CN102307222A - Intelligent greenhouse demonstration measurement and control system based on Internet of things technology - Google Patents
Intelligent greenhouse demonstration measurement and control system based on Internet of things technology Download PDFInfo
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Abstract
The invention discloses an intelligent greenhouse demonstration measurement and control system based on an Internet of things technology. The intelligent greenhouse demonstration measurement and control system comprises a plurality of field control station networks, a plurality of embedded gateways and a central server, wherein one field control station network is accessed into one embedded gateway; and the embedded gateways realize communication between the central server and the field control station networks. The intelligent greenhouse demonstration measurement and control system acquires parameters inside and outside a greenhouse and parameters of crop growth soil constitutes through a sensing network of the Internet of things; a network layer of the Internet of things combines various data transmission networks and communicates with the central server through an embedded Ethernet controller interface, so that communication among various nodes is realized; and an application layer, namely the central server, of the Internet of things realizes optimization control, page publish and short message inquiry control for the parameters.
Description
Technical field
The present invention relates to warmhouse booth system field, be specially a kind of intelligent greenhouse demonstration TT&C system based on technology of Internet of things.
Background technology
Internet of Things is meant through various information sensing equipment; Like various devices and technology such as transducer, radio-frequency (RF) identification (RFID) technology, global positioning system, infrared inductor, laser scanner, gas sensors; Gather in real time anyly need to monitor, connect, interactive object or process; Gather the information of various needs, combine a huge network that forms with the Internet.Its objective is and realize thing and thing, thing and people, all article are connected with network, convenient identification, management and control.
Warmhouse booth is the infrastructure that realizes industrialized agriculture and factory farming, is the basic facilities of crop growth environment manual adjustment.Can be for a long time create best growth conditions through warmhouse booth, avoid the influence of extraneous harsh weather, reach and regulate crop term, promote crop growth, prevention and elimination of disease and pests and purpose such as improve the yield and quality for crop.The warmhouse booth plantation has obtained promotion and application rapidly for the living standard that improves people brings great convenience.Envirment factors such as the temperature in the planting environment, humidity, illuminance, CO2 concentration have very big influence to the production of crop.The conventional artificial control mode is difficult to reach the requirement of scientific and reasonable plantation, at present domesticly can realize above-mentioned envirment factor the system of monitoring is also rare automatically, has multi-functional large-scale attached-greenhouse control system abroad and costs an arm and a leg and introduce, and is not suitable for national conditions.
Summary of the invention
The purpose of this invention is to provide a kind of intelligent greenhouse demonstration TT&C system, to realize to more optimal control of warmhouse booth and management based on technology of Internet of things.
In order to achieve the above object, the technical scheme that the present invention adopted is:
Intelligent greenhouse demonstration TT&C system based on technology of Internet of things is characterized in that: comprise a plurality of field control station networks, a plurality of embedded gateway, central server; Embedded gateway of phenomenon control station network insertion, said embedded gateway is realized the communication of central server and field control station network;
Said field control station network comprises sensing node, XM, transmission trunking node, wherein:
Said sensing node is divided into two kinds; A kind of sensing node is carried out measured sensor to greenhouse and is constituted by multiple; Another kind of sensing node is carried out measured sensor to plant in the greenhouse and is constituted by multiple; Wherein each sensor network that greenhouse is measured disposes the Zigbee wireless transport module, and each sensor network that plant is measured disposes the RFID frequency read/write;
Said XM is each final controlling element of greenhouse parameter for a change, and said final controlling element is connected with relay respectively, realizes the change to the greenhouse parameter through each final controlling element of relay control;
The communication network that said transmission trunking node is made up of sensing node and embedded gateway constitutes; Wherein greenhouse is carried out sensing node that measured sensor constitutes by Zigbee wireless transport module and corresponding embedded gateway formation Zigbee network; The sensing node that plant in the greenhouse is carried out the measured sensor formation constitutes the RFID communication network by RFID frequency read/write and corresponding embedded gateway; Each Zigbee wireless transport module, RFID frequency read/write also dispose data processing unit respectively; Said data processing unit is to the data format analysis processing; Each sensor of the sensing node of said field control station network transmits information by the transmission trunking node to embedded gateway, with the coordination that realizes converging data and and gateway between transmission;
