection; The V+ pin of described chip ADM3222 (10) is by capacitor C 8 and inductance L 1 ground connection; Its V-pin is by capacitor C 9 and inductance L 1 ground connection; Be connected with resistance R 9 and R8 between the D1 pin of described chip ADM485 (11) and the DE pin; The GND pin of described chip ADM485 (11) is through inductance L 1 ground connection; The B pin of described chip ADM485 (11) is connected with 1 pin with 2 pin of RS485 interface (15) with resistance R 12 by resistance R 13 respectively with the A pin; 4 pin of described chip SMD are connected with DC switch power module I with 1 pin; The VCC pin of described chip I P1221 is connected with DC switch power module I; The P2.4 pin of described chip I P1221, P3.1 pin, P3.2 pin, RXO pin and TXO pin all are connected with programmable I/O expansion module CPLD/FPGA; The VCC pin of described chip ADM3222 (10) is connected with DC switch power module I; The VCC pin of described chip ADM485 (11) is connected with DC switch power module I; The DI pin of described chip ADM485 (11), RO pin and DE pin all are connected with programmable I/O expansion module CPLD/FPGA; The DE pin of described chip ADM485 (11) is connected with DC switch power module I through resistance R 8 with the RE pin simultaneously; The A pin of described chip ADM485 (11) is connected with DC switch power module I with resistance R 10 through resistance R 12.

