JP3728447B2 - Data communication system - Google Patents

Description

  The present invention relates to a communication method for performing data transfer between two communication devices with established network connections.

  When performing data communication between two communication devices, data can be sent and received even if a network connection is established between the two communication devices, and the desired data type, data format, and data size Etc. cannot be handled by both communication devices, actual data communication cannot be performed or the communicated data becomes invalid. Conventionally, communication has been performed based on a communication method uniquely determined by a device manufacturer. Examples of communication methods include a method for determining whether or not a data transmission side device can transmit data, or a method for determining whether or not requested data can be transmitted, and a type of data that can be transmitted by the data transmission side device , A method for comparing the data type valid at the data receiving side device to determine the communication target device and the data type, the data type and number of data that can be transmitted by the data transmitting side device, and the data identification information There are methods for obtaining and communicating. Furthermore, some of these procedures are omitted or a method of executing a certain communication sequence by combining a plurality of methods is employed. For example, see Patent Document 1.

Japanese Patent Laid-Open No. 9-244942

  Therefore, when trying to perform data communication with various combinations of various data types, data formats, and data sizes, the amount of communication information between communication devices increases due to invalid data communication and communication form notification and confirmation. , Causing an increase in communication traffic and a decrease in data transfer speed due to the increase in traffic. In addition, by performing data transfer in a specific communication sequence, duplicate information must be exchanged each time, even during multiple data transfers between the same communication device, increasing the amount of communication information and data transfer There was a problem that the speed decreased.

  In this case, for example, in a communication environment where a large file must be divided and transmitted / received, settings such as the division procedure and the size of divided data are uniquely described by each application vendor. Communication is not possible.

  An object of the present invention is to efficiently notify and confirm communication forms and communication data with a small amount of information exchange, and to determine communication devices and valid data for data communication to reduce communication traffic when performing data communication. It is to improve the data communication speed.

  The data communication method of the present invention is useful when two or more communication devices connected to a network perform data communication with each other. The data communication method includes a data communication function table that holds a function related to data communication provided on a memory of the communication device, and a data communication control unit, and performs data communication control for writing to and reading from the data communication function table. The data communication between the communication devices is performed by the unit. This method has the effect of reducing network traffic because it is not necessary to transmit the same data. Since the data communication time is short, each communication device can obtain the same effect as the improvement of the data communication speed.

  The data communication function table may include a code indicating the type of data that can be transmitted or the type of data that can be received. Network traffic can be reduced by eliminating requests for untransmittable data, unreceivable or invalid data transmission.

  In addition, the data communication function table may include an item indicating the presence or absence of the spontaneous communication function or request response communication. Network traffic can be reduced by performing data communication only with a communication device that can acquire spontaneous communication data, or by requesting communication only with a communication device that can respond to a request response communication request.

  The data communication function table may include an item representing the division size of data that is most efficient for data communication. Data communication with the most efficient communication speed can be performed with respect to a network constituted by an arbitrary communication medium.

  A communication device includes a data communication function table that holds functions related to data communication on a memory, and a data communication control unit that performs mutual data communication of the communication devices by writing to and reading from the data communication function table I have. The data communication function table has at least one of a spontaneous transmission data type, a spontaneous reception data type, a response transmission data type, and a request reception data type. The data communication function table holds at least one of transmission data information, data transfer status, number of data for each type, number of data divisions, and transfer data. On the other hand, the data communication function table of the communication partner includes a spontaneous transmission data type, a spontaneous reception data type, a response transmission data type, a request reception data type, a transmission data information, a data transfer state, a data number for each type, a data division number, and transfer data. At least one piece of information. The transmitting side and the receiving side may share the information with each other. This has the effect of reducing network traffic because it is not necessary to transmit the same data. Since the data communication time is short, each communication device can obtain the same effect as the improvement of the data communication speed.

  A communication device includes a data communication function table that holds functions related to data communication on a memory, and a data communication control unit that performs mutual data communication of the communication devices by writing to and reading from the data communication function table I have. The data communication function table holds at least one of a spontaneous transmission data type, a spontaneous reception data type, a response transmission data type, and a request reception data type. On the other hand, the data communication function table of the communication partner has at least one information among a spontaneous transmission data type, a spontaneous reception data type, a response transmission data type, and a request reception data type. The transmitting side and the receiving side may share the information with each other. This has the effect of reducing network traffic because it is not necessary to transmit the same data. Since the data communication time is short, each communication device can obtain the same effect as the improvement of the data communication speed.

  According to the present invention, there is provided a recording medium for a data communication method in which a program for causing a computer to function the above data communication method is recorded. Such a program may be recorded on a recording medium.

  Further, according to the present invention, the above-described data communication method is also provided as a program for causing a computer to function.

  A communication device includes a data communication function table that holds functions related to data communication on a memory, and a data communication control unit that performs mutual data communication of the communication devices by writing to and reading from the data communication function table I have. The data communication function table has at least one of a spontaneous transmission data type, a spontaneous reception data type, a response transmission data type, and a request reception data type. The data communication function table holds at least one of transmission data information, data transfer status, number of data for each type, number of data divisions, and transfer data. The data communication function table of the communication partner includes: spontaneous transmission data type, spontaneous reception data type, response transmission data type, request reception data type, transmission data information, data transfer status, number of data per type, number of data divisions, transfer data At least one piece of information. The transmitting side and the receiving side may share the information with each other.

  A communication device includes a data communication function table that holds functions related to data communication on a memory, and a data communication control unit that performs mutual data communication of the communication devices by writing to and reading from the data communication function table I have. The data communication function table holds at least one of a spontaneous transmission data type, a spontaneous reception data type, a response transmission data type, and a request reception data type. The data communication function table of the communication partner has at least one information of a spontaneous transmission data type, a spontaneous reception data type, a response transmission data type, and a request reception data type. The transmitting side and the receiving side may share the information with each other.

  As described above, according to the data communication method of the present invention, it is possible to determine a communication device capable of performing data communication by spontaneous communication or request / response communication by sharing a function table related to communication, and a transmission data type. Determination, the number of data, acquisition of each data identification information, and data communication can be performed by dividing the data into optimum sizes, and in data communication, communication traffic can be reduced and communication speed can be increased. Become.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Prior to describing each embodiment, the concept of the present invention will be described.

  FIG. 50 is a diagram showing a configuration of a communication system 100 that transmits and receives data based on the communication method according to the present invention. The communication system 100 includes two communication devices 1 and 2 and a network 3 that connects them.

  An example of the communication system 100 assumed in the present specification is a home LAN in which home appliances are connected to each other in a communicable state. The communication devices 1 and 2 are basically household electrical appliances having the same communication function and configuration, such as an air conditioner (air conditioner), a refrigerator, a microwave oven, and an outdoor camera. The network 3 is a power line that supplies power to the home appliance. Since the network 3 is a power line, it is assumed that it is a communication medium with a relatively low communication speed of, for example, a maximum of 9600 bps. As the network 3, a wireless network that performs communication at a lower communication speed (for example, a maximum of 2400 bps) can be adopted instead of the home LAN. In any case, no new wiring is required. The network 3 may be a general communication network.

  In the following description, it is assumed that the communication device 1 transmits a data file to the communication device 2 and the communication device 2 processes the data file. For example, assume that the communication device 1 is an outdoor camera for visitors, the communication device 2 is a control device (controller) having a monitor, and an image data file taken by the outdoor camera is displayed on the monitor of the controller via the network 3. It is assumed that the data file includes simple data without a name added as a file.

  The configuration of the communication device 1 is as follows. That is, the communication device 1 includes application software 101, service middleware 102, service API (Application Program Interface) 103, basic APIs 104-1 and 104-2, a communication processing unit (communication middleware) 105, and a service object 107. , Lower communication software 108 and common lower communication interface 109 are provided. As is clear from the description “software”, the configuration of the communication device 1 illustrated in FIG. 50 is a conceptual model of a layer related to the communication function of the communication device 1. A block diagram based on the physical configuration is as described in FIG.

  One of the main features of the present invention is that the service middleware 102 and the service object 107 are provided in both of the communication devices 1 and 2 of the communication system 100 to unify the processing procedure for communication. Since the necessary functions are different between the communication device 1 on the data file transmission side and the communication device 2 on the data file reception side, the specific contents of the service middleware 102 and the service object 107 are different. However, as will be described below, information required for data file exchange is specified in advance and communicated in a predetermined procedure, enabling efficient communication mode and communication data notification / confirmation. It is possible to determine the device and valid data that are subject to data communication. As a result, sufficient practicality is secured in the network 3 having a relatively low transmission rate.

  The application software 101 is software that executes main processing of the communication device 1. For example, the communication device 1 is software that performs shooting, encoding, and the like using an outdoor camera. The communication device 2 corresponds to software that performs display processing by decoding received images. The application software 101 may exist alone or may be a set of a plurality of software that performs specific processing.

  The service middleware 102 is a program that defines common and basic processing of the application software 101. More specifically, the service middleware 102 performs processing (transmission sequence management of data files, assembly (restoration) processing of divided and received data files) for transmitting and receiving relatively large data files. The service middleware 102 is positioned as a part of specific application software. Therefore, the service middleware 102 uses the basic API 104-2 when using the function of the communication middleware 105 in internal processing. Therefore, from the viewpoint of the communication middleware 105, the service middleware 102 is treated as one of the application software 101. By defining the common processing function by the service middleware 102, the development burden of application software can be reduced, and the software vendor can concentrate on system and device development with more essential functions and performance. It is possible to provide system-related products useful for users. The service middleware 102 will be described in detail later.

  The service API 103 is an API for accessing the service middleware 102 from the application software 101. The service API 103 is provided by the service middleware 102. By using the service API 103, the application software 101 can pass a request to the service middleware 102, and the application software 101 can receive a processing result from the service middleware 102.

  In general, the API refers to an interface for calling each function prepared by the OS from an application. In general, APIs are widely open, so applications can be efficiently developed by using APIs.

  Next, the basic APIs 104-1 and 104-2 are interfaces used when the application software exchanges data files with the communication middleware 105. As described above, since the service middleware 102 is a part of application software as viewed from the communication middleware 105, the basic API is shared. However, for the sake of easy understanding, it is clearly indicated that the basic API 104-1 is used for the application software 101 and the basic API 104-2 is used for the service middleware 102 for convenience.

  The communication middleware 105 uses the device object 106 and the service object 107 to perform communication processing related to data file transmission / reception. Specifically, frame processing such as analysis of a message received via the network 3, processing according to the properties of the service object 107, writing to the service object 107, and reading processing. The data file includes both a file received from the application software 101 and / or the service middleware 102 and a file received from the network 3.

  The device object 106 provided in the communication middleware 105 will be described. The device object 106 is an object that defines various information related to the device. The device object 106 of the communication device 1 includes a class, instance, property, property value, and the like in the network. The information defined by these includes, for example, an ID number for identifying the camera, a flag indicating the operating state of the external camera, a shutter speed, shutter settings such as a shutter aperture, a storage position of an acquired image, and the like. You can specify and search the memory area of the device object by class and instance.

  The service object 107 is the function and setting information of the service middleware 102 disclosed to the network, and more specifically, is a class specification object model that defines functions, services, and properties. The purpose of defining the service object 107 is to enable the system to be efficiently constructed by accessing the service middleware 102 from the network 3. The service object 107 includes a code representing the type of data file that can be transmitted / received, an item representing a spontaneous communication function, or a request response communication function. Specific examples of the configuration of the service object 107 are as shown in the “function table” described in FIGS. 2 to 8 and FIGS. These details will be described in each embodiment.

  The lower-layer communication software 108 performs processing for enabling access to the network 3. Specifically, the lower-layer communication software 108 absorbs differences in protocols of different communication media, and exchanges data with the common-defined common lower-layer communication interface 109. The common lower-layer communication interface 109 mediates the data file. Conversely, when a data file to be transmitted to the network 3 is received from the communication middleware 105, the lower-layer communication software 108 receives the data file via the common lower-layer communication interface 109, and sends the data file to the network 3 using a predetermined protocol. To do.

  The configuration related to the communication function of the communication device 1 has been described above. Note that the basic configuration of the communication device 2 is substantially the same as that of the communication device 1. However, since the communication device 2 functions as a controller, it is necessary to communicate with devices other than the communication device 1. Therefore, one service object 117 of the communication device 2 may be provided for each device to be communicated.

  Here, the service middleware 102 which is the main feature of the present invention will be described in more detail. The service middleware 102 supports file transfer when data files are transmitted and received over the network 3 having a relatively small transmission capacity. This file transfer process is called a file transfer service.

  Data file transfer sequences managed by the service middleware 102 can be roughly classified into two types. The first is a series of communication sequences when the communication device 1 spontaneously transmits a data file. This form of communication is referred to as “spontaneous communication” or “PUSH type data communication”. Specifically, this is a communication sequence in a case where a shooting data file is spontaneously transmitted from the camera (communication device 1) to the controller (communication device 2). The second is a series of sequences when the communication device 2 requests the communication device 1 to transfer a data file and the communication device 1 transmits the data file in response to the request. This type of communication is referred to as “request response communication” or “PULL type data communication”. Specifically, when the user wants to see an image of the camera (communication device 1), the controller (communication device 2) requests the camera (communication device 1) for a shooting data file and receives the request. This is a communication sequence when the (communication device 1) performs shooting and transmits a shooting data file to the controller. Both communication sequences will be described in detail in later embodiments.

  The division of the data file performed by the service middleware 102 is determined based on the transmission capacity of the network 3 and the data size that can be handled at one time by the communication device 2 as the transmission destination. The service middleware 102 of the camera (communication device 1) may recognize the current transmission capacity of the network 3 based on information from the lower-layer communication software 108 when the power is turned on. When the destination communication device 2 is specified, the service object 117 of the communication device 2 is referred to, and the data size that can be handled by the communication device 2 at a time is acquired. When the data file to be transmitted is larger than the size, the data file is divided and transmitted so as to have a size equal to or smaller than the transmission capacity.

  Now, it is assumed that the maximum data length that can be transmitted and received at once in the network 3 is 131 bytes. For example, when the data size of image data captured by the camera is 5 kbytes (about 5000 bytes), the service middleware 102 of the camera considers the data size that the controller (communication device 2) can handle at one time by communication. Then, the image data is divided every 131 bytes and transmitted to the controller (communication device 2). In relation to the division, the service middleware 102 sets information (data division information) regarding data to be transmitted in the service object 107. The data division information is a data size that the camera on the data transmission side can handle at one time by communication. Furthermore, the service object 107 may include an ID for specifying each divided image data, an order, a number, and the like.

  The controller (communication device 2) on the receiving side receives the divided individual image data. Then, the service middleware 112 of the communication device 2 refers to the service object 107 of the camera (communication device 1) and confirms whether the received data is all divided data. If not, the camera (communication device 1) is requested to retransmit the missing data. When all the divided data are collected, the service middleware 112 assembles the divided data based on the data division information set in the service object 107 of the camera (communication device 1), and the original image data Get the file. The service middleware 112 provides an image data file via the service API 113 in response to a request from the application software 111.

  Next, the service objects 107 and 117 will be described in more detail in relation to the data transfer service described above. In relation to the transfer of the data file, the communication device 1 on the transmission side is equipped with a service object 107 (file transmission service object 107) related to file transmission. The communication device 2 on the receiving side is equipped with a service object 117 (file reception service object 117) related to file reception. Any file transmission / reception service object implements essential properties according to the file transfer method (PUSH type, PULL type). The “property” individually represents the attributes and functions of the service itself such as the operation status, transmission status, and transmission content of the file transfer service.

  The file transmission service object 107 is an object that discloses transmission settings, transmission states, transmission contents, and the like. Specific contents are described in FIG. 21, FIG. 22, FIG. 35, and FIG. On the other hand, the file reception service object 117 is an object disclosed as a window for receiving a data file. Specific contents are described in FIGS. 20 and 34. The PUSH transmission / reception handling object information indicates the type of data that can be transmitted / received by PUSH, and the PULL transmission / reception handling object information indicates the type of data that can be transmitted / received by PULL. .

(Embodiment 1)
FIG. 1 is a diagram showing a configuration of a communication system 100 that transmits and receives data based on a communication method according to the present invention. Similar to FIG. 50, the communication system 100 includes a communication device 1 and a communication device 2 connected via the network 3.

