JP4083598B2 - Network system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a network system including a plurality of communication nodes that are connected via a common transmission line and can be shifted between a power saving state and a normal state.
[0002]
[Prior art]
Conventionally, there has been proposed a network system in which a plurality of communication nodes mounted in a vehicle are connected by a common multiplex bus, and each communication node has a normal state and a power saving state. When the communication nodes satisfy the transition condition (sleep condition), the communication nodes simultaneously shift from the normal state to the power saving state to reduce the power consumption of the battery as the power supply source (see Patent Document 1 and Patent Document 2). ).
[0003]
Here, the transition condition is
i) Input of each communication node (the input from the switch or sensor connected to each communication node has not changed over a predetermined time,
ii) The output control processing of each communication node (control processing of the controlled load connected to each communication node) is completed,
iii) Each communication node has not received information from other communication nodes for a predetermined time or more, or has received transition command information from another communication node to a power saving state.
The three items i) to iii) are all established.
When an input change is detected in one of the communication nodes in the power saving state, activation information (wakeup information) is transmitted from the communication node, and all communication nodes are simultaneously transmitted by receiving the wakeup information. By returning to the normal state, communication between nodes is resumed and the network system is operated.
[0004]
Here, the state in which communication between the communication nodes is stopped when all the communication nodes are in the power saving state is referred to as the power saving state of the network system, and all the communication nodes are in the normal state and communication is performed between the communication nodes. The state being performed is defined as the normal state of the network system.
The power saving state of each communication node is a state in which the current consumption is reduced compared to the normal state. For example, a state in which a specific electronic element such as a clock or an oscillator inside the communication node is stopped, a communication node This is a state in which power supply to a part or all of the internal electric circuit is stopped.
[0005]
[Patent Document 1]
Japanese Patent Laid-Open No. 6-291773 (paragraph number 0014)
[Patent Document 2]
JP 7-38966 A (paragraph number 0027)
[0006]
[Problems to be solved by the invention]
However, in the power saving method disclosed in the prior art, when all communication nodes satisfy the transition condition, the network system shifts to the power saving state when all the communication nodes simultaneously shift to the power saving state. For example, as described in paragraph 0014 of Patent Document 1, in a state where one communication node is controlling a load connected to itself by an internal timer, the timer control process (internal timer process) being executed is controlled. There is a problem that other communication nodes unrelated to (1) cannot shift to the power saving state and cannot suppress battery power consumption.
In addition, when the network is in a power saving state, that is, when all communication nodes are in a power saving state, the internal timer process is performed on the load connected to itself as described above due to a change in the input connected to itself of one communication node. In this case, the wake-up signal is transmitted to other communication nodes that are not related thereto, and the other communication nodes are shifted to the normal state, so that the network system shifts to the normal state. There was a problem of wasting.
[0007]
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a network system capable of saving power by suppressing power consumption of a battery.
[0008]
[Means for Solving the Problems]
The invention described in claim 1 made to solve the above problems is connected via a common transmission line (for example, multiple bus 8 in the embodiment described later), and is in a power saving state and a normal state (for example, A plurality of communication nodes (for example, described later) that can be shifted to a normal operation state, a power saving enabled state, a sleep command transmission state, a wakeup command transmission state, and a communication I / F power saving enabled state in an embodiment described later. In the network system provided with the communication nodes 2A to 2D) in the embodiment, the network system has established a transition condition from the normal state to the power saving state when all of the plurality of communication nodes are in the normal state. Communication nodes other than the communication node that is executing the self-contained control process (for example, the communication node 2D in the embodiment described later) For example, when the communication nodes 2A to 2C) in the embodiments described later shift to the power saving state and all of the plurality of communication nodes are in the power saving state, the activation input of at least one communication node is self-contained. In the case of the activation input of the control process, communication nodes (for example, communication nodes 2A to 2C in the embodiment described later) other than the communication node (for example, the communication node 2D in the embodiment described later) that has generated the activation input are It has a local power saving state that maintains the power saving state.
[0009]
According to the present invention, the network system has a local power saving state in which a communication node other than the communication node that is executing the self-contained control process is in a power saving state. Shifts to the power saving state early, and if the start input generated in a certain communication node is the start input of self-contained control processing, the power saving state continues for communication nodes that are irrelevant or unnecessary for the control. Therefore, waste of battery power can be prevented efficiently.
[0010]
In the invention described in claim 2, the communication node transmits / receives information to / from a control circuit unit (for example, a CPU 4D in an embodiment described later) that controls a load connected to the communication node via the transmission path. It is composed of a communication circuit unit (for example, communication I / F 3D in an embodiment described later) and a peripheral circuit unit (for example, a peripheral circuit unit 5D in an embodiment described later), and is omitted from a normal state. If the self-contained control process is being executed when the transition condition to the power state is established, the communication circuit unit can be shifted to the power saving state and the network system can be shifted to the local power saving state. When the communication node is in a power saving state and the start input is a self-contained control processing input, the control circuit unit and the peripheral circuit unit are shifted to a normal state. Thereby, to maintain the communication circuit unit to the power saving state, characterized in that to maintain the network system to the local power-saving state.
[0011]
According to the present invention, the communication node that is executing the self-contained processing stops the power supply of the communication circuit unit, shifts to the power saving state, and stops the communication, so that the other communication node enters the power saving state. The network system is shifted to the local power saving state by enabling the transition, and if the start-up input of the communication node in the power saving state is a self-contained control processing input, the communication circuit unit of the communication node is fed. Therefore, even if the communication node is activated for self-contained control, the communication stop state with other communication nodes is continued and the network system maintains the local power saving state. The waste of electric power can be efficiently prevented.
