KR101067064B1 - Integrated Home Network System Using SCPSimple Control Protocoland Method thereof - Google Patents

Abstract

The present invention relates to an integrated home network system and a configuration method using SCP, and more particularly, PLC, which is a wired communication module, between a low-performance CPU-based home appliance and a special purpose IP non-embedded device in a home network application. (Power Line Communication) The present invention relates to an integrated home network system and a configuration method using SCP, which can be applied to a UPnP network using a communication technology.

An integrated home network system utilizing SCP according to the present invention includes an SCP network to which a plurality of SCP devices are connected; A UPnP network to which a plurality of UPnP devices are connected; And an SCP-to-UPnP bridge connecting the SCP network and the UPnP network, and the plurality of SCP devices can be controlled as one logical network without a separate mechanical bridge configuration.

SCP-to-UPnP Bridge, ASA, IP Non-Embedded Device, CPC

Description

Integrated Home Network System Using SCP (Simple Control Protocol) and Method

The present invention relates to an integrated home network system and a configuration method using SCP, and more particularly, PLC, which is a wired communication module, between a low-performance CPU-based home appliance and a special purpose IP non-embedded device in a home network application. (Power Line Communication) The present invention relates to an integrated home network system and a configuration method using SCP, which can be applied to a UPnP network using a communication technology.

Home network (Home Network) is a technology that can control or communicate with the indoor equipment, especially by connecting all the electrical devices used in the home to communicate with each other.

However, the standardization on the home network has not been achieved yet, and a home network is formed by forming a network individually using a wired method such as PLC (Power Line Communication) and wireless methods such as Bluetooth, WLAN, and Zigbee. It is. In addition, home network protocols are also being developed separately for each wired and wireless system.

In order to use Zigbee of 900MHz band, which is the standard of home wireless home network standard that was established in 2003, for the purpose of controlling lights and remote controllers, commercial chips and various application products are under development.Bluetooth, which guarantees transmission speed of 1Mbps, We have decided to follow the existing standard scheme, and for the UWB (Ultra Wide Band) of the 3 to 10 GHz band, which can transmit large amounts of data much faster than Bluetooth, whether the entire band is used or only the 3 to 5 GHz band is used. The situation is under consideration.

As such, there is no technology to form a home network using the same protocol by integrating wired / wireless.

Universal Plug and Play (UPnP) devices cannot connect to any device without a control point (CP) assigned to them, which is not easy to implement in a low-performance processor (8-bit) embedded device.

The Simple Control Protocol (SCP) solves this problem using the concept of a property route, which connects the behavior or properties of another SCP device other than the existing SCP device, Enables to perform common tasks. It is also possible to map attributes between devices in a property root in one direction, enabling point-to-point transmission between devices and multiple broadcasts on one network. Information about which property roots are stored is set in the EEPROM, which requires a specific storage space for storing such information and provides a limited number of available routes.

The biggest difference between SCP devices and UPnP devices is the Event Source Property.

From the perspective of the UPnP middleware, all event information can be referenced from any device connected to the network, and the properties of the event information can be changed quickly and easily. That is, all UPnP devices detect the property of all events occurring in the UPnP network, and by changing the event property in one UPnP device, another event may be generated or other event property may be changed.

However, in the SCP device, the event information cannot simply refer to the property of the event information in the SCP device as the output of the processing result according to the operation of the device or the user's operation, and no action can be performed with the event property.

An object of the present invention is to support a low-performance processor embedded home appliance and a non-IP embedded device (Non-IP embedded device) connected by the logical network connection of SCP and UPnP having the above characteristics.

An object of the present invention is to provide a powerful middleware function of UPnP that can utilize the features and event information of the SCP that can interoperate the device by the property connection between the devices by utilizing the property root of the SCP and UPnP control point.

It is an object of the present invention that a bridge in the application area converts the description document of the SCP device into an XML document for UPnP network connection and connects it to the UPnP network as if each SCP device is a UPnP device.

An object of the present invention is to reduce economic waste by implementing a bridge in a home network gateway to which an existing UPnP network is connected without using a separate mechanical device.

An integrated home network system utilizing SCP according to the present invention includes an SCP network to which a plurality of SCP devices are connected; A UPnP network to which a plurality of UPnP devices are connected; And an SCP-to-UPnP bridge connecting the SCP network and the UPnP network, and the plurality of SCP devices can be controlled as one logical network without a separate mechanical bridge configuration.