  The communication device 1 includes a central processing unit (CPU) (10), a memory 11, a data communication control unit 12, a memory management unit 13, and a network control unit 14. The CPU 10 comprehensively controls the operation of the communication device 1. Under the control of the CPU 10, the other components (the memory 11, the data communication control unit 12, the memory management unit 13, and the network control unit 14) operate at appropriate timing and perform appropriate processing. The memory 11 has a data communication function table 15. The data communication function table 15 holds information defining the data communication function and information related to the communication processing procedure. The memory 11 stores software executed in the communication device 1. That is, the application software 101 and the service middleware 102. Further, the memory also stores middleware (not shown) for operating the communication middleware 105. The data communication control unit 12 includes a table sharing control unit 16 and performs control related to a table sharing process described later. The memory management unit 13 includes a table value reading unit 17, a table value writing unit 18, and a table common processing unit 19, and performs common processing with other communication devices 2 on the contents of the data communication function table 15. The network control unit 14 performs communication processing with other communication devices.

  On the other hand, the communication device 2 may have the same configuration as the communication device 1. The communication device 2 includes a CPU 20, a memory 21, a data communication control unit 22, a memory management unit 23, and a network control unit 24. The memory 21 stores a data communication function table 25, application software 111, and service middleware 112. Each component of the communication device 2 is given a reference numeral different from that of the component of the communication device 1, but the component having the same name has the same configuration and function. Therefore, individual description of each component of the communication device 2 is omitted.

  Next, with reference to FIG. 50 again, it will be described which component of FIG. 1 corresponds to the model structure of the communication device 1 shown in FIG.

  First, the application software 101 and the service middleware 102 are stored in the memory 11 (FIG. 1) as shown in FIG. The service middleware 102 is read from the memory 11 (FIG. 1) and executed by the CPU 10 (FIG. 1). The CPU 10 performs processing by appropriately accessing the device object 106 and the service object 107 stored in the memory 11 (FIG. 1) based on the instruction of the service middleware 102. The application software 101 is also read from the memory 11 (FIG. 1) and executed by the CPU 10 (FIG. 1). In the processing, the CPU 10 uses the processing result of the service middleware 102 using the service API 103 or sends a request to the service middleware 102 based on an instruction of the application software 101.

  The device object 106 and the service object 107 correspond to the data communication function table 15 (FIG. 1). Both are stored in table format.

  The communication middleware 105 is stored in the memory 11 (FIG. 1). The CPU 10 appropriately accesses the data communication function table 15 (FIG. 1) of the memory 11 based on middleware (not shown) for managing communication of the communication device 1 and the memory management. The unit 13 (FIG. 1) is operated.

  The lower communication software 108 and the common lower communication interface 109 correspond to the network control unit 14 (FIG. 1). The network control unit 14 (FIG. 1) is realized as a communication module such as an interface card or a board provided with a serial interface (for example, RS-232C). The lower-layer communication software 108 is stored in a memory (for example, EEPROM) provided in such a communication module, and is executed by a separate CPU provided in the same manner, to realize communication according to a predetermined protocol.

  As for the communication device 2, the correspondence between FIG. 1 and FIG. 50 is basically the same as that of the communication device 1. Therefore, the device object and service object of the communication device 2 correspond to the data communication function table 25 (FIG. 1). However, the data communication function table 15 of the communication device 1 and the data communication function table 25 of the communication device 2 are different in the device object and the service object that should be provided. When the communication device 1 is a data transmission side node and the communication device 2 is a data transmission side node, the service object 107 (FIG. 50) of the communication device 1 includes a file transmission service object. 117 (FIG. 50) needs to include a file reception service object.

  Hereinafter, the data communication operation of the present embodiment will be described. First, a case where transfer data is spontaneously transmitted from the terminal device to the controller will be described. The communication device 1 connected to the network is an air conditioner having a spontaneous transmission function, and the communication device 2 is a controller that centrally controls a reception function for spontaneous transmission, that is, an air conditioner having a spontaneous reception function. Communication by spontaneous transmission and spontaneous reception will be referred to as spontaneous communication.

  First, in response to a command from the data communication control unit 12 of the air conditioner 1, it is confirmed whether the partner communication device is a device having a data communication function table at the time of establishing a network connection or performing data communication. . This confirmation can be made by determining a communication message for that purpose in advance, inquiring the other communication device, and obtaining a reply. In addition, it is confirmed whether the device has a data communication function table, and at the same time, the presence of each information stored in the data communication function table is inquired and a reply is obtained to confirm whether the device has a spontaneous reception function. May be performed. This confirmation may be performed by the controller 2 with each connected device before data communication or periodically. Further, the controller 2 may confirm whether the device has a spontaneous transmission function by inquiring the partner communication device about the existence of information stored in the data communication function table.

  FIG. 2 is a diagram illustrating a state before data communication of the data communication function table 15 of the air conditioner 1 and the data communication function table of the controller 2. FIG. 3 is a diagram illustrating an example of transmission data information. FIG. 4 is a diagram illustrating a state immediately before the end of data communication in the data communication function tables 15 and 25 of the air conditioner 1 and the controller 2.

  The following information is stored in the data communication function table 201 in the initial state of the air conditioner 1 shown in FIG. The spontaneous transmission data type 211 indicates a state in which the air conditioner 1 can spontaneously transmit two types of “CSV” format which means table format data and “TXT” format which means text format data. The value is meaningful. The spontaneous reception side data type 214 means a data type that can be handled by the other party receiving the spontaneous transmission, but is not set because the state of the other party is unknown. The transmission data information 212 is shown in FIG. 3 in the data format when the air conditioner 1 spontaneously transmits data, for example, the data type, data name, data creation date, and data size. In the initial state, no value is set. The data transfer state 213 indicates whether transmission is in progress, and is initially “not transmitted”. The data division information 215 is a data division size that can be handled by the spontaneous reception destination, and is not set because it is unknown at the beginning. The transfer data 216 is the data to be transferred, and is not set initially.

  The data communication function table 202 in the initial state of the controller 2 stores the following information. The spontaneous reception side data type 224 means a data type that can be handled by the controller 2 that receives the spontaneous transmission, and indicates that “TXT” can be handled. The transmission data information 222 is information in the format shown in FIG. 3 in the format of data when the air conditioner 1 of the spontaneous transmission source spontaneously transmits, for example, the data type, data name, data creation date, and data size. In the initial state, since it is not known what type of message will come, it is not set. The data transfer state 223 indicates whether transmission is in progress, and is initially “not transmitted”. The data division information 225 is a data division size that can be handled by the spontaneous reception destination, that is, the controller 2 itself, and is 1024. The transfer data 226 is data to be received and is not yet set because it is before transmission.

  Next, the air conditioner 1 checks whether or not the controller 2 is a communication device that can be a spontaneous transmission destination as follows. The table sharing control unit 16 of the air conditioner 1 sends a command for sharing the data of the spontaneous reception side data type 214 to the table sharing processing unit 19. Upon receiving the instruction, the table sharing processing unit 19 instructs the network control unit 14 to confirm that the telegram for sharing the data type of the spontaneous reception side has a data communication function table in advance. It is sent to the controller 2 which has already been used, in this example.

  The controller 2 that has received the message sends the received information from the network control unit 24 to the table sharing processing unit 29, and the table sharing processing unit 29 uses the table value reading unit 27 to read the data communication function table 25, that is, the data in FIG. The value “TXT” of the spontaneous reception side data type 224 in the communication function table 202 is read and returned to the table common processing unit 29. The table sharing processing unit 29 instructs the network control unit 24 to send and return the read value to the device that sent the message. Upon receiving this value, the air conditioner 1 sends this information from the network control unit 14 to the table sharing processing unit 19, and the table sharing processing unit 19 instructs the table value writing unit 18 to transfer the acquired value to the data communication function. Write to table 15. In this way, the value “TXT” is written in the spontaneous reception side data type of the data communication function table 15 of the air conditioner 1 as shown by 414 in FIG. 4, and one item of the data communication function table is shared. Is done.

  Next, the table sharing processing unit 19 of the air conditioner 1 notifies the data communication control unit 12 that the spontaneous reception side data type 214 is shared with the spontaneous reception side data type 224 of the spontaneous reception destination, and the data communication The control unit 12 compares the written value “TXT” of the spontaneous reception side data type 214 with the values “CSV” and “TXT” of the spontaneous transmission data type 211, and since there is a matching data type, transmission is possible. to decide. If there is no data of the matching type, it is determined that the other party cannot perform spontaneous transmission. Further, if the value indicating “all” is included in the spontaneous reception side data type 224 of the data communication function table 25 of the controller 2, all data included in the spontaneous transmission data type 211 on the air conditioner 1 side can be transmitted. To be judged.

  Next, the data communication control unit 12 of the air conditioner 1 sends a command to the table value writing unit 17 in order to perform spontaneous transmission of data, thereby setting the value of the data transfer state 213 in the data communication function table 15 to 413 in FIG. As shown in FIG. 3, the data shown in FIG. 3 is the latest information as the transmission data information 212 of the data communication function table 15 by issuing a command to the table value writing unit 17 after being set to the “transferring” state. Type 301, data name 302, date information 303, and data byte number 304 are set. This transmission data information 212 is used to notify the spontaneous reception destination of the format of the transfer data to be transferred this time. At the same time, the latest data is set as the transfer data 216 which is the main body of the transfer data. This state is shown at 412 and 416 in FIG.

  Next, the data communication control unit 12 uses the table sharing control unit 16 to share transmission data information. That is, the table sharing processing unit 19 causes the table value reading unit 17 to read the set transmission data information 412, passes it to the network control unit 14, and transmits it to the controller 2. The table sharing processing unit 29 on the controller 2 side that has received the transmission data information 412 causes the transmission data information 412 to be written to the transmission data information 422 in the data communication function table 25 via the table value writing unit 28.

  Then, the data communication control unit 22 is notified that transmission data information has been shared, and is the data communication control unit 22 receivable data from the data type and data size notified by the transmission data information? If the data is receivable, the table value writing unit 28 sets the data transfer state 423 of the data communication function table 25 to “in transfer”. Thereafter, the table sharing control unit 26 of the data communication control unit 22 instructs the table sharing processing unit 29 to read the value “1024” of the data division information 425 of the data communication function table 25, and the network control unit The air conditioner 1 is notified from 24.

  The air conditioner 1 stores the received value “1024” of the data division information 425 in the data communication function table 15 of the air conditioner 1 as the data division information 415 and shares it with the controller 2. This completes preparation for transfer of transfer data. Therefore, the data communication control unit 12 instructs the table sharing control unit 16 to share the value of the transfer data 416 in the data communication function table 15. That is, the data division of the transfer data 416 is created in units of 1024 bytes, and the data is spontaneously transmitted from the air conditioner 1 to the controller 2. As a result, the transfer data is written as 426 in the transfer data 226 of the data communication function table 25 on the controller 2 side, and the data is transferred from the air conditioner to the controller.

  Finally, when the data communication control units 12 and 22 of the air conditioner 1 and the controller 2 determine that the sharing of the transfer data is completed, the data transfer states 413 and 423 are in the standby state, not transmitted, or not set. To 213 and 223. For items other than the data transfer state, a common value is held. Accordingly, data communication for sharing the same information becomes unnecessary after this.

  When transmitting the spontaneous reception side data type 224, the data division information 225 may be transmitted simultaneously or continuously.

(Embodiment 2)
Next, an example of request response communication for requesting transfer data from the controller to the terminal device will be described. As an example, data communication between a lighting device and a controller that centrally controls the lighting device will be described. The configuration can be represented by the same diagram as FIG. In this embodiment, in FIG. 1, the communication device 1 is a lighting device 1, and the communication device 2 is a controller 2. This is a case where the controller 2 requests data transfer to the lighting device 1, the lighting device 1 transmits a response, and the controller 2 receives the request. Such data communication is referred to as request response communication.

  FIG. 5 is a diagram illustrating a state before data communication of the data communication function tables 15 and 25 of the lighting device 1 and the controller 2, and FIG. 6 is a diagram immediately before the end of data communication of the data communication function tables 15 and 25 of the lighting device 1 and the controller 2. It is a figure which shows the state of.

  The data communication function table 15 of the lighting device 1 stores the following information as an initial state as indicated by reference numeral 501 in FIG. The response transmission data type 511 is a value that means a state in which the lighting device 1 can transmit data in “CSV” format that means table format data. The transmission data information 512 is shown in FIG. 3 in the format of data when the lighting device 1 transmits data as a response, for example, the data type, data name, data creation date, and data size. In the initial state, it is not set. The data transfer state 513 indicates whether transmission is in progress, and is initially “not transmitted”. The data division information 515 is a data division size that can be handled by the request receiving destination, and is not set because it is unknown at the beginning. The transfer data 516 is the data itself to be transferred, and is not set initially. The number-of-types data number 517 is information indicating the number of files and the like to be transmitted for each data format such as “CSV”, “TXT”. In this embodiment, initially, “CSV” shown in 511 is set to one.

  The data communication function table 25 of the controller 2 stores the following information as an initial state as indicated by 502 in FIG. The response transmission data type 521 is not set because the response transmission source indicates the type of data to be transmitted by response, and is not known at the beginning. The transmission data information 522 is the data format when the response transmission source lighting device 1 transmits the data in response, for example, the data type, the data name, the data creation date, and the data size, as shown in FIG. However, since it is not yet known in the initial state, it is not set. The data transfer state 523 indicates whether transmission is in progress, and is initially “not transmitted”. The data division information 525 is a data division size that can be handled by the controller 2 itself, which is a request receiving destination, and is set to 1024. The transfer data 526 is the data itself that is received by the request, and is not set initially. The number-of-types data number 527 is information indicating how many files or the like data is transmitted for each data format such as “CSV”, “TXT”, etc., and is not set initially. The request receiving side data type 524 is a data type that can be handled by the controller 2 and can receive two types of requests, “CSV” and “TXT”.

  Hereinafter, the data communication operation of the present embodiment will be described. First, according to a command from the data communication control unit 12 of the controller 2, it is confirmed whether the partner communication device is a device having a data communication function table at the time of establishing a network connection or performing data communication. . This confirmation can be made by determining a communication message for that purpose in advance, inquiring the other communication device, and obtaining a reply. In addition, it is confirmed whether the device has a data communication function table, and at the same time, the presence of each information stored in the data communication function table is inquired and a reply is obtained to confirm whether the device has a response transmission function. May be performed. Note that this confirmation may be performed before or regularly with data communication between the lighting device 1 and each connected device. Further, the lighting device 1 may confirm whether the device has a request reception function by inquiring of the other communication device about the existence of information stored in the data communication function table.

  Next, the controller 2 having a transmission request function confirms whether the communication device can be a transmission request destination at the time of establishing a network connection or performing data communication according to a command from the data communication control unit 22 as follows. Do as follows. The controller 2 uses the table sharing control unit 26 of the data communication control unit 22 to set “CSV” which is the value of the response transmission data type 511 of the table 501 shown in FIG. 5 in the data communication function table 15 of the lighting device 1. The data is taken into the response transmission data type 521 of the function table 25 of the controller 2. For this purpose, the table sharing processing unit 29 causes the network control unit 24 to create a message requesting response transmission type data, and transmits it to the lighting device 1.

  The lighting device 1 analyzes the received message in the network control unit 14 and passes the request content to the table sharing processing unit 19. The table sharing processing unit 19 sends the response transmission data via the table value reading unit 17. The value “CSV” of the type 511 is extracted, stored in a reply message, and sent from the network control unit 14 to the controller 2, that is, a request is sent. The controller 2 extracts the value “CSV” of the response transmission data type 511 from the received request message, and writes it in the data communication function table 25 as the response transmission data type 621 of FIG. Next, the data communication control unit 26 of the controller 2 compares the written response transmission data type “CSV” with the request receiving side data type 524 “CSV” and “TXT”. Since there is a matching type of data, it is determined that a request for response transmission can be received. At this time, if there is no matching type of data, it is determined that the request cannot be received.

  Next, the data communication control unit 26 of the controller 2 requests the sharing of the number of data 517 for each type in order to obtain information on the data that can be requested, so that the data for each type 527 The value 1 of the equation 517 is set as the data number 527 for each type. This sharing can also be performed by exchanging messages in a procedure similar to the sharing of response transmission data types 511 and 521 to 611 and 621. In this case, since the number of data is one, the number of data that can be requested is one.