4, network intelligent wireless control system according to claim 2 is characterized in that: described programmable I/O expansion module CPLD/FPGA comprises chip 24LC02, chip LCMXO256/TQFP100, jtag interface, interface chip IO-1TO10, interface chip IO-11TO20, five chip block ULN2803C (U1, U3, U5, U6, U7) and five chip block 8P4R-22K (RP1, RP2, RP3, RP4, RP5); The A0 pin of described chip 24LC02, A1 pin, A2 pin, GDN pin and WP pin are through inductance L 1 ground connection; Described chip 24LC02 SCL pin and SDA pin simultaneously with signal processing/also be connected with the PT3D pin with the PCLKT0-0/PT4A pin of chip LCMXO256/TQFP100 respectively when Zigbee radio-frequency module I is connected; 2 pin of described jtag interface, 3 pin, 6 pin and 8 pin are connected with TD0 pin, TD1 pin, TMS pin and the TCK pin of chip LCMXO256/TQFP100 respectively; 7 pin of described jtag interface are through inductance L 1 ground connection; The PL2B pin of described chip LCMXO256/TQFP100, the PL3B pin, the PL3D pin, the PL4B pin, the PL5B pin, the PL5D pin, the PL6B pin, the PL7B pin, the PL7D pin, the PL8B pin, the PB2B pin, the PB4B pin, the PB4D pin, the PR9A pin, the PR7B pin, the PR6B pin, the PR4A pin, the PR3C pin, PT5A pin and PT4D pin respectively with the I1 pin of chip ULN2803C (U1), the I2 pin, the I3 pin, the I4 pin, the I5 pin, the I6 pin, the I7 pin, the I8 pin, the I1 pin of chip ULN2803C (U3), the I2 pin, the I3 pin, the I4 pin, the I5 pin, the I6 pin, the I7 pin, the I8 pin, the I1 pin of chip ULN2803C (U5), the I2 pin, I3 pin and I4 pin connect; The PL2A pin of described chip LCMXO256/TQFP100, the PL3A pin, the PL3C pin, the PL4A pin, the PL5A pin, the PL5C pin, the PL6A pin, the PL7A pin, the PL7C pin, the PL8A pin, the PB2A pin, the PB4A pin, the PB4C pin, the PR9B pin, the PR7C pin, the PR7A pin, the PR4B pin, the PR3D pin, PT5B pin and PT4E pin respectively with the O5 pin of chip ULN2803C (U5), the O6 pin, the O7 pin, the O8 pin, the O1 pin of chip ULN2803C (U6), the O2 pin, the O3 pin, the O4 pin, the O5 pin, the O6 pin, the O7 pin, the O8 pin, the O1 pin of chip ULN2803C (U7), the O2 pin, the O3 pin, the O4 pin, the O5 pin, the O6 pin, the O7 pin, the O8 pin connects; The VCCIO3 foot meridian capacitor C3 of described chip LCMXO256/TQFP100 and inductance L 1 ground connection; All GNDIO1 pin, GND pin and the GNDIO0 pin of described chip LCMXO256/TQFP100 are through inductance L 1 ground connection; The O1 pin of described chip ULN2803C (U1), O2 pin, O3 pin, O4 pin, O5 pin, O6 pin, O7 pin, O8 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin of 8 pin, 7 pin, 6 pin, 5 pin and the 8P4R-22K (RP2) of 8P4R-22K (RP1) respectively; The O1 pin of described chip ULN2803C (U3), O2 pin, O3 pin, O4 pin, O5 pin, O6 pin, O7 pin, O8 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin of 8 pin, 7 pin, 6 pin, 5 pin and the 8P4R-22K (RP4) of 8P4R-22K (RP3) respectively; The O1 pin of described chip ULN2803C (U5), O2 pin, O3 pin, O4 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin of 8P4R-22K (RP5) respectively; 1 pin of described chip 8P4R-22K (RP1), 2 pin, 3 pin, 4 pin are connected with chip ULN2803C (U5) I5 pin, I6 pin, I7 pin, I8 pin respectively; 1 pin of described chip 8P4R-22K (RP2), 2 pin, 3 pin, 4 pin are connected with chip ULN2803C (U6) I1 pin, I2 pin, I2 pin, I4 pin respectively; Described chip ULN2803C (U6) I5 pin, I6 pin, I7 pin, I8 pin respectively with 1 pin, 2 pin, 3 pin, 4 pin of chip 8P4R-22K (RP3); 1 pin of described chip 8P4R-22K (RP4), 2 pin, 3 pin, 4 pin are connected with chip ULN2803C (U7) I1 pin, I2 pin, I2 pin, I4 pin respectively; Described chip ULN2803C (U7) I5 pin, I6 pin, I7 pin, I8 pin are connected with 1 pin, 2 pin, 3 pin, 4 pin of chip 8P4R-22K (RP5) respectively; 1 pin of described interface chip IO-1TO10,2 pin, 3 pin, 4 pin, 5 pin, 7 pin, 8 pin, 9 pin, 10 pin, 11 pin are connected with 8 pin, 7 pin, 6 pin, 5 pin, 8 pin of chip 8P4R-22K (RP2), 7 pin, 6 pin, 5 pin, 8 pin of chip 8P4R-22K (RP3), 7 pin of described chip 8P4R-22K (RP1) respectively; 1 pin of described interface chip IO-1TO20,2 pin, 3 pin, 4 pin, 5 pin, 7 pin, 8 pin, 9 pin, 10 pin, 11 pin are connected with 6 pin, 5 pin, 8 pin of chip 8P4R-22K (RP4), 7 pin, 6 pin, 5 pin, 8 pin of chip 8P4R-22K (RP5), 7 pin, 6 pin, 5 pin of described chip 8P4R-22K (RP3) respectively; 6 pin of described interface chip IO-1TO10 and 6 pin of interface chip IO-11TO20 are respectively through inductance L 1 ground connection; The GND pin of described five chip block ULN2803C (U1, U3, U5, U6, U7) is respectively through inductance L 1 ground connection; 12 pin of the 12 pin interface chip IO-11TO20 of described interface chip IO-1TO10 are connected with the COM pin of chip ULN2803C (U1, U3, U5) simultaneously; Be connected with resistance R 21 between the VCC pin of described chip LCMXO256/TQFP100 and the SLEEPN pin; The PB5C pin of described chip LCMXO256/TQFP100, PB5D pin, PR8A pin, PR5C pin, PR5B pin and PR5A pin while and described signal processing/Zigbee radio-frequency module I; The PR3B pin of described chip LCMXO256/TQFP100, PR3A pin and PR2B pin are connected with DC switch power module I by LED 1, LED2 and LED3 respectively; The VCC pin of described chip 24LC02 is connected with DC switch power module I; The PCLKTO-0/PT4A pin of described chip LCMXO256/TQFP100 is connected with DC switch power module I with resistance R 1 through resistance R 2 respectively with the PT3D pin; 1 pin of described jtag interface is connected with DC switch power module I; The VCCIO1 pin of described chip LCMXO256/TQFP100 is connected with DC switch power module I.