An integrated home network system utilizing SCP according to the present invention comprises the steps of: discovering an SCP device of an SCP network with an application layer bridge; Converting information about the device and service description of the SCP device into an XML description document; The XML description document of the SCP device may include: connecting the SCP device to the UPnP network as a virtual UPnP device; The UPnP device searching for the SCP device that is the virtual UPnP; And interfacing the UPnP device with the SCP device as the virtual UPnP through a UPnP middleware.

The integrated home network system utilizing SCP according to the present invention can reduce the cost for system integration operation through SCP device design of various information appliances by SCP-to-UPnP bridge for conversion to UPnP device technical document. In addition, it is possible to reduce the cost of developing a bridge for a UPnP network of an IP non-embedded device.

The integrated home network system using SCP according to the present invention can reduce costs by providing a low-cost SCP device that can be used in the same device as the UPnP device, and also integrates wired and wireless in the home network field by securing flexibility of adding a bridge function. It can be applied, connected to various devices, and conveniently utilizes UPnP middleware.

An integrated home network system utilizing SCP according to the present invention includes an SCP network to which a plurality of SCP devices are connected; A UPnP network to which a plurality of UPnP devices are connected; And an SCP-to-UPnP bridge connecting the SCP network and the UPnP network, and the plurality of SCP devices can be controlled as one logical network without a separate mechanical bridge configuration.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

The present invention supports the SCP-based device design and the UPnP network to realize the ease of use, flexibility, and standards-based connectivity of the UPnP network in the low-performance processor-embedded home appliance and the IP non-embedded device designed for a special purpose. The goal is to build an integrated home network that implements the SCP-to-UPnP bridge in the application area, allowing all devices to be controlled by one logical network called the UPnP network.

SCPs are configured to provide light communication protocols to devices with small amounts of memory and low throughput, such as by using power lines. The network between the devices can be configured with a separate control network to connect to other devices to control other devices by a single power line communication such as a PLC. In this case, the SCP device may be directly applied to the UPnP network using the UPnP device as it is.

All SCP devices include nodeID, networkID, Device Serial Number (DSN), and Private Ownership Key (POK).

nodeID: The unique ID on the logical network of the SCP device.

networkID: The unique ID on the SCP device's physical network, indicating the connection of the device's secure logical network.

-DSN (Device Serial Number): 136-bit POK and 128-bit DSN are assigned when the SCP device is manufactured. DSN is similar to UDN (UPnP Device Name) in UPnP. Distinguish multiple SCP devices in a network.

Private Ownership Key (POK): It can extract settings related to the security of SCP devices and the physical connection between the device and user applications.

Initialization of the SCP device is performed through a special network node called the Address Space Arbiter (ASA). This node performs a similar function to a Dynamic Host Configuration Protocol (DHCP) server in an IP-based network. The SCP network searches this node to find the SCP device connected to the ASA, specifying the nodeID and networkID of the connected SCP device as the unique ID on the network. When the SCP device is disconnected from the ASA, the nodeID and networkID are returned so that other SCP devices connected to the ASA can use the returned ID. This is the same principle as UPnP's AUTO-IP.

1 is a block diagram showing the structure of an SCP device.

2 is a block diagram illustrating the structure of an exemplary SCP device in accordance with the present invention.

The SCP device consists of two key components: the communications subsystem and the application subsystem.

The communication subsystem of the SCP device is a low performance processor that provides a physical interface with the core SCP protocol and consists of a communication protocol controller. The communication subsystem maintains communication within the network and is directly connected with the PHY.

The connection of the SCP device requires the configuration and maintenance of the communication protocol controller of the physically used communication module, and can be connected to various protocols of all devices.

The application subsystem of the SCP device performs the functions of controlling various SCP devices and communicates with the communication subsystem by the Serial Peripheral Interface (SPI).

2 shows a system of an SCP device in accordance with the present invention.

The present invention implements an application subsystem that can control various applicable devices (door locks, air conditioners, electronic clocks, lighting devices, thermostats) with an 8-bit processor.

3 is a block diagram illustrating an SCP-to-UPnP bridge in accordance with the present invention.