  Next, in order to request data, the data communication control unit 26 of the controller 2 sets the value of the data transfer state 523 in the data communication function table 25 to “in transfer” as indicated by 623 in FIG. Thereafter, the value of the data transfer state 613 of the lighting device 1 is set to “in transfer” using the table sharing control unit 26. This sharing can also be performed by a procedure similar to the above. As a result, the data communication function table 15 of the lighting device 1 has information necessary for setting the latest data information 616 and 612 as the transfer data 516 and the transmission data information 512.

  Thereafter, data is transferred from the lighting device 1 to the controller 2 by the same control procedure as in the first embodiment.

  Finally, when the respective data communication control units 12 and 22 of the lighting device 1 and the controller 2 determine that the sharing of the transfer data 616 and 626 is completed, the data transfer states 613 and 623 are set to “complete”. For items other than the data transfer states 613 and 626, a common value is held. Therefore, data communication for sharing the same information becomes unnecessary thereafter.

(Embodiment 3)
Next, a case of request response communication requesting transmission of transfer data from the terminal device to the controller will be described. In FIG. 1, a communication device 1 is a controller 1 that centrally controls a terminal device group, and a communication device 2 is a microwave oven 2.

  7 is a diagram showing a state before data communication between the data communication function tables 15 and 25 of the controller 1 and the microwave oven 2, and FIG. 8 is a state immediately before the end of data communication between the data communication function tables 15 and 25 of the controller 1 and the microwave oven 2. It is a figure which shows a state.

  The data communication function table 15 of the controller 1 stores the following information as an initial state as indicated by reference numeral 701 in FIG. The response transmission data type 711 indicates that the controller 1 is in a state where it can transmit “HTM” meaning hypertext markup language format data and “TXT” format data meaning text format data. means. The transmission data information 712 is the data format when the controller 1 transmits data as a response, such as the data type, data name, data creation date, and data size, as shown in FIG. Transmission data information in the format of FIG. 3 is stored for each possible data type, “HTM”, “TXT”. The data transfer state 713 indicates whether transmission is in progress, and is initially “not transmitted”. The data division information 715 is a data division size that can be handled by the request receiving destination, and is not set because it is unknown at the beginning. The transfer data 716 is the data itself to be transferred, and is not set initially. The number-of-types data number 717 is information indicating how many pieces of data are transmitted in units of files or the like for each data format such as “HTM” and “TXT”. In this embodiment, initially, “ The number is set to 10 in the “HTM” format and 5 in the “TXT” format.

  The data communication function table 25 of the microwave oven 2 stores the following information as an initial state as indicated by 702 in FIG. The response transmission data type 721 indicates the type of data that can be transmitted by the response transmission source, and is not set since it is not initially known. The transmission data information 722 is the data format used when the controller 1 transmits data as a response, for example, the data type, data name, data creation date, and data size, as shown in FIG. In the state, it is not set yet. The data transfer state 723 indicates whether transmission is in progress, and is initially “not transmitted”. The data division information 725 is a data division size that can be handled by the microwave oven 2 that is a request receiving destination, and is set to 1024. The transfer data 726 is a place for storing data to be requested and received, and is initially empty, that is, not set. The number-of-types data number 727 is information indicating how many data units of data are transmitted for each data format such as “HTM”, “TXT”, etc., and is not set initially. The request receiving side data type 724 is a data type that can be handled by the microwave oven 2 and can receive one type of “HTM”.

  Hereinafter, the data communication operation of the present embodiment will be described. First, the microwave oven 2 having a transmission request function confirms whether it is a communication device that can be a transmission request destination at the time of establishing a network connection or performing data communication as follows. That is, the microwave oven 2 acquires the values “HTM” and “TXT” of the response transmission data type 711 from the data communication function table 15 of the controller 1 using the table common processing unit 29 and stores them in 821. Compared with the value “HTM” of the reception-side data type 724, it is determined that data reception from the controller 1 when the data type is “HTM” is possible.

  Next, the microwave oven 2 acquires the values 10 and 5 of the number of types of data 717 from the data communication function table 15 of the controller 1 using the table sharing processing unit 29 and stores them in 827. In order to select data to be acquired from the target data, the microwave oven 2 performs table sharing with the transmission data information 712 in the data communication function table of the controller 1 using the table sharing processing unit 29. . At this time, the controller 1 holds the transmission data information of all the data to be transmitted, as indicated by 712, so the microwave oven 2 acquires the transmission data information 712 of all the target data and transmits the transmission data information 822. Can be stored in the data communication function table 25. Requested data can be selected from a plurality of types of transmission data information. However, in this embodiment, since only one type of “HTM” can be received, the “HTM” type can only be selected.

  Next, the data communication control unit 22 of the microwave oven 2 performs the data transfer state of the data communication function table 25 in order to make the third data request of the “HTM” data among the data types acquired by the transmission data information 822. 723 is set to “No. 3 transfer” as indicated by 823 in FIG. 8, and then the value of the data transfer state 713 of the controller 1 is set as indicated by 813 in FIG. 8 using the table sharing control unit 26. To “No. 3 transfer”. Thereby, the data communication control unit 12 of the controller 1 can set the latest data information in the transfer data 716 and the transmission data information 712.

  Thereafter, designated data is transferred from the controller to the microwave oven under the same control as in the first embodiment.

  Further, when the data in the controller is variable, that is, when the number of data for each type, the transmission data information of each data, and the value of transfer data are variable, when the data transfer state is “during transfer”, the write is disabled. In addition, it is possible to set the data transfer state to a “writable” state separately from “during transfer”. In this state, the number of data for each type, each transmission data information, and each value of each data information are unchanged. It becomes possible.

  Finally, when the data communication control units 12 and 22 of the controller 1 and the microwave oven 2 determine that the sharing of the transfer data has been completed, the data transfer state is set to “complete”, and other than the data transfer state A common value is stored for the item. Therefore, data communication for sharing the same information becomes unnecessary thereafter.

  In the above three embodiments, a configuration of a device for sharing information in each data communication function table of a start side (trigger side) communication device that needs to transmit data and its counterpart communication device, The operation and processing procedure of the equipment were explained. In the first embodiment, the spontaneous transmission side of the spontaneous communication matches the data type of the spontaneous reception side. In the second and third embodiments, the request reception side of request response communication is matched with the data type of the response transmission side.

  If there is no data type common to both, data transfer cannot be performed, so that one or both of the communication devices may display that data transfer is impossible.

  Alternatively, another communication device having a function of converting the data type may be connected to the network and provided, and data transfer may be performed via this converter. If such a conversion function is provided in the communication device, even if the data types do not match, it is possible to transmit and receive data converted in accordance with either data type.

  Alternatively, another communication device that can receive the desired data type may receive the transfer data and deliver it later.

  If the data types do not match each other, another communication device is inquired about a transfer sequence or a program that can process the transfer data of the data type according to the data type to be transmitted. 2 may be downloaded to an unsupported device so that a desired data type can be handled by a desired number of types of data and data division.

  On the other hand, when there are a plurality of data types common to the two communication devices, data transfer can be performed by any of the data types. Since the type of normal transfer data is predetermined such as “TXT”, “CSV”, “HTM”, etc., it is necessary to set the data type according to the data file desired to be transferred. After checking the data type of a required file, a plurality of data type information may be selected and shared.

  The data communication function table used in the present invention has a series of procedures related to data communication, that is, functions for defining objects, and the table itself can be regarded as one object. Not only sharing information related to data transmission for each information, but also as an object called a transfer task, that is, by making the object common, it facilitates negotiation between both communication devices at the start of data communication, Unnecessary communication congestion can be reduced.

  Spontaneous transmission data type, transmission data information, data transfer status, transfer data, spontaneous reception side data type, response transmission data type, request reception data type, number of data divisions, number of data per type described above are data communication services It is a parameter called property for determining the form. There are various methods for determining these parameters. Specific examples are shown in FIGS. 9, 10, and 11. FIG. 9 and 10 show properties related to [A] data transmission service.

(1) Handling type information for PUSH transmission (spontaneous transmission data type)
<Details of value>
-Properties indicating the number of MAX bytes and types of data to be handled when data is transmitted in the PUSH type, and the number of each data type and MAX data.
-Handling data MAX byte number: Indicates the maximum number of bytes of one data that can be transmitted.
-Number of types: Number of data types handled. A value of 0 indicates that all data types can be targeted.
-MAX data number: MAX number of data handled for each type.

<Reading / writing / notification timing>
• This value can always be read regardless of the data transfer status.

(2) Handling type information for PULL transmission (response transmission data type)
<Details of value>
-Properties indicating the number of MAX bytes of data, the number of types, each data type and the number of MAX data when data transmission is performed in the PULL type.
-Handling data MAX byte number: Indicates the maximum number of bytes of one data that can be transmitted.
-Number of types: Number of data types handled. A value of 0 indicates that all data types can be targeted.
-MAX data number: MAX number of data handled for each type.

<Reading / writing / notification timing>
• This value can always be read regardless of the data transfer status.

(3) Number of data by type for PULL transmission (number of data for each type)
<Details of value>
-Current number of data for each type.
・ The order of types is the same as the handling type information for PULL transmission, but the type with 0 data can be omitted.
・ Data No. specified for data transfer status. Are also listed in the order of this type.

<Reading / writing / notification timing>
• When the data transfer status is transferring or write-locked, the number of data is not changed.
• This value can always be read regardless of the data transfer status.

(4) Transmission data information <Details of value>
-Information such as the type, name, date, and number of bytes of each data to be sent.
-The information of one transmission data is an array-handled property, and the array element No. Is data No. It becomes. In addition, data No. The order is arranged in the type order designated by the handling type information for PULL transmission.
Date information: The date of data is represented by XX: YY: MN: DD: HH: MM: SS.
(20 to 99): (0 to 99): (1 to 12): (1 to 31): (0 to 23):
(0-59): (0-59)
If the object has no date information, set each byte data to 0.
-Number of data bytes: The total number of bytes of transmission data.
-Check code: The total of each byte data of the transmission data is added and its 2's complement.

<Reading / writing / notification timing>
• If the data transfer status is transferring or write-locked, this information is not changed.
・ Reading of transmission data information by element specification is always possible.

(5) Data transfer status <Details of value>
-Indicates the current data transfer status. Represents.
-It is also possible to set the write type information, the number of data of the specified type, and the write lock state so that the value of each data information is not changed.

<Reading / writing / notification timing>
• If the data transfer status is write lock or transfer, the data No. Must be written to start data transfer, or return to a normal end or abnormal end state.
・ If there is no missing data request or data transfer status setting after a certain period of time after data transfer, the terminal sets the data transfer status to abnormal termination.
• If the data transfer status is write lock or transfer, this value cannot be written from a terminal other than the terminal performing the transfer process.
• Reading of this value is always possible.

(6) Data transfer <Value details>
・ Data No. in the data transfer status. Is specified, the data is divided into division sizes obtained from the data division information and continuously transmitted as an array type.
-Total number of arrays: Number of all arrays to be transmitted in a divided manner.
-Divided data size: Number of divided data bytes in this frame.

<Reading / writing / notification timing>
-After receiving the data division information notification, the transmission data body is notified and transmitted from the transmission side.

  FIG. 11 shows properties related to [B] data reception service.

(1) PUSH reception handling type information (spontaneous reception side data type)
<Details of value>
-Properties indicating the number of MAX bytes of data, the number of types, and each data type when receiving data in the push type.
-Handling data MAX byte number: Represents the maximum number of bytes of one data that can be received.
-Number of types: Number of data types handled. When this value is 0, it indicates that all data types can be received.

<Reading / writing / notification timing>
• This value can always be read regardless of the data transfer status.

(2) PULL reception handling type information (request receiving side data type)
<Details of value>
-Properties indicating the number of MAX bytes of data, the number of types, and each data type when receiving data in the PULL type.
-Handling data MAX byte number: Represents the maximum number of bytes of one data that can be received.
-Number of types: Number of data types handled. When this value is 0, it indicates that all data types can be received.

<Reading / writing / notification timing>
• This value can always be read regardless of the data transfer status.

(3) Data division information <Details of value>
・ Maximum number of bytes of on-board data that is ideal for reception by the receiver
-The maximum number of installed data bytes, the maximum number of installed data bytes that can be transmitted at once by the terminal itself.
-Transmit data is divided and data transfer processing is performed so that the mounted data for data transfer can be configured with the minimum number of bytes in the maximum number of mounted data bytes.

<Reading / writing / notification timing>
• If the data transfer status is transferring, values cannot be written.

  Next, in order to execute the data communication method and procedure described in the above three embodiments, examples of messages using the properties shown in FIGS. 9, 10, and 11 will be described.

  In the process of spontaneous communication (PUSH type data communication), when performing data transfer by automatic transmission from the transmission side, after requesting the PUSH reception handling type on the reception side and confirming the transfer data type, the transmission data information Notification is performed, and data transfer is performed by performing divided data transfer from the transmission side following data transfer confirmation as a response from the reception side. A typical communication sequence of the spontaneous communication (PUSH type data communication) is shown in FIG. In this process, the transmission side automatically transmits data by an internal trigger.

<Pre-processing>
(1) Handling type information request (transmission side → reception side)
The transmission side requests the reception side to read the PUSH reception handling type information.
(2) Handling type information response (receiving side → transmitting side)
In response to the request, the receiving side transmits PUSH reception handling type information as a response.

<Data transmission process>
(3) Transmission data information notification (transmission side → reception side)
The transmission side sets the transmission data No. in the “data transfer state”. Is set during write transfer, and then the transmission data information such as transfer data size and checksum is notified to the receiving side. The receiving side determines whether or not data can be received from the transmission data information, and if reception is not possible, sets abnormal termination in the data transfer completion setting.

(4) Divided data information notification (receiving side → transmitting side)
If the receiving side determines that reception is possible, it transmits the maximum number of bytes that can be received by the terminal itself.
(5) Divided data transfer (transmission side → reception side)
The transmitting side divides the data and continuously transmits it to the receiving side.

(6) Request for specified divided data (receiving side → transmitting side)
If there is divided data that could not be received correctly after receiving the final divided data or when a divided data reception waiting timeout occurred, the receiving side makes a transmission request by specifying the array element number of the divided data .
(7) Designated division data transfer (sending side to receiving side)
When there is a request for designated divided data from the receiving side, the transmission side transmits the divided data of the designated array element.
(8) Data transfer completion setting (receiving side → transmitting side)
The receiving side transmits data for completing the data transfer state to the transmitting side when the data is correctly received or when the data transfer process is terminated for some reason.

  * However, this frame may not be transmitted. Therefore, the data transmission side sets a timeout in the process of waiting for the designated divided data request and the frame reception waiting for the data transfer completion setting, and performs the process of changing the data transfer state from being processed to being completed.

  (1)-(8) of FIG. 13 is an example of the message | telegram used for said each sequence. In FIG. 13, OHD is an object header, SEOJ is a transmission source object, DEOJ is a reception destination object, EPC is a property name code, and ESV is a property service content. After that, various data are loaded as necessary. These electronic messages are transmitted and received between the network control units 14 and 15 by adding the addresses of the communication devices 1 and 2 as either the transmission source address or the reception destination address.

  In the request response communication (PULL type data communication) process, when a data transfer request is made from the receiving side, after confirming the transfer data by requesting the PUSH transmission handling type on the transmitting side, the data is transferred as necessary. The information collection process is performed, and then the receiving side transmits a data transfer start trigger. In response to this trigger, the data transmission side notifies the transmission data information of the designated data, and thereafter performs the same data transfer process as the PUSH type.

  FIG. 14 shows a typical communication sequence of request response communication (PULL type data communication). Each message will be briefly described.

<Pre-processing>
(1) Handling type information request (receiving side → transmitting side)
The transmission side requests the reception side to read the handling type information for PULL transmission.
(2) Handling type information response (transmission side → reception side)
In response to the request, the receiving side transmits PULL transmission handling type information as a response.

<Target data information collection process>
The data selection process is as follows. However, each of these processes is performed as necessary. In addition, each process can be performed independently without performing data transfer.
(3) Data transfer status request (receiving side → transmitting side)
The reception side requests the data transfer state from the transmission side. In response to this request, the transmission side responds with a data transfer state.
(4) Data transfer status response (transmission side → reception side)
The transmission side transmits a data transfer status response to the reception side. When the data transfer state is unprocessed or finished, the receiving side transmits a write lock or a data transfer start trigger.