5, network intelligent wireless control system according to claim 1 is characterized in that: described center base station signal transceiver comprises signal processing/Zigbee radio-frequency module II and the DC switch power module II that is connected with signal processing/Zigbee radio-frequency module II, crystal oscillator II (2) and the microprocessor AXIS that has Flash flash memory and random access memory ram and while ground connection; Described signal processing/Zigbee radio-frequency module I enlarges equipment PA I by the electronic system signal and connects with the antenna II that is used for being connected with the wireless signal transmitter signal with low-noise wide-band amplifier LNA I; Described signal processing/Zigbee radio-frequency module I is by GPRS SMS module and the antenna III that is used for being connected with the mobile network for public signal; Described DC switch power module I is connected with microprocessor AXIS; Be connected with crystal oscillator III (3) on the described microprocessor AXIS, be used to connect the Ethernet modular converter and the data terminal equipment interface RS-232 of Ethernet interface.

6, network intelligent wireless control system according to claim 5 is characterized in that: described signal processing/Zigbee radio-frequency module II comprises chip SMD (4) and chip I P1220 (8); 4 pin of described chip SMD (4), 6 pin, 7 pin, 5 pin are connected with TCK pin, TDO pin, TDI pin, the TMS pin of chip I P1220 (8) respectively; 2 pin of described chip SMD (4), 3 pin and 9 pin are ground connection simultaneously; 1 pin of described chip SMD (4) is connected with DC switch power module II; 4 pin of described chip SMD (4) are connected with DC switch power module II with SMD (4) through resistance R 45; The RF-GND pin of described chip I P1220 (8) is all through inductance L 4 ground connection; The ANT-OUT pin of described chip I P1 220 (8) enlarges equipment PA I by the electronic system signal and is connected with antenna II ANT1/NC1 with low-noise wide-band amplifier LNA I; The P2.4 pin of described chip I P1220 (8) is connected through the base stage of resistance R 50 with triode Q1; The grounded emitter of described triode Q1; Described triode Q1 collector electrode be connected with DC switch power module II with resistance R 47 through LED 4; The equal ground connection of D-GND pin of described chip I P1220 (8); The RXO pin of described chip I P1220 (8) is connected through the base stage of resistance R 6 with triode Q4; The grounded emitter of described triode Q4; The collector electrode of described triode Q4 is connected with DC switch power module II through resistance R 5; The Vav+ pin of described chip I P1220 (8) is connected with DC switch power module II with the VCC pin; The TXO pin of described chip I P1220 (8) is connected through the base stage of resistance R 62 with triode Q5; The grounded emitter of described triode Q5; Described triode Q5 collector electrode be connected with DC switch power module II through resistance R 8.

6, network intelligent wireless control system according to claim 1 is characterized in that: be connected with the relay base station signal amplifier that can play relaying, amplification, error correction and buffer memory effect to signal between described wireless signal transmitter and the center base station signal transceiver.

7, intelligent radio alarm monitoring system according to claim 6 is characterized in that: described relay base station signal amplifier comprise have Flash flash memory and random access memory ram and simultaneously ground connection signal processing/Zigbee radio-frequency module III and the DC switch power module III that is connected with signal processing/Zigbee radio-frequency module III, be provided with and be used for the data terminal equipment interface RS-232 that is connected with computer and universal asynchronous reception/dispensing device UART II and the crystal oscillator III (5) of RS484; Described signal processing/Zigbee radio-frequency module III also enlarges equipment PAIII by the electronic system signal and connects with the antenna IV that is used for being connected with the wireless signal transmitter signal with the center base station signal transceiver with low-noise wide-band amplifier LNAIII.