Said embedded gateway comprises Single Chip Microcomputer (SCM) system; Insert the embedded Ethernet controller interface of Single Chip Microcomputer (SCM) system; Wherein be provided with the Zigbee radio network interface in the embedded gateway corresponding to the sensing node that greenhouse is measured; Said embedded gateway is through corresponding Zigbee wireless transport module communication in Zigbee radio network interface and the field control station network; Be provided with the RFID radio network interface in the embedded gateway corresponding to the sensing node that plant is measured; Said embedded gateway is through corresponding RFID frequency read/write communication in RFID radio network interface and the field control station network; Said embedded gateway is responsible for interconnecting of field control station network and central server; Protocol stack changes and local control, wherein:
Be circumscribed with E2PROM memory, real-time timepiece chip, A/D converter interface, expansion I/O interface, power supply module on the said Single Chip Microcomputer (SCM) system; Be used to control corresponding sensing node to the on-site parameters data acquisition and processing (DAP); And parameter transferred to central server, accept the parameter in the order monitoring greenhouse that central server assigns simultaneously;
Said Zigbee radio network interface comprises the Zigbee chip; The Zigbee chip links to each other through the UART interface with Single Chip Microcomputer (SCM) system; With IEEE 802.15.4 standard, Zigbee 2006 protocol construction on-site wireless communication networks; Single Chip Microcomputer (SCM) system and said transmission trunking node communicate in the realization embedded gateway, the information that transmitting, monitoring is on-the-spot;
Said RFID radio network interface comprises RFID radio frequency chip, single chip control module, and the RFID radio frequency chip carries out read-write operation with the 14443A protocol specification to the RFID frequency read/write on the plant;
Said embedded Ethernet controller interface comprises the independent ethernet controller of band SPI interface; Single Chip Microcomputer (SCM) system is through embedded Ethernet controller and said central server communication in the said embedded gateway; Said ethernet controller meets whole standards of IEEE 802.3; Adopted a series of packet filtering mechanism to limit to importing packet into; Ethernet controller also provides an inner DMA module, to realize that rapid data is handled up and the IP verification and the calculating of hardware supports;
Said central server comprises gsm module, the switch of industry PC, band USB interface;
Said industry PC is connected with the embedded gateway communication through switch, is used for the issue control at web interface, and the GSM inquiry service has write in the industry PC greenhouse parameter optimization control algolithm;
Said gsm module inserts industry PC through USB interface, and gsm module is through GSM network and outside mobile communication, and mobile phone can inquire about, control the environmental parameter in greenhouse to central server through the note of gsm module transmission set form;
Said switch is responsible for industry PC communication in each embedded gateway and the central server is connected, and realizes the transmission of the gateway data of a plurality of field control station networks.
Described intelligent greenhouse demonstration TT&C system based on technology of Internet of things; It is characterized in that: constitute in the field control station network of sensing node corresponding to greenhouse being carried out measured sensor, each transducer constitutes greenhouse wireless data acquisition sensing net through the Zigbee wireless transport module in the sensing node.
Described intelligent greenhouse demonstration TT&C system based on technology of Internet of things is characterized in that: the sensing layer of said sensing node, the networking of XM homologue; The network layer of said transmission trunking node, the networking of embedded gateway homologue; Said central server homologue working application layer.
The present invention through the sensing net of Internet of Things gather inside and outside the greenhouse, plant growth soil constituent parameter; The network layer of Internet of Things merges the several data transmission network, communicates by letter with central server with the embedded Ethernet controller interface at last, realizes mutual communication between each node; The Internet of Things application layer is that central server is realized Parameter Optimization control, page issue, message search control.
Compared with prior art, beneficial effect of the present invention is embodied in:
1, based on the multitiered network structure
System of the present invention comprises various data transmission networks: Zigbee transmission network, RFID transmission network, Ethernet.Zigbee is a kind of short-range wireless networks communication technology of being absorbed in low-power consumption, low cost, low complex degree, low rate; Advantages such as RFID has that read or write speed is fast, batch identification, memory space are big, long service life, safe, Real-time and Dynamic communication; So the on-site wireless sensing netting gear that is made up by Zigbee and RFID has above-mentioned advantage.Ethernet is with low cost to have improved the communication performance of system with transmitting high speed.
2, several data information fusion
Because the apperceive characteristic that the Internet of Things warmhouse booth is abundant; Each network of native system comprises collection and transmission data separately; To the format differences of transfer of data between the heterogeneous networks, adopted based on the ICP/IP protocol embedded gateway and realized the fusion of transfer of data between the multiple network and collaborative.
3, multiple control modes realizes more convenient rational management
Central server can be realized real-time regulated through leading subscriber through page issue parameter information in the system of the present invention in the Internet; Include optimized Algorithm and can realize the automatic adjusting between sensing node and the action node; Central server has the GSM searching platform, and mobile phones enquiring control is provided, and makes the restriction of regulating on not free and the space; Simultaneity factor also provides the control of adjusting manually, really realizes omnibearing control.