(5) Write lock (receiving side → sending side)
In order to lock the transmission side so that the current data type and data information are not rewritten, the data transfer state is set to write lock. This write lock is performed as necessary. After performing this lock, be sure to enter the data No. in the data transfer state. Must be set to start data transfer or set to end state.
(6) Number of data requests by type (receiving side → sending side)
In order to collect information immediately before the start of data transfer as required, the number of data for each transmission type is requested.
(7) Data count response by type (transmission side → reception side)
Responds to the number of data for each type upon request.

(8) Designated transmission data information request (receiving side → transmitting side)
If it is desired to acquire data information to be transmitted before data transfer processing, the transmission data information is requested by designating a data number.
(9) Specified transmission data information response (transmission side → reception side)
The transmission side responds with specified transmission data information in response to the request.

<Transmission process>
(10) Data transfer start trigger (receiving side → transmitting side)
The reception side transmits a data transfer start trigger by transmitting a frame for processing the data transfer state to the transmission side. In response to this trigger, the transmission side performs the following processing.

* The subsequent steps are the same as “PUSH type data transfer”.
15 and 16 are examples of the communication message of the PULL type sequence.

  Next, another embodiment of the data communication function table is shown in FIGS. 17 and 18, the data communication function table 901 of the communication device 1 includes a spontaneous transmission data type 911, a spontaneous reception data type 912, a response transmission data type 913, a request reception data type 914, transmission data information 915, and a data transfer state. 916, data number 917 for each type, data division number 918, and transfer data 919 are provided. The data communication function table 902 of the communication device 2 also includes a spontaneous transmission data type 921, a spontaneous reception data type 922, a response transmission data type 923, a request reception data type 924, transmission data information 925, a data transfer state 926, and a data number 927 for each type. A data division number 928 and transfer data 929 are provided.

  Each data area is divided into (a) and (b). (A) stores its own data, and (b) stores the other party's data. Among the own data (a), the spontaneous transmission data types 911 and 921, the spontaneous reception data types 912 and 922, the response transmission data types 913 and 923, the request reception data types 914 and 924, the number of data per type 917 and 927, and the data division The numbers 918 and 928 store the type of data that can be handled by the communication device itself and the number of data divisions. The transmission data information 915 and 925 and the data transfer states 916 and 926 are values determined in the data communication execution process, and are not set in the initial state. The non-setting of the data transfer states 916 and 926 means “not transmitted”. Of each data, (b) is not set since the state of the other party is not known in the initial state.

  A case where the communication device 1 performs spontaneous transmission will be described. The communication device 1 sends a telegram to the communication device 2 so as to send the spontaneous reception data type 922 (a) and the data division information 928 (a), and the communication device 2 sends data in response thereto. . The communication device 1 stores the received spontaneous reception data type 922 (a) and data division information 928 (a) in 912 (b) and 918 (b), respectively, and 911 (a), 918 (a), and The comparison confirms that there is something in common, selects a desired data type from among the common things, and writes it in the transmission data information 915 (a). In the case of FIG. 18, “HTM” is common in 911 (a) and 912 (b), and 1024 is common in 918 (a) and 918 (b).

  The communication device 1 spontaneously transmits the file A in the “HTM” format, and the transmission data information 915 (a) is converted into the data type “HTM”, the data name file A, the date 2002/3 / according to the format of FIG. 10. Set the number of data bytes as 5500, and send this data to the communication device 2. The communication device 2 stores the received data in the transmission data information 925 (b). Then, the communication device 1 prepares the file A in the transfer data 919 (a). The data transfer state 916 (a) is set to “in transfer”, and the set data is transmitted to notify the communication device 2 that the transfer is to be executed. The communication device 2 stores the received data transfer state 916 (a) in 926 (b) and prepares to receive a file.

  Next, the communication device 1 divides and transfers the file A of the transfer data 919 (a) every 1024 bytes. The communication device 2 stores the divided file A in the transfer data 929 (b) in the order of reception. If the file A is composed of a plurality of subfiles, the data transfer status 916 (a) can be changed according to the subfile number according to the subfile number, such as “Transferring No. 3”. Status and subfile number management. The communication device 2 can also manage the transfer status and the number of subfiles according to 926 (b). When the transmission data information 915 (a) is transmitted, if the number of types of data 917 (a) is transmitted at the same time or separately, the communication device 2 can transmit the number of files transmitted in the transfer execution. However, it is possible to determine whether or not the reception is completed.

  In this way, one of the data types, the number of data divisions, the number of data for each type that can be handled by each of the communication devices 1 and 2 is obtained, and compared with its own processing capability, the processing capability is shared. Keep it. When transfer data such as a file is selected and transferred, the data type, data name, etc. of the transfer data are made common to each other. Next, the transfer data is shared by the transfer execution. As described above, by using the data communication function table in common, communication arbitration between the communication devices 1 and 2 can be reliably performed with a small communication amount.

  In the data communication function tables of FIG. 17 and FIG. 18, it is assumed that both the communication devices 1 and 2 can perform spontaneous transmission, spontaneous reception, response transmission, and request reception. Of these, one or both of (a) and (b) may be omitted. Embodiments 1, 2, and 3 correspond to such a case. For sharing, it is preferable to share the data type, data division information, number of data for each type, etc. that can be handled by the communication device on the transmission data transmission side. Correspondingly, preparations for reception may be made. In particular, if the receiving side can change the correspondence according to the attribute and situation of the transfer data to be received, this may be done.

  In the data communication function tables of FIGS. 17 and 18, the spontaneous transmission data type 911 and the response transmission data type 913 are combined into one transmission data type 911, and the spontaneous reception data type 912 and the request reception data type 914 are combined. One received data type 912 may be used, and 913 and 914 may be deleted. In this case, in the spontaneous communication, the received data type of the other party is obtained, and the own transmission data type and the received data type of the other party are compared. In request response communication, the transmission data type of the other party is obtained, and the received data type of the other party is compared with the transmission data type of the other party.

  As described above, individual properties may be shared by transferring them in the form of a data communication function table, instead of transferring and sharing them step by step. In this case, the necessary contents of the data communication function table are not set and are sent. In some cases, only one transfer may be required, but in general, transfer is performed several times between both the communication devices 1 and 2.

(Embodiment 4)
A case in which data is spontaneously transmitted from the terminal device to the controller will be described for the terminal device and the controller having the configuration of FIG. As an example, a case will be described in which the terminal device that spontaneously transmits data is the air conditioner 1 and the receiving side is the controller 2, and the air conditioner 1 spontaneously transmits the data to the controller 2 when maintenance data is accumulated for a certain period.

  As shown in FIG. 19, the air conditioner 1 is provided with a transmission function table 1001, and the controller 2 is provided with a reception function table 1002, both of which refer to and write to a communication partner table via a communication network. To send and receive data. Hereinafter, the transmission function table and the reception function table are collectively referred to as a communication function table.

  The transmission function table 1001 stores the following information. The operation state 1011 indicates whether or not the operation of the entire transmission function table 1001 is valid. For example, the operation state 1011 is expressed by binary values of ON = 0x30 and OFF = 0x31. Reference numeral 1012 denotes data providing device / function information, which stores a type of device that provides transmission data and a code representing its function. When transmitting maintenance data for a certain period of the air conditioner, 0x013001F0, which is a combination of the code 0x013001 representing the air conditioner and the code 0xF0 representing the maintenance data, is stored in 1012 (the code is an example). This code is unique depending on the device and function. Reference numeral 1013 denotes transmission data information, which is composed of, for example, a data type (bitmap format, text format, etc.), a data name, a data creation date, and a transmission data size, as shown in FIG. Reference numeral 1014 denotes a data transmission state indicating whether transmission is in progress. Reference numeral 1015 denotes data division information, which is a data size that can be handled by the controller 2 on the receiving side. Reference numeral 1016 denotes transmission data itself.

  On the other hand, the following information is stored in the reception function table 1002. The operation state 1021 indicates whether or not the operation of the entire reception function table 1002 is valid. For example, the operation state 1021 is expressed by binary values of ON = 0x30 and OFF = 0x31. 1022 is data providing device / function information similar to 1012, and stores a device type that provides transmission data and a code representing its function. Reference numeral 1024 denotes a data reception state indicating whether reception is in progress. Reference numeral 1025 denotes data division information, which is a data size that can be handled by the receiving side.

  The operation of this embodiment will be described below. First, the air conditioner 1 and the controller 2 need to recognize each other's communication partner. In particular, since the air conditioner 1 on the transmission side can transmit data to the controller 2 only after confirming the presence of the controller 2 as the transmission destination, this confirmation sequence is essential. This is performed by the following communication procedure.

  The air conditioner 1 and the controller 2 are designed to notify the communication function table information of the air conditioner 1 and the controller 2 on the network immediately after the power is turned on. When the power supply of the air conditioner 1 enters after the controller 2, the controller 2 receives a notification that the air conditioner 1 is equipped with the transmission function table 1001, and then writes an ON message for the operation state 1011 of the transmission function table 1001 of the air conditioner 1. Send. The writing message for the air conditioner 1 includes the address of the controller 2 and information indicating that the receiving function table 1002 is mounted. The air conditioner 1 knows the existence of a device having a reception function table by receiving the message.

  On the other hand, when the controller 2 is turned on later, the air conditioner 1 can receive the notification of the reception function table 1002 installed in the controller 2 and thus can recognize the transmission destination. After receiving the notification that the reception function table 1002 is mounted, an ON write message may be sent to the operation state 1021 of the reception function table 1002 of the controller 2 so that the controller 2 recognizes the presence of the air conditioner 1.

  Instead of the above communication procedure, the air conditioner 1 and the controller 2 turn on the power and notify the communication function table information of the air conditioner 1 and the controller 2 on the network, and then refer to the communication function table of the other party for reference / notification of the operation state A message may be sent and the communication partner may be confirmed by a response to the message. For example, when the air conditioner 1 having a transmission function table is activated, an operation state reference / notification request message is sent to all devices having a reception function table on the network. When the controller 2 receiving this message reads the operation state 1021 of the reception function table 1002 and creates a response message and sends it to the air conditioner 1, the air conditioner 1 can confirm the presence of the reception function table 1002 of the controller 2.

  As described above, as a pre-process for performing data transmission, the air conditioner 1 can recognize the controller 2 that is a partner of spontaneous transmission.

  Next, transmission / reception of data between the air conditioner 1 and the controller 2 will be described. For example, when maintenance data for a certain period is accumulated, the air conditioner 1 creates data providing device / function information and transmits it to the controller 2. When the controller 2 receives the data providing device / function information of the air conditioner 1, the controller 2 examines the contents of the information, and when obtaining the maintenance data, the controller 2 sets the data transmission status 1014 of the transmission function table 1001 of the air conditioner 1 to “ A message for writing a code indicating “sending” is sent to the air conditioner 1. At the same time, the controller 2 writes a code indicating “receiving” in the data reception state 1024 of its reception function table 1002. When the controller 2 does not acquire maintenance data, a message for writing a code indicating “abnormal end” to the data transmission state 1014 of the transmission function table 1001 of the air conditioner 1 is sent to the air conditioner 1. In this case, the controller 2 writes nothing in the data reception state 1024 of its own reception function table 1002.

  The air conditioner 1 first reads the transmission data information 1013 from the transmission function table 1001 and transmits it to the controller 2, triggered by reception of a “sending” write message by the controller 2. Thereafter, the transmission data 1016 is read out, the transmission data is divided into data sizes stored in the data division information 1015, and spontaneous transmission to the controller 2 is executed. When the controller 2 receives all of the divided transmission data, the controller 2 assembles the data and stores it linked to the previously received transmission data information.

  When the air conditioner 1 transmits data providing device / function information to the controller 2, transmission data information 1013 may be added. In this case, when the air conditioner 1 receives the “transmitting” write message from the controller 2, it immediately sends the divided transmission data to the controller 2.

  As described above, in the fourth embodiment, the terminal device having the function of spontaneously transmitting data and the controller that receives the data include the device / function information of the terminal device before the terminal device transmits the data. Since the information about the data is sent to the controller, the controller can acquire the data after clearly grasping the device / function information that provides the data.

(Embodiment 5)
A case where the controller requests data from the controller to the terminal device and the controller having the configuration shown in FIG. 1 will be described. As an example, a method of transmitting and receiving data when the terminal device is a camera 1 that takes a still image and the receiving side is a controller 2 and the controller 2 requests still image data of the camera 1 will be described.

  The camera 1 and the controller 2 have a transmission function table 1001 and a reception function table 1002 shown in FIG. Since the configuration of each table is the same as that of the fourth embodiment, the description thereof is omitted. Note that the data providing device / function information 1012 of the transmission function table 1001 stores 0x06C001F1 in which the code 0x06C001 representing the camera 1 and the code 0xF1 representing still image data are combined (the code is an example).

  The operation of this embodiment will be described below. First, the controller 2 must recognize the presence of the camera 1. This is performed by the following communication procedure.

  As in the fourth embodiment, the camera 1 and the controller 2 are designed to notify the information of the communication function table of the camera 1 and the controller 2 on the network immediately after the power is turned on. When the power supply of the controller 2 enters after the camera 1, the camera 1 writes ON in the operation state 1021 of the reception function table 1002 of the controller 2 when receiving the notification that the reception function table 1002 of the controller 2 is installed. The writing message for the controller 2 includes information indicating that the address of the camera 1 and the transmission function table 1001 are mounted. The controller 2 knows the existence of a device having a transmission function table by receiving the message.

  Conversely, when the camera 1 is turned on later, the controller 2 can receive the notification of the camera 1 having the transmission function table 1001 installed, and thus can recognize the data request destination. After receiving the notification that the first transmission function table 1001 is installed, an ON write message may be sent to the operation state 1011 of the transmission function table 1001 of the camera 1 to make the camera 1 recognize the presence of the controller 2.

  Instead of the above communication procedure, as in the fourth embodiment, the camera 1 and the controller 2 turn on the power and notify the communication function table information of the camera 1 and the controller 2 to the other party's communication function table. An operation state reference / notification request message may be sent, and a communication partner may be confirmed by a response to the message.

  As described above, the controller 2 can recognize the camera 1 that is the data request destination as pre-processing for performing data transmission.

  Next, data transmission / reception between the camera 1 and the controller 2 will be described. The controller 2 transmits to the camera 1 a reference request message for acquiring information on the device and function of the data supply source with respect to the data providing device / function information 1012 in the transmission function table 1001 of the camera 1. Whether the controller 2 obtains information on the device and function of the data supply source of the camera 1 (information called “camera still image” in the present embodiment) from the response message of the camera 1 and obtains data from the camera 1 Judging. When the controller 2 acquires data from the camera 1, first, a reference request message in the data transmission state 1014 of the transmission function table 1001 of the camera 1 is transmitted to the camera 1. The controller 2 receives the response message from the camera 1 and confirms the transmission state of the camera 1. If the transmission state is “READY”, the “transmission” code is displayed in the data transmission state 1014 of the transmission function table 1001 of the camera 1. A write request message is transmitted to the camera 1. Further, the controller 2 writes a code indicating “receiving” in the data reception state 1024 of its own reception function table 1002.

  When the “transmitting” code is written in the data transmission state 1014 of the transmission function table 1001 by the controller 2, the camera 1 creates transmission data information 1013 and transmits it to the controller 2. Thereafter, the transmission data 1016 is read, the transmission data is divided into data sizes stored in the data division information 1015, and the spontaneous transmission to the controller 2 is executed. When the controller 2 receives all of the divided transmission data, the controller 2 assembles the data and stores it linked to the previously received transmission data information.

  As described above, in the fifth embodiment, in the terminal device that holds data and the controller that requests the data, before the controller requests the data from the terminal device, the information about the data including the device / function information of the terminal device. Therefore, the controller can acquire the data of the terminal device after clearly grasping the device / function information that provides the data.

(Embodiment 6)
Specific examples of properties for realizing the data communication method and procedure described in the fourth and fifth embodiments are shown in FIGS. 20, 21, and 22. FIG.

  FIG. 20 shows properties related to the data reception service.

(1) Handling object information for PUSH reception <Details of value>
-Handling file MAX byte number: MAX byte number of assembled file that can receive PUSH.
-Number of file providing device objects / properties: Number of properties of the local node device or other node device that provides files that can be received by PUSH. The maximum value is 40.
-File providing device object / property: A combination of the object code and property code of the local node device or other node device that provides a PUSH receivable file.
-Number of files: Indicates the number of files for each device object / property that can be received and held.
・ 0 ~ 0xFFFE = number of files. 0xFFFF = Indicates that there is no particular limitation.