8, intelligent radio alarm monitoring system according to claim 7 is characterized in that: described signal processing/Zigbee radio-frequency module III comprises chip SMD (6), chip I P1220 (7), chip ADM485 (8) and chip ADM3222 (9); 5 pin of described chip SMD (6), 7 pin, 4 pin and 6 pin are connected with TMS pin, TDI pin, TCK pin and the TDO pin of chip I P1220 (7) respectively; 2 pin of described chip SMD (6), 3 pin and 9 pin are ground connection simultaneously; 1 pin of described chip SMD (6) is connected with DC switch power module III with 4 pin simultaneously; All RF-GND pin of described chip I P1220 (7), all A-GND pin and all D-GND pin ground connection; Described chip I P1220 (7) ANT-OUT pin is connected with antenna IV; The P2.4 pin of described chip I P1220 (7) is connected with the base stage of triode Q6 by resistance R 12; The grounded emitter of described triode Q6, its collector electrode is connected with DC switch power module III with resistance R 21 by LED 7; The RXO pin of described chip I P1220 (7) is connected with DC switch power module III by resistance R 5; The TXO pin of described chip I P1220 (7) is connected with DC switch power module III by resistance R 2; The RESET pin of described chip I P1220 (7) is connected with DC switch power module III by resistance R 6; Described chip I P1220 (7) Vav+ pin is connected with DC switch power module III with the VCC pin; The VCC pin DC switch power module III of described chip ADM3222 (9) connects; Be connected capacitor C 1 between the C1+ pin of described chip ADM3222 (9) and the C1-pin; Be connected capacitor C 2 between the C2+ pin of described chip ADM3222 (9) and the C1-pin; The T1-IN pin of described chip ADM3222 (9) is connected with 3 ends of NAND gate U2A; 1 end of described NAND gate U2A also is connected with the collector electrode of triode Q9 when being connected with DC switch power module III by resistance R 3 with 2 ends; The grounded emitter of described triode Q9, its base stage is connected with the TXO pin of chip I P1220 by resistance R 4; The T1-IN pin of described chip ADM3222 (9) also 9 ends of NAND gate U2C and the DI pin of 10 ends and chip ADM485 (8) is connected; The T1-OUT pin of described chip ADM3222 (9) is connected with 4 ends of NAND gate U2B; 6 ends of described NAND gate U2C also are connected with the collector electrode of triode Q10 when being connected with DC switch power module III by resistance R 5; The grounded emitter of described triode Q10, its base stage also are connected with the RXO pin of chip I P1220; When being connected with the RO pin of chip ADM485 (8), 5 ends of described NAND gate U2B also are connected with DC switch power module III by resistance R 8; 8 ends of described NAND gate U2C are connected with the RE pin simultaneously with the DE pin of chip ADM485 (8); The GND pin ground connection of described chip ADM485 (8); The VCC pin of described chip ADM485 (8) is connected with DC switch power module III; The R1OUT pin of described chip ADM3222 (9), R2OUT pin, R1-IN pin and R2-IN pin are connected with 2 pin, 8 pin, 3 pin and 7 pin of data terminal equipment interface RS-232 (12) respectively; The EN pin of described chip ADM3222 (9) and GND pin be ground connection respectively; The V+ pin of described chip ADM3222 (9) is by capacitor C 3 ground connection; Its V-pin is by capacitor C 4 ground connection; The B pin of described chip ADM485 (11) is connected with 1 pin with 2 pin of RS485 interface (13) with resistance R 12 by resistance R 13 respectively with the A pin; 1 pin of described RS485 interface (13) is connected with DC switch power module III through resistance R 24 with 3 pin simultaneously; 2 pin of described RS485 interface (13) are through resistance R 22 ground connection.

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