4, the Internet of Things greenhouse system that possesses intellectuality and cloud computing technology
System of the present invention has comprised Internet of Things cloud computing technical characterictic based on the Internet of Things system, realizes the resource-sharing between the different technologies platform, has promoted the Internet of Things information processing capability.Mutual perception between each sub-systems, intelligent adjusting have increased the convenient flexibility of system.
Description of drawings
Fig. 1 is the block diagram of system of the present invention.
Fig. 2 is a central server software flow pattern involved in the present invention.
Fig. 3 is the present invention and Internet of Things and osi model corresponding relation figure.
Embodiment
As shown in Figure 1, system of the present invention forms and comprises field control station net, embedded gateway, central server;
The field control station network is placed in inside and outside the warmhouse booth; Comprise outdoor meteorological sensor; The room parameter transducer; The cultivation soil detecting sensor that crop is traced to the source; Blower fan and heater action node; And corresponding Z igbee; The RFID wireless sense network; In the corresponding local installation room of crop of plantation, reach the soil detecting sensor; The outdoor mounted wind speed; Wind direction; Rain sensor is gathered corresponding environmental parameter; The foundation in control greenhouse is provided; The action node is being received the corresponding folding circulation blower fan in instruction back; Heater device carries out parameter regulation, in each sensing net, has set up some via nodes realization data coordination transmission for fear of the distance and the flow restriction of transfer of data;
Embedded gateway comprises that Single Chip Microcomputer (SCM) system, Zigbee radio network interface, RFID radio network interface, embedded Ethernet controller interface are connected with switch; Realizing that multiple sensing net merges finally to be connected with central server with the Ethernet control interface provides parameter and transmits control command; Embedded gateway is responsible for the interconnecting of field control station network and central server, protocol stack changes and local control, wherein:
It is embedded microprocessor, E2PROM memory, real-time timepiece chip, A/D converter interface and expansion I/O interface, the power supply module of STC12C5A60S2 that Single Chip Microcomputer (SCM) system adopts model; Be used to control the on-site parameters data acquisition and processing (DAP) and be transferred to center management server, accept the parameter in the order monitoring greenhouse that server command assigns simultaneously;
The Zigbee radio network interface comprises that model is the Zigbee chip of CC2430; The Zigbee chip links to each other through the UART interface with Single Chip Microcomputer (SCM) system; With IEEE 802.15.4 standard, Zigbee 2006 protocol construction on-site wireless communication networks; Realize communicating the information that transmitting, monitoring is on-the-spot with on-the-spot Zigbee network;
The RFID radio network interface comprises that model is RFID radio frequency chip, the single chip control module of FM1702NL; Mifare 1 S50RFID frequency read/write on the RFID radio frequency chip is traced to the source to plant with the 14443A protocol specification carries out read-write operation, and the read-write content is soil information, the implantation time of the detected cultivation of soil detecting sensor and goes out the garden time;
The embedded Ethernet controller interface comprises that the model of band SPI interface is the independent ethernet controller of ENC28J60.Ethernet controller meets whole standards of IEEE 802.3, has adopted a series of packet filtering mechanism to limit importing packet into.It also provides an inner DMA module, to realize that rapid data is handled up and the IP verification and the calculating of hardware supports;
Central server comprises industry PC, has the gsm module of USB interface, switch; Realize the page issue of greenhouse control; Land the adjusting of control greenhouse parameter through manager's username and password; Gsm module inserts industry PC through USB interface; The user inquires about to the note that industry PC sends set form through gsm module through mobile phone; Can querying server to AT instruction resolve, according to the environmental parameter of command request control warmhouse booth.Industry PC be used for the web interface issue control, GSM inquiry service, with the communicating by letter of embedded gateway, contain greenhouse parameter optimization control algolithm.In addition, can regulate manually at the scene.
In the practical implementation; The transducer of tyre Zigbee radio network interface has constituted on-the-spot Zigbee communication network through the Zigbee radio network interface in the various greenhouses; Each transducer and corresponding Z igbee radio network interface can carry out the expansion of any amount according to the needs of the reality in greenhouse; Can cover fully by the Zigbee communication network in the warmhouse booth; Wherein set up the transmission trunking node, the transfer of data of a large amount of networks is coordinated.Embedded gateway and each sensing net are set up the transmission trunking node, the fusion of realization multiple network and collaborative.Embedded gateway is connected with central server in the Internet through Ethernet interface; The data that the scene is detected send to central server provides various control methods, comprises the automatic adjusting of page issue on the internet, GSM message search, inner optimized Algorithm etc.This warmhouse booth system configuration based on technology of Internet of things, favorable expandability is convenient to control, can reduce system's construction cost, improves the network coverage and autgmentability.