<Reading / writing / notification timing>
・ Reading of this property value is always possible.

(2) PULL reception handling object information <value details>
-Handling file MAX byte number: MAX byte number of assembled file that can be PULL received.
-Number of file providing device objects / properties: Number of properties of the own node device or other node device that provides files that can be received by PULL. The maximum value is 40.
-File providing device object / property: A combination of the object code and property code of the local node device or other node device that provides the PULL receivable file.
-Number of files: Indicates the number of files for each device object that can be received and held. 0 to 0xFFFE = number of files. 0xFFFF = Indicates that there is no particular limitation.

<Reading / writing / notification timing>
・ Reading of this property value is always possible.

(3) Data division information <Details of value>
-EDT maximum number of bytes that is optimal for reception

<Reading / writing / notification timing>
• Read before sending data notification on the sending side.
・ Reading of this property value is always possible.

  FIG. 21 shows some of the properties related to the data transmission service.

(1) Handling object information for PUSH transmission <value details>
-Handling file MAX byte number: MAX byte number of file before splitting that can be sent by PUSH.
-File providing device object / property count: The number of properties of the local node device or other node device that provides files that can be sent by PUSH. The maximum value is 40.
-File providing device object / property: A combination of the object code and property code of the local node device or other node device that provides a PUSH receivable file.
-Number of files: Indicates the number of files held for each device object / property.

<Reading / writing / notification timing>
-This property value can be read regardless of the transmission status.
-The number of files in this property value is not changed when the transmission status is sending or writing is locked.

(2) PULL transmission handling object information <value details>
-Handling file MAX byte number: MAX byte number of file before splitting that can be sent by PULL.
-Number of file providing device objects / properties: Number of properties of the own node device or other node device that provides files that can be sent via PULL. The maximum value is 40.
-File providing device object / property: A combination of the object code and property code of the local node device or other node device that provides the PULL receivable file.
-Number of files: Indicates the number of files held for each device object / property.

<Reading / writing / notification timing>
-This property value can be read regardless of the transmission status.
-The number of files in this property value is not changed when the transmission status is sending or writing is locked.

  FIG. 22 shows some of the properties related to the data transmission service.

(3) Transmission status <Details of value>
-READY / Previous normal end = 0: Waiting for processing, before transmission execution, or previous normal end.
-Start transmission = 0x01: Start transmission processing (during transmission processing)
-Write locked = 0x10: Mode for not changing the values of transmission target information, transmission file information, and transmission data. • Previous abnormal termination = 0xFF: Waiting for processing and abnormal termination last time.

<Reading / writing / notification timing>
・ Reading of this property value is always possible.
• When the transmission status is “Sending” or “Write locked”, this property value cannot be written from other than the file receiving side node that has written the transmission status.
-Transmission processing can be interrupted by writing normal end or abnormal end to this property during data transmission.
・ If the transmission status is “Transmission” or “Write lock”, it is necessary to return to the normal or abnormal termination status, or write “Transmission start” again to start transmission.

(4) Information to be transmitted <Details of value>
-File providing device object / property: Device object / property information to be sent in handling object information.-File number: File number when multiple files can be handled.

<Reading / writing / notification timing>
-In the case of PUSH type transmission, the transmission side node notifies the reception side node.
• In the case of PULL type transmission, data is written from the receiving node to the transmitting node.
-This property value is not changed when the transmission status is sending or writing is locked.
-This property value can always be read when the transmission status is “Sending” or “Write locked”.

(5) Transmission file information <value details>
-Indicates the name, date information, number of file bytes, and check code of the transmission file.
-Name: File name expressed in ASCII 8 characters.
• Attribute: A file attribute expressed in ASCII 3 characters.

-Date information: File date is expressed in the format of Y1Y2 / MN / DD HH: MM: SS.
Y1 = 0x13 ~ 0x63 (19 ~ 99), Y2 = 0x00 ~ 0x63 (00 ~ 99), MN = 0x01 ~ 0x0C (1-12),
DD = 0x01 ~ 0x1F (1 ~ 31), HH = 0x00 ~ 0x17 (0 ~ 23), MM = 0x00 ~ 0x3B (0 ~ 59),
SS = 0x00 ~ 0x3B (0 ~ 59)
If the file does not have date information, each byte data is set to 0.

-Number of file bytes: The number of bytes of the entire transmission file.
-Check code: The total of each byte of the transmission file is the 2's complement.

<Reading / writing / notification timing>
-In the case of PULL type transmission, the transmission side node notifies the reception side node of this property value after “in transmission” is written in the transmission state property from the reception side node.
-In the case of PUSH type transmission, the sending node notifies the receiving node of this property value after changing the sending state property to “sending”.

-This property value is not changed when the transmission status is sending or writing is locked.
-This property value can always be read when the transmission status is “Sending” or “Write locked”.

(6) Transmission data <Value details>
-Total number of arrays: The number of all arrays to be transmitted separately.
-Divided data size: Number of bytes of divided data. The divided data size is the same except for the final array element whose total number of arrays is 2 or more, and (divided data size + 6) is equal to the EDT size.
-Divided data: The divided data itself. The final array element has the same EDT size as the other arrays, and data after the divided data size is zero-padded.

<Reading / writing / notification timing>
-After receiving the data division information on the receiving side, send data is notified from the transmitting side node.
-If the transmission status is not transmitting, this property value cannot be notified or read.

  Next, in order to realize the data communication method and procedure described in the fourth and fifth embodiments, an example of a sequence using the properties shown in FIGS. 20, 21, and 22 will be described.

  When starting up the device, use the instance change class notification in the startup sequence of each node. When performing PUSH type file transfer, the sending side uses the EA of the receiving side node and PULL type file transfer. The receiving side acquires the EA of the transmitting side node.

FIG. 23 is a sequence in the case where the reception side rises before the transmission side.
<Processing when the receiving node rises first and the sending node rises later>

(1) Instance change class notification (sending side → receiving side)
The instance change class is notified to the receiving side according to the startup sequence. Upon receiving this notification, the receiving side can acquire the EA of the device on which the transmission service object is mounted.

(2) Operation state ON write request (reception side → transmission side)
When the receiving side is PUSH type and can receive a file, the receiving side receives a notification of the instance change class and makes a write request for turning on the operation state of the transmission service object. Upon receiving this request, the transmission side can acquire the EA of the device on which the reception service object is mounted.

FIG. 24 is a sequence in the case where the transmission side rises before the reception side.
<Processing when the transmitting node rises first and the receiving node rises later>

(1) Instance change class notification (receiving side → transmitting side)
In accordance with the startup sequence, the instance change class is notified to the transmission side. Upon receiving this notification, the transmission side can acquire the EA of the device on which the reception service object is mounted.

(2) Operation state ON write request (transmitting side → receiving side)
When the transmission side is PULL type and file transmission is possible, the transmission side receives a notification of the instance change class and makes a write request for turning on the operation state of the reception service object. Upon receiving this request, the receiving side can acquire the EA of the device on which the transmission service object is mounted.

  In the process of spontaneous communication (PUSH type data communication), when performing file transfer by automatic transmission from the sending side, after requesting PUSH reception handling object information on the receiving side and notifying the transmission target information as necessary Following the notification of the transmission file information, the file transmission is performed by transmitting the divided data from the transmission side.

  FIG. 25 is a typical communication sequence of spontaneous communication.

<Pre-processing>
(1) Handling object information request (sending side → receiving side)
The sending side requests the receiving side to read the PUSH reception handling object information.

(2) Handling object information response (receiving side → transmitting side)
Upon receiving the request, the receiving side sends a PUSH reception handling object information as a response.
The above (1) and (2) can be omitted.

<Transmission process>

(3) Notification of transmission target information (transmission side → reception side)
When there are a plurality of reception handling object information on the reception side, the transmission side transmits the transmission target information in order to specify to which device object the data is transmitted.

(4) Transmission status write request (reception side → transmission side)
Upon receiving the transmission target information notification, the receiving side makes a write request for setting the transmission state of the transmission service object to “transmission start” when the data to be transmitted can be received. If the data to be transmitted cannot be acquired, a write request is made to set the transmission state to “last abnormal termination”.

(5) Send file information notification (send side → receive side)
After the transmission side sets “transmission start” in “transmission state”, the transmission side notifies the reception side of transmission file information such as the size and checksum of the transmission file. The receiving side determines from the transmission file information whether reception is possible.

(6) Transmission file information notification response (reception side → transmission side)
The receiving side returns a notification response.
(7) Division data transmission (transmission side → reception side)
The transmission side divides the file and continuously transmits it to the reception side.

(8) Specified division data request (receiving side → sending side)
If there is divided data that could not be received correctly after receiving the final divided data or when a divided data reception waiting timeout occurred, the receiving side makes a transmission request by specifying the array element number of the divided data .

(9) Designated division data transmission (transmission side → reception side)
When there is a request for designated divided data from the receiving side, the transmission side transmits the divided data of the designated array element.
The above (8) and (9) can be omitted.
(10) Transmission completion setting (receiving side → transmitting side)

  The reception side sets the transmission state to the end state when the file is correctly received or when the transmission process is terminated for some reason. However, the transmission completion setting may not be performed. Accordingly, the transmission side sets a timeout in the process of waiting for the designated divided data request and the frame reception waiting for the transmission completion setting, and performs the process of changing the transmission state from being transmitted to the previous normal end.

  In request response communication (PULL type data communication) processing, when requesting file transmission from the receiving side, after requesting the PUSH transmission handling object information on the transmitting side and confirming the transmission file, if necessary, After collecting transmission file information, the receiving side transmits a transmission start trigger. Upon receiving this trigger, the transmission side notifies the transmission file information of the specified object, and thereafter performs the same transmission processing as the PUSH type.

FIG. 26 shows a typical communication sequence of request / response communication.
<Pre-processing>
(1) Handling object information request (receiving side → transmitting side)
The transmitting side requests the receiving side to read the handling object information for PULL transmission.

(2) Handling object information response (transmission side → reception side)
Upon receiving the request, the receiving side sends a response for handling object information for PULL transmission.

<File information collection processing>
(3) Transmission status request (receiving side → transmitting side)
The reception side requests the transmission state from the transmission side. In response to this request, the transmission side responds with a transmission state.

(4) Transmission status response (sending side → receiving side)
The transmission side transmits a transmission status response to the reception side. The receiving side transmits a write lock or a transmission start trigger when the transmission state is unprocessed or end state.

(5) Write lock (receiving side → transmitting side)
In order to lock the transmission side so that the transmission file information is not rewritten, a write request of “write lock” is made in the transmission state. In response to the write request, the transmission side sets the transmission state to “write lock”. This write lock is performed as necessary. In addition, after setting the transmission state to “write lock”, it is necessary to set “transmission start” to the transmission state to start transmission or set it to the end state.

(6) Sending status write response (sending side → receiving side)
Responds to write requests.
(7) Request to write information to be sent (receiver side → sender side)
In order to collect various file information as required, a request for writing transmission target information is made.
(8) Sending target information write response (sending side → receiving side)
Responds to write requests.

(9) Designated transmission file information request (reception side → transmission side)
If it is desired to acquire transmission file information to be transmitted before transmission processing, the transmission file information is requested.
(10) Specified transmission file information response (transmission side → reception side)
The transmission side responds with the specified transmission file information in response to the request.

<Transmission process>
(11) Transmission start trigger (reception side → transmission side)
The reception side sends a transmission start trigger to the transmission side by making a write request to make the transmission state in process. In response to this trigger, the transmission side performs the following processing. The process after sending file information notification is the same as “PUSH type file transfer”.
The above (5) to (11) can be omitted.

(Embodiment 7)
Specific examples of properties for realizing the data communication method and procedure described in the fourth and fifth embodiments are shown in FIGS. 27, 28, and 29. FIG.

FIG. 27 shows properties related to the data reception service.
(1) Operating status Indicates the operating status of the file reception service function. 0x31 when stopped, 0x30 during normal operation.
(2) Handling object information for PUSH reception
Properties that represent information such as the maximum number of handled file bytes and file providing device objects and properties when receiving with the PUSH type. The presence of this property indicates that the file can be received with the PUSH type. This property is mandatory when receiving files with the PUSH type. When multiple instances of this service object are installed on the receiving side node, implement this property value so that each instance does not overlap.

<Details of value>
-Handling file MAX byte number: MAX byte number of assembled file that can receive PUSH.
-File storage device class / number of properties: The number of combinations of classes and properties that store files that can be received by PUSH. The maximum value is 40.
-File storage device class / property: A combination of the class group code, class code, and property code of the own node or other node device that stores files that can receive PUSH.
-Number of files: Indicates the number of files for each device class / property that can be received and held. 0 to 0xFFFE = number of files. 0xFFFF = Indicates that there is no particular limitation.

<Reading / writing / notification timing>
・ Reading of this property value is always possible.

(3) Data division information A property indicating the maximum division size of receivable data. The transmission side node compares the notified property value with the division size that can be transmitted by the own node, and reads the property in order to divide the file into smaller sizes for transmission.

<Details of value>
-Represents the maximum number of EDT bytes that can be received.
<Reading / writing / notification timing>
• Read before sending data notification on the sending side.
・ Reading of this property value is always possible.

  FIG. 28 shows properties related to the data transmission service.

(1) Operating status Indicates the operating status of the file transmission service function. 0x31 when stopped, 0x30 during normal operation.

(2) Handling object information for PULL transmission
Properties that indicate the maximum number of handled files and file providing device objects and properties when sending files with PULL. The presence of this property indicates that file transmission is possible with the PULL type. When multiple instances of this service object are installed on the receiving side node, implement this property value so that each instance does not overlap.
This property is indispensable when sending files with PULL type.

<Details of value>
-Handling file MAX byte number: MAX byte number of file before splitting that can be sent by PULL.
-File provision device object / property count: Number of property combinations with the own node or other node device object that provides files that can be sent via PULL The maximum value is 40.
-File providing device object / property: A combination of the device object and property code indicated by the class group code, class code, and instance code of the local node device or other node device that provides the PULL receivable file.
-Number of files: Indicates the number of files held for each device object / property.

<Reading / writing / notification timing>
-This property value can be read regardless of the transmission status.
-The number of files in this property value is not changed when the transmission status is sending or writing is locked.

  FIG. 29 shows properties related to the data transmission service.

(3) Transmission / reception settings Properties for writing transmission triggers and transmission / reception results from the receiving node. This property value is reflected in the “Transmission status” property at the same time as writing.
<Details of value>
-Normal end = 0x00: Transmission ends normally-Forced end = 0x01: Forced end by the receiving node
-Write lock setting = 0x10: Setting that does not allow writing of this property value from other than the receiving node that has written this property. With this setting, files are not sent to other than the receiving node that wrote this property.
-Start transmission = 0x20: Start transmission processing

<Reading / writing / notification timing>
-Writing a value to this property is reflected in the "Transmission status" property immediately after writing. If "Start transmission" is written to this property value, the transmission status is "Sending" and "Write lock". Is set to “write locked”, otherwise it is set to “READY”. When the “Transmission status” property is being sent or the write is locked, this property value cannot be written from a node other than the receiving node that has written to this property.
-Transmission processing can be interrupted by writing normal end or abnormal end to this property during data transmission.

(3) Transmission status A property indicating the transmission status of whether or not the local instance is in transmission processing. When this property value is being transmitted, the transmission target information, transmission file information, and transmission data are not changed.

<Details of value>
・ READY = 0: Waiting.
-Write lock = 0x10: Mode to protect file transmission to other than the receiving node that wrote to the send / receive setting property.
-Sending = 0x20: Sending process in progress.
<Reading / writing / notification timing>
・ Reading of this property value is always possible.
The value written in the “Send / Receive Setting” property is reflected in this property.

(4) Transmission target information A property for specifying a file to be actually transmitted from handling object information to be transmitted. When the number of file providing device objects / properties in the handling object information is one and the number of files is one, it is not necessary to specify the file by this property.