An integrated home network system utilizing SCP according to the present invention comprises the steps of: discovering an SCP device of an SCP network with an application layer bridge; Converting information about the device and service description of the SCP device into an XML description document; The XML description document of the SCP device may include: connecting the SCP device to the UPnP network as a virtual UPnP device; The UPnP device searching for the SCP device that is the virtual UPnP; And interfacing the UPnP device with the SCP device as the virtual UPnP through a UPnP middleware.

Each network is connected through an application layer bridge called SCP-to-UPnP Bridge. The bridge discovers SCP devices on a physical SCP network and converts information about service descriptions of those SCP devices into XML technical documents, the UPnP device technical documentation standard. The XML technical document of the SCP device converted by the bridge connects the SCP device to the virtual UPnP device through the UPnP network. Through the bridge connection, the UPnP device searches for a virtual UPnP device generated corresponding to each SCP device, thereby allowing the SCP device to perform interaction using UPnP middleware. In contrast, SCP devices cannot discover or operate UPnP devices.

SCP-to-UPnP bridge according to the present invention is the core of the logical integrated network configuration to the UPnP network, the bridge in the application area reduces the resource waste due to the separate physical bridge configuration, UPnP each SCP device It can be recognized as a device, ultimately making use of UPnP middleware as an SCP device. This SCP-to-UPnP bridge is implemented in a home gateway that acts as a network connection and server. Property roots and ASAs are also implemented in the home gateway.

SCP supports various network connections depending on the design of the Communication Protocol Controller (CPC) in the device. CPC is a device for physical network connection of SCP devices, and in the present invention, in order to substantially increase the efficiency of network connection, a low-power, low-bandwidth PLC network is designed through CPC's PLC protocol connection design for a low-performance processor-based home appliance. Configure and connect various IP non-embedded devices.

4 is a diagram showing the configuration of the entire network according to the present invention.

The network configured as shown in FIG. 4 integrates a low-performance processor embedded home appliance and an IP non-embedded device into a UPnP network, and may confirm a connection or command an operation of the home appliance and a sensor device at a UPnP control point. In addition, it is easy to expand to various convergence services through connection between various devices and provides integrated management efficiency of devices.

The above description is merely illustrative of the technical details of the present invention, and those skilled in the art to which the present invention pertains may various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1 is a block diagram illustrating the structure of an exemplary SCP device in accordance with the present invention.

2 shows a system of an SCP device in accordance with the present invention.

3 is a block diagram illustrating an SCP-UPnP bridge in accordance with the present invention.

4 is a diagram showing the configuration of the entire network according to the present invention.

Claims (9)

SCP network to which multiple SCP devices are connected; A UPnP network to which a plurality of UPnP devices are connected; And Including the SCP-to-UPnP bridge connecting the SCP network and the UPnP network, it is possible to control the plurality of SCP devices as a single logical network without a separate mechanical bridge configuration, The SCP device An application subsystem with an application processor to control the SCP device; And Includes a communication subsystem, The application subsystem is in communication with the communication subsystem via a serial peripheral interface (SPI). Integrated home network system. delete The method of claim 1, The application subsystem To control household appliances and non-IP embedded devices with low performance processors. Integrated home network system. The method of claim 3, The low performance processor is characterized in that the 8-bit (bit) processor Integrated home network system. The method of claim 3, The communication subsystem A communication protocol controller; Technology and persistence data storage (EEPROM); And Includes a PLC modem, The PLC modem is characterized in that the PLC communication with the PHY Integrated home network system. The method of claim 3, The SCP device is characterized in that the device of the same model as the UPnP device Integrated home network system. The method of claim 3, The SCP device nodeID, networkID, Device Serial Number (DSN), and Private Ownership Key (POK) Integrated home network system. In an integrated home network system that includes an SCP network, a UPnP network, and an SCP-to-UPnP bridge, Searching for the SCP device of the SCP network with an application layer bridge; Converting information about the device and service description of the SCP device into an XML description document; The XML description document of the SCP device may include: connecting the SCP device to the UPnP network as a virtual UPnP device; The UPnP device searching for the SCP device that is the virtual UPnP; And Interfacing the UPnP device with the SCP device that is the virtual UPnP through a UPnP middleware. How to configure an integrated home network system. The method of claim 8, The steps to discover an SCP device are Searching for an SCP device connected to an address space arbiter (ASA); Designating the nodeID and the networkID of the connected SCP device as the unique ID of the SCP network; And returning the nodeID and the networkID when the ASA is disconnected from the SCP device. How to configure an integrated home network system.

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