As shown in Figure 2, this real system centre server software workflow diagram, its step is following:
Central server is through setting up communication between socket module and the embedded gateway; Environment, plant growth parameter(s) that the scene is recorded transmit; Store database into through the Mysql technology; And carry out the page on the internet through XML and PHP language and issue; The user can pass through the web browser, inquires about all information of monitored device whenever and wherever possible.Simultaneously, server receives the instruction that the user submits to through the web service, and former road is returned, and the action node is controlled; Write the message search control section through the MSCOMM control with C++ in addition, instruction is resolved to AT, when receiving the short message enquiry instruction; Resolve command; Current environment parameter and soil information can be able to be issued designated mobile phone, when receiving control command, the action node controlled; The threshold value of each parameter can be write in the database,, unmanned close-loop automatic adjustment of participating in can be realized through optimized Algorithm in view of the relation between each parameter.
As shown in Figure 3, the relation between native system and Internet of Things and the osi model:
On-the-spot data acquisition and parameter are handled the sensing layer corresponding to Internet of Things, i.e. physical layer and data link layer in the OSI seven layer model; Various Zigbee, RFID, GSM, Ethernet transmission network are corresponding to the network layer of Internet of Things, i.e. physical layer and transport layer in the OSI seven layer model; The GSM of greenhouse parameter inquiry, page issue, optimized Algorithm are corresponding to the application layer of Internet of Things, i.e. application layer and application program in the osi model.The invention system does not contain presentation layer and the session layer in the osi model, and its function how realizes in the network layer of Internet of Things, also can realize in application layer.
Claims (3)
1. based on the intelligent greenhouse demonstration TT&C system of technology of Internet of things, it is characterized in that: comprise a plurality of field control station networks, a plurality of embedded gateway, central server; Embedded gateway of phenomenon control station network insertion, said embedded gateway is realized the communication of central server and field control station network;
Said field control station network comprises sensing node, XM, transmission trunking node, wherein:
Said sensing node is divided into two kinds; A kind of sensing node is carried out measured sensor to greenhouse and is constituted by multiple; Another kind of sensing node is carried out measured sensor to plant in the greenhouse and is constituted by multiple; Wherein each sensor network that greenhouse is measured disposes the Zigbee wireless transport module, and each sensor network that plant is measured disposes the RFID frequency read/write;
Said XM is each final controlling element of greenhouse parameter for a change, and said final controlling element is connected with relay respectively, realizes the change to the greenhouse parameter through each final controlling element of relay control;
The communication network that said transmission trunking node is made up of sensing node and embedded gateway constitutes; Wherein greenhouse is carried out sensing node that measured sensor constitutes by Zigbee wireless transport module and corresponding embedded gateway formation Zigbee network; The sensing node that plant in the greenhouse is carried out the measured sensor formation constitutes the RFID communication network by RFID frequency read/write and corresponding embedded gateway; Each Zigbee wireless transport module, RFID frequency read/write also dispose data processing unit respectively; Said data processing unit is to the data format analysis processing; Each sensor of the sensing node of said field control station network transmits information by the transmission trunking node to embedded gateway, with the coordination that realizes converging data and and gateway between transmission;
Said embedded gateway comprises Single Chip Microcomputer (SCM) system; Insert the embedded Ethernet controller interface of Single Chip Microcomputer (SCM) system; Wherein be provided with the Zigbee radio network interface in the embedded gateway corresponding to the sensing node that greenhouse is measured; Said embedded gateway is through corresponding Zigbee wireless transport module communication in Zigbee radio network interface and the field control station network; Be provided with the RFID radio network interface in the embedded gateway corresponding to the sensing node that plant is measured; Said embedded gateway is through corresponding RFID frequency read/write communication in RFID radio network interface and the field control station network; Said embedded gateway is responsible for interconnecting of field control station network and central server; Protocol stack changes and local control, wherein:
Be circumscribed with E2PROM memory, real-time timepiece chip, A/D converter interface, expansion I/O interface, power supply module on the said Single Chip Microcomputer (SCM) system; Be used to control corresponding sensing node to the on-site parameters data acquisition and processing (DAP); And parameter transferred to central server, accept the parameter in the order monitoring greenhouse that central server assigns simultaneously;
Said Zigbee radio network interface comprises the Zigbee chip; The Zigbee chip links to each other through the UART interface with Single Chip Microcomputer (SCM) system; With IEEE 802.15.4 standard, Zigbee 2006 protocol construction on-site wireless communication networks; Single Chip Microcomputer (SCM) system and said transmission trunking node communicate in the realization embedded gateway, the information that transmitting, monitoring is on-the-spot;
Said RFID radio network interface comprises RFID radio frequency chip, single chip control module, and the RFID radio frequency chip carries out read-write operation with the 14443A protocol specification to the RFID frequency read/write on the plant;
Said embedded Ethernet controller interface comprises the independent ethernet controller of band SPI interface; Single Chip Microcomputer (SCM) system is through embedded Ethernet controller and said central server communication in the said embedded gateway; Said ethernet controller meets whole standards of IEEE 802.3; Adopted a series of packet filtering mechanism to limit to importing packet into; Ethernet controller also provides an inner DMA module, to realize that rapid data is handled up and the IP verification and the calculating of hardware supports;
Said central server comprises gsm module, the switch of industry PC, band USB interface;
Said industry PC is connected with the embedded gateway communication through switch, is used for the issue control at web interface, and the GSM inquiry service has write in the industry PC greenhouse parameter optimization control algolithm;
Said gsm module inserts industry PC through USB interface, and gsm module is through GSM network and outside mobile communication, and mobile phone can inquire about, control the environmental parameter in greenhouse to central server through the note of gsm module transmission set form;
Said switch is responsible for industry PC communication in each embedded gateway and the central server is connected, and realizes the transmission of the gateway data of a plurality of field control station networks.
2. the intelligent greenhouse demonstration TT&C system based on technology of Internet of things according to claim 1; It is characterized in that: constitute in the field control station network of sensing node corresponding to greenhouse being carried out measured sensor, each transducer constitutes greenhouse wireless data acquisition sensing net through the Zigbee wireless transport module in the sensing node.
3. the intelligent greenhouse demonstration TT&C system based on technology of Internet of things according to claim 1 is characterized in that: the sensing layer of said sensing node, the networking of XM homologue; The network layer of said transmission trunking node, the networking of embedded gateway homologue; Said central server homologue working application layer.
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Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101013321A (en) * | 2007-02-07 | 2007-08-08 | 浙江大学 | Intelligent actuator of greenhouse based on Ethernet and wireless sensor network |
CN201004177Y (en) * | 2007-01-16 | 2008-01-09 | 浙江大学 | A conservatory parameter measurement and monitoring system based on embedded technology |
WO2010046939A1 (en) * | 2008-10-25 | 2010-04-29 | Microlaben S.R.L. | Wireless system for greenhouse monitoring and control |
CN101827007A (en) * | 2010-04-19 | 2010-09-08 | 中兴通讯股份有限公司 | Method and device for interconnecting sensor network and mobile terminal and network connection equipment |
CN201750562U (en) * | 2010-07-31 | 2011-02-16 | 大连工业大学 | Device for interconnecting the wireless sensor network with the internet and the mobile communication net |
CN102045896A (en) * | 2010-11-22 | 2011-05-04 | 中山爱科数字科技有限公司 | Virtual Internet-of-things gateway system capable of realizing multiprotocol and network self-adapting |
-
2011
- 2011-05-07 CN CN201110117123XA patent/CN102307222B/en not_active Expired - Fee Related
Patent Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201004177Y (en) * | 2007-01-16 | 2008-01-09 | 浙江大学 | A conservatory parameter measurement and monitoring system based on embedded technology |
CN101013321A (en) * | 2007-02-07 | 2007-08-08 | 浙江大学 | Intelligent actuator of greenhouse based on Ethernet and wireless sensor network |
WO2010046939A1 (en) * | 2008-10-25 | 2010-04-29 | Microlaben S.R.L. | Wireless system for greenhouse monitoring and control |
CN101827007A (en) * | 2010-04-19 | 2010-09-08 | 中兴通讯股份有限公司 | Method and device for interconnecting sensor network and mobile terminal and network connection equipment |
CN201750562U (en) * | 2010-07-31 | 2011-02-16 | 大连工业大学 | Device for interconnecting the wireless sensor network with the internet and the mobile communication net |
CN102045896A (en) * | 2010-11-22 | 2011-05-04 | 中山爱科数字科技有限公司 | Virtual Internet-of-things gateway system capable of realizing multiprotocol and network self-adapting |
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