<Details of value>
-File providing device object / property: Device object / property information to be sent in handling object information.-File number: File number when multiple files can be handled.
<Reading / writing / notification timing>
-In the case of PUSH type transmission, the transmission side node notifies the reception side node.
• In the case of PULL type transmission, data is written from the receiving node to the transmitting node.
-This property value cannot be changed when the transmission status is “Transmitting”.
-This property value can always be read when the transmission status is “Sending” or “Write locked”.
-If the transmission status is not transmitting or write-locked, this property value will read the data padded with 0 for each value.

(5) Transmission file information A property indicating information such as the name and attribute of a file to be transmitted, date information, and the number of bytes. This property makes it possible to acquire information for selecting files to be sent and received when sending and receiving with the PULL type.

<Details of value>
-Indicates the name, date information, number of file bytes, and check code of the transmission file.
-Name: File name expressed in ASCII 8 characters.
• Attribute: A file attribute expressed in ASCII 3 characters.

-Date information: File date is expressed in Y1Y2 / MN / DD HH: MM: SS format.
Y1 = 0x13 ~ 0x63 (19 ~ 99), Y2 = 0x00 ~ 0x63 (00 ~ 99), MN = 0x01 ~ 0x0C (1-12),
DD = 0x01 ~ 0x1F (1 ~ 31), HH = 0x00 ~ 0x17 (0 ~ 23), MM = 0x00 ~ 0x3B (0 ~ 59),
SS = 0x00 ~ 0x3B (0 ~ 59)
If the file does not have date information, each byte data is set to 0.

-Number of file bytes: The number of bytes of the entire transmission file.
-Check code: The total of each byte of the transmission file is the 2's complement.

<Reading / writing / notification timing>
-In the case of PULL type transmission, the transmission side node notifies the reception side node of this property value after “in transmission” is written in the transmission state property from the reception side node.
-In the case of PUSH type transmission, the sending node notifies the receiving node of this property value after changing the sending state property to “sending”.
-This property value is not changed when the transmission status is transmitting.
-This property value can always be read when the transmission status is “Sending” or “Write locked”.
-If the transmission status is not transmitting or write-locked, this property value will read the data padded with 0 for each value.

(6) Transmission data A property indicating transmission file data as an array.
<Details of value>
-Total number of arrays: The number of all arrays to be transmitted separately.
-Divided data size: Number of bytes of divided data. The divided data size is the same except for the final array element whose total number of arrays is 2 or more, and (divided data size + 6) is equal to the EDT size.
-Divided data: The divided data itself. The final array element has the same EDT size as the other arrays, and data after the divided data size is zero-padded.

<Reading / writing / notification timing>
-After receiving the transmission file information notification response of the receiving side node, the transmission side node notifies the transmission data.
-If the transmission status is not transmitting, this property value cannot be notified or read.

  Next, in order to realize the data communication method and procedure described in the fourth and fifth embodiments, examples of sequences using the properties shown in FIGS. 27, 28, and 29 will be described.

  When starting up the device, use the instance change class notification in the startup sequence of each node. When performing PUSH type file transfer, the sending side uses the EA of the receiving side node and PULL type file transfer. The receiving side acquires the EA of the transmitting side node.

FIG. 30 is a sequence in the case where the reception side rises before the transmission side.
<Processing when the receiving node rises first and the sending node rises later>

(1) Instance change class notification (sending side → receiving side)
In accordance with the startup sequence, the instance change class is notified to the receiving side node. Upon receiving this notification, the application on the receiving node can acquire the EA of the transmitting node on which the file transmission service object is mounted. (Sending node notification service)

(2) Operation status notification (receiving side → transmitting side)
When the receiving node is PUSH type and can receive a file, it receives an instance change class notification and notifies the operation status of the file reception service object. Upon receiving this notification, the application on the transmission side node can acquire the EA of the reception side node on which the file reception service object is mounted. (Receiving node notification service)

FIG. 31 is a sequence in the case where the transmission side rises before the reception side.
<Processing when the transmitting node rises first and the receiving node rises later>

(1) Instance change class notification (receiving side → transmitting side)
In accordance with the startup sequence, the instance change class is notified to the transmitting side node. Upon receiving this notification, the application on the transmission side node can acquire the EA of the reception side node on which the file reception service object is mounted. (Receiving node notification service)

(2) Operation status notification (sending side → receiving side)
When the transmission side is PULL type and file transmission is possible, the transmission side node receives the notification of the instance change class and notifies the operation state of the file transmission service object. Upon receiving this notification, the receiving-side application can acquire the EA of the transmitting-side node in which the file transmission service object is mounted. (Sending node notification service)

  In the spontaneous communication (PUSH type data communication) process, the sending node requests PUSH reception handling object information of the receiving node, notifies the transmission target information as necessary, and then sends the transmission file information notification. Subsequently, file transmission is performed by performing divided data transmission from the transmission side node.

FIG. 32 is a typical communication sequence of spontaneous communication.
<Pre-processing>

(1) Handling object information request (sending side → receiving side)
The application on the sending side node requests the receiving service object on the receiving side node to read out the PUSH reception handling object information. (Handling Object Information Request Service) The file transfer service middleware of the transmission side node may perform simultaneous broadcast to the entire instance on the assumption that a plurality of reception service objects are mounted on the reception side node.

(2) Handling object information response (receiving side → transmitting side)
Upon receiving the request, the receiving side node transmits PUSH reception handling object information as a response.
The above (1) and (2) can be omitted.

<Transmission process>
(3) Notification of transmission target information (transmission side → reception side)
When there is a plurality of reception handling object information of the reception side node, the application of the transmission side node transmits the transmission target information in order to specify to which device object the data is transmitted. This notification is triggered by a request from the application to the file transfer service middleware. (File transmission request service)

(4) Transmission / reception setting write request (reception side → transmission side)
In response to the transmission target information notification, the application on the receiving side node makes a write request to set the transmission / reception setting of the transmission service object to “start transmission” when the data to be transmitted can be received. If the data to be transmitted cannot be acquired or is not acquired, a write request is made to set the transmission / reception setting to 0x01: forced termination. (Transmission setting writing service)

(5) Send file information notification (send side → receive side)
The file transfer service middleware of the transmission side node notifies the transmission side node of transmission file information such as the size and checksum of the transmission file after receiving “transmission start” in the transmission / reception setting write request (4). In addition, the “transmission state” property of the transmission service object used for file transmission is set to 0x20: transmitting.

(6) Transmission file information notification response (reception side → transmission side)
The receiving side node returns a notification response to the transmitting side node.

(7) Division data transmission (transmission side → reception side)
The transmission side node divides the file and continuously transmits it to the reception side node.

(8) Specified division data request (receiving side → sending side)
The receiving node specifies the array element number of the divided data if there is divided data that could not be received correctly after receiving the final divided data or when a timeout (= 1 minute) waiting to receive the divided data occurred. And make a transmission request.

(9) Designated division data transmission (transmission side → reception side)
The transmitting side node always transmits the divided data of the designated array element when there is a request for the designated divided data from the receiving side node.
The above (8) and (9) can be omitted.

(10) Transmission completion setting (receiving side → transmitting side)
The file transfer service middleware on the receiving node sets the transmission / reception setting to 0x00: normal end or 0x01: forced end when the file is received correctly to the transmitting node or when the transmission process is terminated for some reason To do.

  However, the transmission completion setting may not be performed. Therefore, the transmission side node sets a timeout of 1 minute in the process of waiting for the reception of the designated divided data and the frame reception of the transmission completion setting, and sets the “transmission state” property to 0x00: READY.

  The file transfer service middleware of the receiving node assembles a plurality of data obtained by the divided data transmission into one file and notifies the application together with the file information obtained by the transmission file information notification. (File reception notification service)

  In the request response communication (PULL type data communication) process, the sending node requests PUSH transmission handling object information from the receiving node, checks the sending file, and then collects the sending file information as necessary. The receiving node transmits a transmission start trigger. In response to this trigger, the transmitting node notifies the transmission file information of the specified object, and thereafter performs the same transmission processing as the PUSH type.

FIG. 33 shows a typical communication sequence of request / response communication.
<Pre-processing>

(1) Handling object information request (receiving side → transmitting side)
The application on the reception side node requests the transmission side node to read the handling object information for PULL transmission. (Handling Object Information Request Service) The file transfer service middleware of the receiving side node may perform simultaneous broadcasting to the entire instance on the assumption that a plurality of transmission service objects are mounted on the transmitting side node.

(2) Handling object information response (transmission side → reception side)
Upon receiving the request, the transmitting side node transmits the PULL transmission handling object information as a response.

<File information collection processing>
(3) Transmission status request (receiving side → transmitting side)
The file transfer middleware of the reception side node requests the transmission state from the transmission service object of the transmission side node obtained by the handling object information request (1).

(4) Transmission status response (sending side → receiving side)
The transmission side node transmits a transmission state response to the reception side node. When the transmission state is “READY”, the reception side node transmits a write lock or a transmission start trigger.

(5) Write lock (receiving side → transmitting side)
In order for other nodes to protect the reception request, 0x02: Write lock write request is made to the “transmission / reception setting” property. In response to the write request, the transmission side node sets the “transmission state” property to 0x02: write lock. This write lock is performed as necessary.

  In addition, after setting the “transmission / reception setting” property to 0x02: write lock, it is necessary to set the property to 0x20: transmission start to start transmission or set it to the end state.

  After the write lock request, a timeout of 1 minute is provided for any write request from the receiving side, and the transmission state is set to 0x00: READY.

(6) Send / Receive setting write response (Transmission side → Reception side)
Responds to write requests.

(7) Request to write information to be sent (receiver side → sender side)
If necessary, request to write the transmission target information.

(8) Sending target information write response (sending side → receiving side)
Responds to write requests.
The above (3) to (8) can be omitted.

(9) Transmission start trigger (receiving side → transmitting side)
The file transfer service middleware of the reception side node sends a transmission start trigger to the transmission side node by making a write request to set the transmission / reception setting to 0x20: transmission start. In response to this trigger, the file transfer service middleware of the sending side node sets the “sending state” property to 0x20: sending.

  The sequence after the transmission file information notification is the same as the sequence after the transmission file information notification of the spontaneous communication.

  The PUSH type file transmission related service, which is the service of the transmission side node shown in FIG. 32, is shown below.

(1) Receiving-side node notification service A service for notifying an application of the ECHONET address of a receiving-side node that is a transmission destination for transmitting a file in the push type. There is no input data, and the response data is the ECHONET address of the receiving node.

(2) Handling object information request service A service for obtaining handling object information for PUSH reception from the receiving node. Input data is the ECHONET address of the receiving node. The response data is PUSH reception handling object information.

(3) File transmission request service A service that sets data to the file transmission object of its own node and performs file transmission in the push type. Input data is transmission target information, transmission file name, transmission file attribute, transmission file date, and pointer to the transmission file body which is transmission data. The response data is a transmission result indicating transmission completion or transmission failure.

  The PULL type file transmission related service, which is the service of the transmission side node shown in FIG. 33, is shown below.

(1) Write lock notification service A service for notifying an application when a write lock is written from the receiving node to the transmission / reception setting of the transmitting node. There is no input data or response data.

(2) Transmission target information notification service When writing is performed on the transmission target information of the transmission side node from the reception side node, the written transmission target information is notified to the application. There is no input data, and the response data is transmission target information.

(3) File update request service A service for setting data to the file transmission object of the own node. When the transmission state of the file transmission object is write lock or transmission, it cannot be updated. Input data is transmission target information, transmission file name, transmission file attribute, transmission file date, and pointer to the transmission file body which is transmission data. The response data is a transmission result of update completion or update failure.

  The PUSH type file reception related service which is the service of the receiving side node shown in FIG. 32 is shown below.

(1) Transmission target information notification service
A service that notifies the application of the received information when a notification of transmission target information is received from a sending node that performs PUSH type file transmission. There is no input data. The response data is the ECHONET address of the transmission side node and transmission target information.

(2) Transmission / reception setting write request service A service that makes a “transmission start” write request to the transmission / reception setting property of the file transmission service object of the transmitting node when the transmission target information received by the transmission target information notification service is receivable. There is no input data or response data.

(3) File reception notification service A service that notifies an application of information on a received file when reception of a PUSH type file is completed from the transmission side node. There is no input data, the response data is a transmission file name, a transmission file attribute, a transmission file date, and a pointer to a transmission file body that is transmission data.

  The PULL type file reception related service, which is the service of the receiving side node shown in FIG. 33, is shown below.

(1) Sending-side node notification service A service for notifying an application of the ECHONET address of a sending-side node that is a transmission source for sending a file in the push type. There is no input data, and the response data is the ECHONET address of the transmitting side node.

(2) Handling object information request service A service for requesting handling object information for PULL transmission to the file transmission object of the transmission side node. The input data is an ECHONET address on the transmission side, and the response data is handling object information for PULL transmission.

(3) File reception request service Requests the file transmission service object of the transmission side node to transmit the file with the specified file providing device object, property, and file number. The file transfer service middleware is a service that controls a series of sequence from confirmation of the transmission state of the transmitting side node, transmission of a transmission start trigger, reception of a file, and setting of completion of reception, and returns “reception completion” upon completion of reception of the file. The input data is the ECHONET address that is the transmission source, the transmission target information, and the write lock setting that is a flag indicating whether or not the transmission / reception setting of the transmission file service object is set to the write lock at the beginning of the reception process. The response data is a reception result indicating reception completion or reception failure.

(Embodiment 8)
Specific examples of properties for realizing a data communication method and procedure when transferring a file between two terminals having the configuration of FIG. 1 are shown in FIGS.

  FIG. 34 shows properties related to the data reception service.

(1) Operation status Set the operation (ON / OFF) of the file reception service function and acquire the operation status. It is 0x30 when the operation is ON (service provision), and 0x31 when the operation is OFF (service stop). When the operation is OFF, access to other properties is not guaranteed.

FIG. 45 is a configuration diagram of PUSH reception handling object information.
(2) Handling object information for PUSH reception Properties that represent information such as the number of handled file MAX bytes and file providing device objects and properties when receiving in the push type. This property is indispensable when receiving files with the push type. The value of the file storage device information of this property must not be duplicated in each instance.

<Details of value>
-Handling file MAX byte number: MAX byte number of the assembled file that can receive PUSH.
Number of file information: The number of file storage information for storing files that can be received by PUSH. The maximum value is 40.
File storage information: A combination of file storage device information, which is information on a device storing a push receivable file, and the number of files that can be received for each file storage device.
-File storage device information: Class group code, class code, and property code of the device that stores the file.
-Number of files: Indicates the number of files for each file storage device information that can be received and held. 0 to 0xFFFE = number of files. 0xFFFF = Indicates that there is no particular limitation.

(3) Data division information A property indicating the maximum division size of receivable data. The transmission side node compares the notified property value with the division size that can be transmitted by the own node, and reads the property in order to divide the file into smaller sizes for transmission.

<Details of value>
-Represents the maximum number of EDT bytes that can be received.

<Reading / writing / notification timing>
• Read before sending data notification on the sending side.

  FIG. 35 shows properties related to the data transmission service.

(1) Operation status Set the operation (ON / OFF) of the file transmission service function and acquire the operation status. 0x30 when the operation is ON (service provision), and 0x31 when the operation is OFF (service stop). When the operation is OFF, access to other properties is not guaranteed.

FIG. 46 is a configuration diagram of PULL transmission handling object information.
(2) Handling object information for PULL transmission Properties indicating the number of handling file MAX bytes, file providing device object and properties, etc. when performing file transmission in PULL type. In each instance, the value of the file providing device information of this property must not be duplicated.
This property is indispensable when performing file transmission in the PULL type.

<Details of value>
-Handling file MAX byte number: MAX byte number of file before splitting that can be sent by PULL.
-Number of file provision information: The number of file provision information for providing files that can be sent by PULL. The maximum value is 40.
File provision information: File provision device information that provides files that can be sent by PULL and the number of files that are held for each file provision device information.
-File providing device information: A combination of a device object and a property code indicated by a class group code, a class code, and an instance code of a device that provides a PULL-transmittable file.
-Number of files: Indicates the number of files held for each device object / property.

<Reading / writing / notification timing>
-The number of files in this property value is not changed when the "Transmission status" property is being sent.

  FIG. 36 shows properties related to the data transmission service.

(3) Transmission / reception settings Properties for writing transmission triggers and transmission / reception results from the receiving node. This property value is reflected in the “Transmission status” property at the same time as writing.

<Details of value>
-Normal end = 0x00: Transmission ends normally-Forced end = 0x01: Forced end by the receiving node
-Start transmission = 0x20: Start transmission processing

<Reading / writing / notification timing>
-Writing a value to this property is reflected in the "Transmission status" property immediately after writing. If "Start transmission" is written to this property value, the "Transmission status" property is set to "Transmission". Otherwise, it is set to READY. Is done. When the "Transmission status" property is being sent, this property value cannot be written from other than the receiving node that has written to this property.
-Transmission processing can be interrupted by writing normal termination or forced termination to this property during data transmission.

(4) Transmission status A property indicating the transmission status of whether or not the local instance is in transmission processing. If this property value is being sent, the “Send file information” property and “Send data” property must not be changed.

<Details of value>
・ READY = 0: Waiting.
-Sending = 0x20: Sending process in progress.

<Reading / writing / notification timing>
-The value written to the “Send / Receive Setting” property is reflected in this property.
・ The timing when the “Transmission status” property changes to READY is as follows. Immediately after starting the node, 2. 2. “Send / Receive Setting” property indicates 0x00 normal termination, 0x01: Forced termination Immediately after Set There are three timings after the timeout.
・ The timing when the “Transmission status” property changes during transmission is as follows: In the “Send / Receive Setting” property, this is 0x20: Immediately after the Send Start Set.

FIG. 47 is a configuration diagram of transmission target information.
(5) Transmission target information A property for specifying file providing device information to be transmitted. In the PUSH type, the transmission side node notifies the reception side node of the property value, thereby indicating the intention of transmitting the file of the file providing device indicated by the property value. On the other hand, in the PULL type, the receiving side node writes in this property of the transmitting side node to request that the transmitting side node secure the file of the file providing device. In response to this, the transmission side node notifies the reception side node of this property value regardless of the success or failure of the file allocation.

<Details of value>
-File providing device information: File providing device information to be sent in handling object information.-File number: File number of file providing device information. The file numbering method is implementation-dependent at the sending node. However, when the file providing device object / property is handled as an array, the file number is set equal to the array element number.

<Reading / writing / notification timing>
-In the case of PUSH type transmission, this property is notified to the file reception service object of the receiving side node.
-In the case of PULL type transmission, this property is written from the receiving node.

  When this write request message is received, the transmission target information is returned to the file reception service object of the receiving node. However, if writing is not performed correctly, the transmission target information with a file number of 0xFFFF is notified.

FIG. 48 is a configuration diagram of transmission file information.
(6) Transmission file information A property indicating information such as the name and attribute of a file to be transmitted, date information, and the number of bytes. With this property, it is possible to acquire information for selecting a file to be transmitted / received at the time of PULL type transmission / reception.

<Details of value>
-Indicates the name, date information, number of file bytes, and check code of the transmission file.
-Name: File name expressed in ASCII 8 characters. File names are left-justified and empty areas are filled with 0x00.
• Attribute: A file attribute expressed in ASCII 3 characters. File names are left-justified and empty areas are filled with 0x00.

-Date information: File date is expressed in Y1Y2 / MN / DD HH: MM: SS format.
Y1 = 0x13 ~ 0x63 (19 ~ 99), Y2 = 0x00 ~ 0x63 (00 ~ 99), MN = 0x01 ~ 0x0C (1-12),
DD = 0x01 ~ 0x1F (1 ~ 31), HH = 0x00 ~ 0x17 (0 ~ 23), MM = 0x00 ~ 0x3B (0 ~ 59),
SS = 0x00 ~ 0x3B (0 ~ 59)
If the file does not have date information, each byte data is set to 0. When Y1 is 0x00, date data is invalid.

-Number of file bytes: The number of bytes of the entire transmission file.
-Check code: The total of each byte of the transmission file is the 2's complement.

<Reading / writing / notification timing>
-When the “Send / Receive Setting” property is written to the sending node and the “Send Status” property is changed during transmission, this property is notified to the receiving node.
-If this property does not include the "Transmission target information" property value in the "PULL transmission handling object information" property file providing device object / property (the transmission target information is invalid), this property file byte Notify by setting the number to 0.

FIG. 49 is a configuration diagram of transmission data.
(7) Transmission data A property indicating the data obtained by dividing the transmission file data for each divided data size as an array. This array element must be contiguous.
<Details of value>
Array element number: The transmission file is divided into divided data sizes, and the number obtained by numbering each divided data in order from the beginning of the transmission file is defined as an array element number.
-Total number of arrays: The number of all arrays to be transmitted separately.
-Divided data size: Number of bytes of divided data. The divided data size is the same except for the final array element whose total number of arrays is 2 or more, and (divided data size + 6) is equal to the EDT size.
-Divided data: Individual data obtained by dividing the transmission file. The final array element has the same EDT size as the other arrays, and data after the divided data size is zero-padded.

<Reading / writing / notification timing>
-After receiving the transmission file information notification response of the receiving side node, the transmission side node notifies the transmission data.
-If the "Transmission status" property is not being transmitted, a response not possible is returned.

  Next, in order to realize a data communication method and procedure when transferring a file between two terminals having the configuration of FIG. 1, an example of a sequence using the properties of FIGS. 34, 35, and 36 will be described. explain. In this embodiment, the file transfer method by spontaneous communication is PUSH type, the file transfer method by request response communication is PULL type, and the file transfer of each method is PUSH type file transfer and PULL type file transfer. And

  When starting up the equipment, use the instance change class notification in the startup sequence of each node. When PUSH type file transfer is performed, the sending side performs EA of the receiving side node and PULL type file transfer. The receiving side acquires the EA of the transmitting side node.

FIG. 37 is a sequence in the case where the reception side rises before the transmission side.
<Processing when the receiving node rises first and the sending node rises later>

(1) Instance change class notification (sending side → receiving side)
[Sender node processing]
In accordance with the startup sequence, the instance change class is notified to the receiving side node.
[Receiver node processing]
When receiving the notification message, the file transfer service middleware of the reception side node notifies the application of the EA of the transmission side node in which the file transmission service object is mounted. (Sender node notification service). The application on the receiving node manages the EA on the transmitting node.

(2) Operation status notification (receiving side → transmitting side)
[Reception side node processing] Upon receiving the instance change class notification, the file transfer service middleware of the reception side node sends the operation state notifications of all file reception service objects capable of receiving files in the PUSH type. Must be notified (required).
[Sender node processing]
When receiving the notification message, the file transfer service middleware of the transmission side node notifies the application of the EA of the reception side node equipped with the file reception service object (reception side node notification service). The application on the transmission side node manages the EA on the reception side node.

FIG. 38 is a sequence in the case where the transmission side rises before the reception side.
<Processing when the transmitting node rises first and the receiving node rises later>

(1) Instance change class notification (receiving side → transmitting side)
[Receiver node processing]
In accordance with the startup sequence, the instance change class is notified to the transmitting side node.
[Sender node processing]
When receiving the notification message, the file transfer service middleware of the transmission side node notifies the application of the EA of the reception side node on which the file reception service object is mounted (reception side node notification service). The application on the transmission side node manages the EA on the reception side node.

(2) Operation status notification (sending side → receiving side)
[Sender node processing]
When receiving the instance change class notification, the file transfer service middleware of the transmission side node must notify the reception side node of the operation state of all the file transmission service objects that can transmit files in the PULL type ( Required).
[Receiver node processing]
When receiving the notification message, the file transfer service middleware on the reception side notifies the application of the EA of the transmission node on which the file transmission service object is mounted (transmission side node notification service). The application of the receiving node manages the EA of the transmitting node.

  When performing file transfer by automatic transmission from the sending side node, request the "PUSH receiving handling object information" property of the receiving side node, notify the "sending target information" property if necessary, Subsequent to the notification of the “information” property, file transmission is performed by dividing and transmitting the target data.

  FIG. 39 shows a typical communication sequence for spontaneous communication, and FIGS. 41 and 42 show examples of messages used in the communication sequence for spontaneous communication.

<Pre-processing>
(1) Handling object information request (sending side → receiving side)
[Sender node processing]
The application on the transmission side node requests the reception service object of the reception side node to read out the “handled object information for PUSH reception” property. (Handling Object Information Request Service) The file transfer service middleware of the transmission side node may perform simultaneous broadcast to the entire instance on the assumption that a plurality of reception service objects are mounted on the reception side node.

(2) Handling object information response (receiving side → transmitting side)
[Receiver node processing]
(1) Upon receipt of the handling object information request, all receiving service objects of the receiving side node send a response “PUSH receiving handling object information” property.
[Sender node processing]
When receiving the response message, the file transfer service middleware of the sending node stores the SEOJ in the message linked with the handling object information as the file sending service object of the receiving node, and stores the handling object information for the application. Returns the response of the request service.

<Transmission process>
(3) Notification of transmission target information (transmission side → reception side)
[Sender node processing]
The application on the transmission side node sets transmission target information in the file transfer service middleware (file acquisition notification service). In response to this, in the file transfer service middleware, the transmission side node notifies the reception side node of transmission target information. (Mandatory) At this time, the file transfer service middleware determines SEOJ and DEOJ of the notification message as follows. SEOJ arbitrarily selects a file transmission service object as a transmission window. DEOJ selects a file reception service object (acquired by sequence (2)) of the reception side node that can handle file providing device information received by the file acquisition notification service.
[Receiver node processing]
The file transfer service middleware of the reception side node stores SEOJ in the notification message as a file transmission service object of the transmission side node (transmission target information notification service).

(4) Transmission start trigger (receiving side → transmitting side)
[Receiver node processing]
The application on the receiving node (3) receives the transmission target information notification and sets the result of determining whether the file can be received to the file transfer service middleware (file reception setting service). When receiving a file, the file transfer service middleware of the receiving node sends a transmission start trigger that sets the “transmission / reception setting” property to 0x20: transmission start to the file transmission service object that is the transmission target information notification source. . If the file specified in the transmission target information cannot be acquired or is not acquired, a write request is made to set the “transmission / reception setting” property to 0x01: forced termination (required).
[Sender node processing]
The file transfer service middleware of the transmission side node notifies the application of the write result for the “transmission / reception setting” property of the reception side node (file transmission setting notification service). The file transfer service middleware of the transmitting side node writes to the “transmission state” property in accordance with the write data to the “transmission / reception setting” property (required).

(5) Send file information notification (send side → receive side)
[Sender node processing]
Upon receiving the file transmission setting service, the application on the transmission side node sets the transmission file and transmission file information in the file transfer service middleware (file transmission request service). In response to this, the file transfer service middleware notifies the file reception service object of the reception side node of the transmission file information (required).

(6) Transmission file information notification response (reception side → transmission side)
[Receiver node processing]
The receiving side node returns a notification response to the transmitting side node.

(7) Division data transmission (transmission side → reception side)
[Sender node processing]
(6) Upon receipt of the transmission file information notification response, the file transfer service middleware of the transmission side node divides the transmission file for each divided data size, specifies the EA of the reception side node and the file reception service object and arranges it. Continuous transmission is performed in ascending order of element number (required).

(8) Specified division data request (receiving side → sending side)
[Receiver node processing]
The file transfer service middleware of the reception side node, when there is divided data that could not be received correctly, the array element No. of the divided data. Is specified and a transmission request is made to the transmission side node.

(9) Designated division data transmission (transmission side → reception side)
[Sender node processing]
When receiving the (8) designated divided data request from the receiving side node, the middleware of the transmitting side node transmits the divided data of the designated array element to the receiving side node.

(10) Transmission completion setting (receiving side → transmitting side)
[Receiver node processing]
The file transfer service middleware on the receiving side node will return 0x00 if the file is received correctly in the “Send / Receive Setting” property of the file transmission service object on the sending side node: 0x01: normal end, 0x01 if the transmission process ends for some reason : Set to forced termination (required).

  The file transfer service middleware of the receiving node (7) assembles a plurality of data obtained by the divided data transmission into one file and notifies the application together with the file information obtained by the transmission file information notification (5). (File reception setting service response) On the other hand, the file transfer service middleware of the transmission side node notifies the application when it receives (10) transmission completion setting or forced transmission termination setting from the reception side node. If file reception fails, notify the application to that effect. (File transmission service response).

[Sender node processing]
In response to the transmission completion setting from the reception side node, the transmission side node sets the “transmission state” property to 0x00: READY. In preparation for the case where the transmission completion setting is not performed, the transmission side node sets a timeout of 1 minute or more in the process of waiting for the designated division data request and the frame reception waiting for the transmission completion setting, and sets the “transmission state” property to 0x00 after the timeout period elapses. : Set to READY. The transmitting side node is allowed to accept a retransmission request from the receiving side node within the timeout of 1 minute (required).
In addition, the file transfer service middleware of the transmission side node notifies the application when it receives (10) a transmission completion setting or a file transmission forced termination setting from the reception side node. (File transmission service response).
In request response communication (PULL type data communication) processing, when a file transmission request is made from the receiving side node, after checking the transmission file by requesting the “PUSH transmission handling object information” property of the transmitting side node The transmission file information is collected as necessary, and the reception side node transmits a transmission start trigger. In response to this trigger, the transmission side node notifies the transmission file information of the designation target object, and thereafter performs the same transmission processing as the PUSH type.

  FIG. 40 shows a typical communication sequence of request / response communication, and FIGS. 43 and 44 show examples of messages used in the communication sequence of request / response communication.

<Pre-processing>
(1) Handling object information request (receiving side → transmitting side)
[Receiver node processing]
The application on the receiving side node requests the transmitting side node to read out the “PULL transmission handling object information” property (handling object information request service). The file transfer service middleware of the receiving side node may perform simultaneous broadcasting to the entire instance on the assumption that a plurality of transmission service objects are mounted on the transmitting side node.

(2) Handling object information response (transmission side → reception side)
[Sender node processing]
In response to the handling object information request (1), all transmission service objects of the transmission side node send a response of “PULL transmission handling object information” property.
[Receiver node processing]
When receiving the response message, the file transfer service middleware of the receiving node stores the SEOJ in the message linked with the handling object information as the file transmission service object of the sending node, and stores the handling object information for the application. Returns the response of the request service.

<Transmission process>

  When the application on the receiving side node issues a file reception request to the file transfer service middleware, the file is transferred according to the following sequence.

(3) Request to write information to be sent (receiver side → sender side)
[Receiver node processing]
When the application on the receiving side node requests the file securing from the file providing device on the sending side node, it sets the EA of the sending side node and the transmission target information to be secured on the file transfer service middleware (file reservation service). In response to this, the file transfer service middleware makes a write request for the “transmission target information” property to the file transmission service object of the transmission side node (required).

At this time, the file transfer service middleware determines SEOJ and DEOJ of the write request message as follows. SEOJ arbitrarily selects a file reception service object as a reception window. DEOJ selects a file transmission service object (obtained in sequence (2)) of the transmission side node that can handle file providing device information received by the file reservation service.
[Sender node processing]
In the sending node, when the file transfer service middleware receives the transmission target information write request message, the SEA, SEOJ, and DEOJ in the message are transferred to the EA of the receiving node, the file reception service object, and the file transmission service object of its own node, respectively. Remember as. Further, a file reservation number is issued and notified to the application together with the transmission target information (transmission target information notification service). At this time, the reservation number is uniquely assigned for each combination of SEA, SEOJ, and DEOJ. The application of the transmission side node receives the transmission target information notification service, secures a file determined by the device object and property specified by the transmission target information, and manages it together with the reservation number received by the transmission target information notification service. When the transmission target information notification service having the same reservation number is continuously received, only the service received last is valid. The secured file is discarded after the timeout period. Note that the timeout depends on the application implementation.

(4) Notification of transmission target information (transmission side → reception side)
[Sender node processing]
The file transfer service middleware of the transmitting side node (3) includes the transmission target information written by the transmission target information write request in the file providing device information of the “PULL transmission handling object information” property of the file transmission service object. If it is included (transmission target information is valid), the transmission target information is reported back, and if it is not included (transmission target information is not valid), or is included (transmission target information) If the file cannot be secured, the transmission target information with the file number 0xFFFF is notified (required).
[Receiver node processing]
The file transfer service middleware of the receiving side node receives this notification and returns a response to the application (file reservation service response).

(5) Request transmission status (receiver side → sender side)
[Receiver node processing]
If the application on the receiving side node finds that the sending side node has secured the file from the response to the file reservation service, it sets the file transfer service middleware to receive the file (file reception setting service).
The file transfer middleware of the receiving node requests (1) the “transmission state” property from the transmission service object of the transmitting node obtained by the handling object information request.

(6) Transmission status response (Transmission side → Reception side)
[Sender node processing]
A response is transmitted in response to the read request.

(7) Transmission start trigger (reception side → transmission side)
[Receiver node processing]
Upon receiving the READY of the file reception service or the transmission status response, the file transfer service middleware transmits a transmission start trigger for writing “0x20: transmission start” in the “transmission / reception setting” property to the file transmission service object of the transmission side node ( Required).

[Sender node processing]
The file transfer service middleware of the transmission side node receives the transmission start trigger from the reception side node and changes the “transmission state” property to 0x20: transmission (required). Also, the file reservation number is searched from SEA, SEOJ, and DEOJ in the transmission start trigger message, and this reservation number is notified to the application (file transmission setting notification service).

  The sequence after the transmission file information notification is the same as the sequence after the transmission file information notification of the spontaneous communication.

  The PUSH type file transmission related service, which is the service of the transmission side node shown in FIG. 39, is shown below.

(1) Receiving-side node notification service A service for notifying an application of the ECHONET address of a receiving-side node that is a transmission destination for transmitting a file in the push type.
The input data is the ECHONET address of the receiving side node, and the response data is none.

(2) Handling object information request service The “PUSH receiving handling object information” property is acquired for the receiving side node. Input data is the ECHONET address of the receiving node. The response data is PUSH reception handling object information.

(3) File acquisition notification service Requests that the receiving side node be notified of the “transmission target information” property. Input data is information to be sent. No response data.

(4) File transmission setting notification service This notifies the application that there has been a request to write transmission / reception settings from the receiving node. Input data includes transmission / reception setting information indicating transmission start or forced termination, and no response data.

(5) File transmission request service Data is set to the file transmission service object of its own node, and file transmission is performed. Input data includes the transmission file name, attributes, date, number of file bytes, and pointer to the transmission file. The response data is a transmission result indicating transmission completion or transmission failure.

  The PUSH type file reception related service which is the service of the receiving side node shown in FIG. 39 is shown below.

(1) Transmission target information notification service When a notification of the “transmission target information” property is received from a transmission side node that performs PUSH type file transmission, the received information is notified to the application. Input data includes the ECHONET address of the transmitting side node, transmission target information, and response data.

(2) File reception setting service When the transmission target information received by the transmission target information notification service is receivable, a transmission start write request is made in the “transmission / reception setting” property of the file transmission service object of the transmission side node, and the file is Receive. The input data includes transmission / reception settings, transmission source EA, file providing device information, and file number. The response data is a reception result, file name, attribute, date, number of file bytes, and pointer to the received file.

  The PULL type file transmission related service, which is the service of the transmission side node shown in FIG. 40, is shown below.

(1) Transmission target information notification service (file reservation)
When writing is performed on the “transmission target information” property of the transmission side node from the reception side node, the value of the written “transmission target information” property is notified to the application. The input data is the reservation number of the registered transmission target information. There is no transmission target information and response data.

(2) File transmission setting notification service A service for notifying an application that a transmission start trigger from a receiving side node has been received. Input data includes reservation No, transmission / reception setting indicating transmission start or forced termination, and no response data.

(3) File transmission request service A service that sets data to the file transmission object of its own node and performs file transmission. Input data is reservation number, transmission file name, attribute, date, number of file bytes, pointer to transmission file. The response data is a transmission result of transmission completion or transmission failure.

  The PULL type file reception related service which is the service of the receiving side node shown in FIG. 40 is shown below.

(1) Sending side node notification service An application is notified of the ECHONET address of a sending side node that is a transmission source for sending a file in the push type. The input data is the ECHONET address of the transmission side node, and the response data is none.

(2) Handling object information request service Requests the “PULL transmission handling object information” property to the file transmission object of the transmission side node. The input data is an ECHONET address on the transmission side, and the response data is handling object information for PULL transmission.

(3) File reservation service The file reservation service makes a reservation for transmitting a file with the specified file providing device object, property, and file number to the file transmission service object of the transmission side node. The file transfer service middleware writes the specified information to the transmission side node by a transmission target information write request, and receives transmission target information notification from the transmission side node. The input data is the ECHONET address of the transmitting side node and transmission target information. The response data is a reservation result indicating reservation completion or reservation failure.

(4) File reception setting service Requests the file transmission service object of the transmission side node to transmit the file reserved by the file reservation service. The file transfer service middleware controls a series of sequences from confirmation of the transmission state of the transmission side node, transmission of a transmission start trigger, reception of a file, and reception completion setting, and returns “reception completion” when reception of the file is completed. Input data is a transmission / reception setting indicating whether reception is permitted or not, an ECHONET address as a transmission source, and transmission target information. The response data is a reception result indicating reception completion or reception failure, reception file name, attribute, date, number of file bytes, and pointer to the reception file body.

  In the present invention, in the case of a communication device that communicates with a plurality of various terminal devices, such as a controller, a plurality of data communication function tables are provided so that a common table can be stored once, and the next time It may be used for data communication.

  In addition, the recording medium which recorded the program of the data communication method of this invention means recording media, such as ROM, RAM, a flexible disk, CD-ROM, DVD, a memory card, and a hard disk which recorded the program. It is also a concept including communication media such as a telephone line and a conveyance path.

It is a figure which shows an example of the block diagram of the communication apparatus which performs the data communication of this invention. It is a figure which shows the state before data communication of the data communication function table of an air conditioner and a controller. It is a figure which shows an example of transmission data information. It is a figure which shows the state after data communication of the data communication function table of an air conditioner and a controller. It is a figure which shows the state before data communication of the data communication function table of illumination and a controller. It is a figure which shows the state after data communication of the data communication function table of illumination and a controller. It is a figure which shows the state before data communication of the data communication function table of a controller and a microwave oven. It is a figure which shows the state after data communication of the data communication function table of a controller and a microwave oven. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the property relevant to a data reception service. It is a figure which shows the example of the communication sequence of spontaneous communication. It is a figure which shows the example of the message | telegram used for the communication sequence of spontaneous communication. It is a figure which shows the example of the communication sequence of request | requirement response communication. It is a figure which shows the example of the message | telegram used for the communication sequence of request response communication. It is a figure which shows the example of the message | telegram used for the communication sequence of request response communication. It is a figure which shows the state before data communication of another data communication function table. It is a figure which shows the state after data communication of another data communication function table. It is a figure which shows the transmission function table of a terminal device, and the reception function table of a controller. It is a figure which shows the example of the property relevant to a data reception service. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the node starting sequence regarding data communication. It is a figure which shows the example of the node starting sequence regarding data communication. It is a figure which shows the example of the communication sequence of spontaneous communication. It is a figure which shows the example of the communication sequence of request | requirement response communication. It is a figure which shows the example of the property relevant to a data reception service. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the node starting sequence regarding data communication. It is a figure which shows the example of the node starting sequence regarding data communication. It is a figure which shows the example of the communication sequence of spontaneous communication. It is a figure which shows the example of the communication sequence of request | requirement response communication. It is a figure which shows the example of the property relevant to a data reception service. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the property relevant to a data transmission service. It is a figure which shows the example of the node starting sequence regarding data communication. It is a figure which shows the example of the node starting sequence regarding data communication. It is a figure which shows the example of the communication sequence of spontaneous communication. It is a figure which shows the example of the communication sequence of request | requirement response communication. It is a figure which shows the example of the message | telegram used for the communication sequence of spontaneous communication. It is a figure which shows the example of the message | telegram used for the communication sequence of spontaneous communication. It is a figure which shows the example of the message | telegram used for the communication sequence of request response communication. It is a figure which shows the example of the message | telegram used for the communication sequence of request response communication. It is a block diagram of PUSH reception handling object information. It is a block diagram of PULL transmission handling object information. It is a block diagram of transmission object information. It is a block diagram of transmission file information. It is a block diagram of transmission data. It is a figure which shows the structure of the communication system 100 which transmits / receives data based on the communication method by this invention.

Explanation of symbols

1, 2 Communication equipment 3 Network 10, 20 CPU
11, 21 Memory 12, 22 Data communication control unit 13, 23 Memory management unit 14, 24 Network control unit 15, 25 Data communication function table 16, 26 Table sharing control unit 17, 27 Table value reading unit 18, 28 Table value Write unit 19, 29 Table common processing unit 100 Communication system 101, 111 Application software 102, 112 Service middleware 103, 113 Service API
104-1 and 104-2 Basic API
105 Communication middleware 106 Device object 107, 117 Service object 108 Lower-layer communication software 109 Common lower-layer communication interface

Claims (9)

In a home network, a data transmission device that transmits data to a data reception device,
The data corresponds to a property of a device object that defines information about a device on a home network,
The data receiving device stores a data reception object including push reception information related to push reception for receiving the data spontaneously transmitted from the data transmission device;
The push reception information includes maximum size information indicating a maximum size of the data after assembly capable of the push reception, data storage device information which is information of a device storing the data capable of push reception, and the data storage. Data storage information combined with the number of receivable data for each device information,
The data transmitting device is:
Data reception object storage means for storing a data reception object of the data reception device based on the push reception information;
Transmission target information setting means for setting transmission target information including data providing device information indicating device information providing the data to be transmitted and a data number of the data providing device information;
Stores a data transmission object including a transmission / reception setting property for writing a transmission trigger and a transmission / reception result from the data receiving device, a transmission state property indicating a transmission state indicating whether or not data transmission processing is being performed, and the transmission target information. Data transmission object storage means;
Select a data receiving object that can handle data providing device information of the transmission target information among the data reception objects stored in the data reception object storage means based on the transmission target information, and notify the transmission target information, Transmitting means for transmitting data corresponding to the data number;
First transmission setting means for setting the transmission state property to “prepared” when there is a transmission completion setting in the transmission / reception setting property from the data receiving device;
Second prepared setting means for providing a time-out period of a predetermined period in the process of waiting for reception of the data requested from the data receiving device and the transmission completion setting, and setting the transmission state property to prepared after the time-out period elapses When,
A data transmission device comprising: a retransmission request reception unit that receives a retransmission request from the data reception device within the timeout period.   The data transmission device according to claim 1, wherein the data transmission device or the data reception device is a home electric appliance capable of data communication. In a home network, a data receiving device that receives data from a data transmitting device,
The data corresponds to a property of a device object that defines information about a device on a home network,
A data reception object storage means for storing a data reception object including push reception information related to push reception for receiving the data spontaneously transmitted from the data transmission device;
The push reception information includes maximum size information indicating a maximum size of the data after assembly capable of the push reception, data storage device information which is information of a device storing the data capable of push reception, and the data storage. Data storage information that combines the number of receivable data for each device information,
A push reception response means for receiving the push reception information acquisition request and responding to the push reception information;
Receiving for receiving data to be transmitted, including data providing device information indicating device information providing the data to be transmitted from the data transmitting device and a data number of the data providing device information, or data based on the transmission target information Means,
The data transmission device stores a data transmission object including a transmission trigger and a transmission / reception setting property for writing a transmission / reception result from the data reception device and the transmission target information ,
The data receiving device is:
When the data is correctly received, normal end setting means for setting normal end to the transmission / reception setting property;
When ending data transmission processing, forced termination setting means for setting forced termination in the transmission / reception setting property;
A data receiving device comprising:   The data receiving device according to claim 3, wherein the data transmitting device or the data receiving device is a home electric appliance capable of data communication. In a home network, a data transmission method of a data transmission device for transmitting data to a data reception device,
The data corresponds to a property of a device object that defines information about a device on a home network,
The data receiving device stores a data reception object including push reception information related to push reception for receiving the data spontaneously transmitted from the data transmission device;
The push reception information includes maximum size information indicating a maximum size of the data after assembly capable of the push reception, data storage device information which is information of a device storing the data capable of push reception, and the data storage. Data storage information combined with the number of receivable data for each device information,
The data transmission method includes:
A data reception object storage step of storing a data reception object of the data reception device based on the push reception information;
A transmission target information setting step for setting transmission target information including data providing device information indicating device information for providing the data to be transmitted and a data number of the data providing device information;
Stores a data transmission object including a transmission / reception setting property for writing a transmission trigger and a transmission / reception result from the data receiving device, a transmission state property indicating a transmission state indicating whether or not data transmission processing is being performed, and the transmission target information. A data transmission object storage step;
Select a data receiving object that can handle data providing device information of the transmission target information among the data reception objects stored in the data reception object storage means based on the transmission target information, and notify the transmission target information, A transmission step of transmitting data corresponding to the data number;
A first prepared setting step for setting a transmission state property to prepared when there is a transmission completion setting in the transmission / reception setting property from the data receiving device;
A second prepared setting step in which a predetermined time-out time is provided in the process of waiting for reception of the data requested from the data receiving device and the transmission completion setting, and the transmission state property is set to prepared after the time-out time elapses. When,
And a retransmission request receiving step of receiving a retransmission request from the data receiving device within the timeout period. In a home network, a data receiving method of a data receiving device for receiving data from a data transmitting device,
The data corresponds to a property of a device object that defines information about a device on a home network,
A data reception object storage step for storing a data reception object including push reception information related to push reception for receiving the data spontaneously transmitted from the data transmission device;
The push reception information includes maximum size information indicating a maximum size of the data after assembly capable of the push reception, data storage device information which is information of a device storing the data capable of push reception, and the data storage. Data storage information that combines the number of receivable data for each device information,
A push reception response step for receiving the push reception information acquisition request and responding to the push reception information;
Receiving for receiving data to be transmitted, including data providing device information indicating device information providing the data to be transmitted from the data transmitting device and a data number of the data providing device information, or data based on the transmission target information Process,
The data transmission device stores a data transmission object including a transmission trigger and a transmission / reception setting property for writing a transmission / reception result from the data reception device and the transmission target information ,
The data receiving method is:
When the data has been correctly received, a normal end setting step for setting normal end to the transmission / reception setting property;
When terminating the data transmission process, a forced termination setting step of setting forced termination in the transmission / reception setting property;
A data receiving method comprising:   The program for making a computer perform the method of Claim 5 or 6.   A computer-readable recording medium on which the program according to claim 7 is recorded. In a home network, a data communication system comprising a data transmitting device and a data receiving device that receives data from the data transmitting device,
The data corresponds to a property of a device object that defines information about a device on a home network,
The data receiving device is a data receiving object storage means for storing a data receiving object including push reception information related to push reception for receiving the data spontaneously transmitted from the data transmitting device;
The push reception information includes maximum size information indicating a maximum size of the data after assembly capable of the push reception, data storage device information which is information of a device storing the data capable of push reception, and the data storage. Data storage information combined with the number of receivable data for each device information,
The data transmitting device is:
Data reception object storage means for storing a data reception object of the data reception device based on the push reception information;
Transmission target information setting means for setting transmission target information including data providing device information indicating device information providing the data to be transmitted and a data number of the data providing device information;
Stores a data transmission object including a transmission / reception setting property for writing a transmission trigger and a transmission / reception result from the data receiving device, a transmission state property indicating a transmission state indicating whether or not data transmission processing is being performed, and the transmission target information. Data transmission object storage means;
Select a data receiving object that can handle data providing device information of the transmission target information among the data reception objects stored in the data reception object storage means based on the transmission target information, and notify the transmission target information, Transmitting means for transmitting data corresponding to the data number;
First transmission setting means for setting the transmission state property to “prepared” when there is a transmission completion setting in the transmission / reception setting property from the data receiving device;
Second prepared setting means for providing a time-out period of a predetermined period in the process of waiting for reception of the data requested from the data receiving device and the transmission completion setting, and setting the transmission state property to prepared after the time-out period elapses When,
Retransmission request accepting means for accepting a retransmission request from the data receiving device within the timeout time,
The data receiving device is:
A push reception response means for receiving the push reception information acquisition request and responding to the push reception information;
Receiving for receiving data to be transmitted, including data providing device information indicating device information providing the data to be transmitted from the data transmitting device and a data number of the data providing device information, or data based on the transmission target information Means,
The data transmission device stores a data transmission object including a transmission trigger and a transmission / reception setting property for writing a transmission / reception result from the data reception device and the transmission target information ,
The data receiving device is:
When the data is correctly received, normal end setting means for setting normal end to the transmission / reception setting property;
When ending data transmission processing, forced termination setting means for setting forced termination in the transmission / reception setting property;
A data communication system comprising:

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