[0012]
According to a third aspect of the present invention, there is provided a network system including a plurality of communication nodes connected via a common transmission path and capable of shifting between a power saving state and a normal state, and at least one of the plurality of communication nodes. One communication node includes a control circuit unit that controls a load connected to the communication node itself, a communication circuit unit that transmits and receives information to and from other communication nodes via the transmission path, and a peripheral circuit unit that includes an input / output circuit When the transition condition from the normal state to the power saving state is established, if the communication node itself is executing a self-contained control process, the communication circuit unit is shifted to the power saving state, After the processing is completed, the control circuit unit and the peripheral circuit unit are shifted to a power saving state, and when the start input is a self-contained control processing input in the power saving state, the control circuit And to shift the peripheral circuit section in the normal state, the communication circuit unit is characterized in that to maintain the power saving state.
[0013]
According to the present invention, when the at least one communication node determines that the information of another communication node is not necessary for load control of the communication node, power is supplied to its communication circuit unit communicating with the other communication node. Since it stops and shifts to the power saving state, the communication node is in a local power saving state, the current consumption of the communication node alone can be reduced, and other communication nodes unnecessary for the load control are also in the power saving state. Since the network can be shifted to the local power saving state, waste of battery power can be efficiently prevented.
Also, when the start input is an input for self-contained control processing in the power saving state, information on other communication nodes is not necessary, or a load that is an output device connected to another communication node The control circuit and peripheral circuit necessary for executing the self-contained control process are shifted to the normal state and the power saving state of the communication circuit is continued. Since the node cannot shift to the normal state and the power saving state is maintained, the communication node and the network generated at the start input become a local (partial) power saving state, and the power consumption of the network system can be reduced.
That is, only the communication node circuit unit necessary for load control during processing execution or load control corresponding to the activation input is energized to a normal state, and the communication circuit unit and other communication nodes unnecessary for the load control are set. By shifting to the power saving state or maintaining the power saving state, waste of battery power of the network system is efficiently prevented.
[0014]
In the invention described in claim 4, the self-contained processing requires information of other communication nodes via the common transmission path in order to control a load connected to the one communication node. The load control is not performed.
[0015]
According to the present invention, in the case of the self-contained processing, since the information of the other communication node is not required to control the load, communication with the other communication node is not necessary. Even if the communication circuit unit is shifted to a power saving state and communication with the other communication node is stopped, load control can be performed without any influence.
[0016]
In addition, a control process for controlling a load (output device) connected to the communication node itself by an internal timer, or a control process for controlling a load connected to itself based on an input change connected to the communication node itself, etc. Control that does not require data (information) from the bus (common transmission path) for load control connected to the communication node itself, that is, control that completes load control by itself without requiring data from other communication nodes It is defined as self-contained control processing.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a network system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram showing a network system according to an embodiment of the present invention. The network system 1 includes a communication node 2 (2A to 2D) mounted on a vehicle and a multiplex bus 8 composed of twisted bear lines that connect adjacent communication nodes 2A to 2D. Each communication node 2 includes a communication I / F (interface) 3 (3A to 3D) as a communication circuit unit, a CPU 4 (4A to 4D) as a control circuit unit, and a peripheral circuit 5 (5A to 5D). Each is equipped. The communication I / Fs 3 </ b> A to 3 </ b> D are connected to the multiplex bus 8 and communicate with each other via the multiplex bus 8. The CPUs 4A to 4C are connected to the communication I / Fs 3A to 3D and the peripheral circuits 5A to 5D, and are connected to themselves via information (data) received by the communication I / Fs 3A to 3D and an input circuit included in the peripheral circuit. An output device (room light 7) which is a load such as an actuator connected to itself via an output circuit included in a peripheral circuit by an input signal from an input device such as a switch or a sensor (for example, door switch 6 or 9) Control. The peripheral circuits 5A to 5D include a power supply circuit, an input / output circuit, a timer, and the like.
[0018]
FIG. 2 is a detailed explanatory diagram of each communication node 2 shown in FIG. Each communication node 2 includes, as peripheral circuits 5, a power supply circuit 10, a WDT (Watch Dog Timer) circuit 11, an input circuit 12, an output circuit 13, and the like. In addition to the signal transmission line 14 and the reception line 15, a power saving setting line 16 for shifting the communication I / F 3 to the power saving mode is provided between the CPU 4 and the communication I / F 3.
[0019]
The communication node 2A has a door switch 6 connected to the door of the vehicle as an input device. When the door switch 6 detects the opening / closing of the door, a detection signal is input to the communication node 2A. On the other hand, the communication node 2D has, as an input device, a door switch 9 connected to another door different from the door to which the door switch 6 is connected, and when the door switch 9 detects the opening / closing of the door, the detection signal Is input to the communication node 2D. Further, the communication node 2D has a vehicle room light 7 as an output device, and ON / OFF information of the door switch 6 transmitted from the communication node 2A and ON / OFF of the door switch 9 input to the communication node 2D. Based on the input signal, the room light 7 is turned on and off by the internal timer of the communication node 2D. Further, the communication nodes 2B and 2C perform other control unrelated to the timer control of the room light 7.
[0020]
FIG. 4 shows the structure (format) of a message frame used for communication between the communication nodes 2A to 2D. FIG. 4 is an explanatory diagram of frames transmitted and received between the communication nodes 2A to 2D. As shown in the figure, the message frame includes a start-of-frame area (SOF) indicating the start of the frame, a priority area (PRI) for determining the priority of the frame, and a code area (ID) indicating message identification ( PF), a destination address area (DA) indicating a destination communication node, a source address area (SA) indicating a source communication node, and a data length area (LEN) indicating the length of a data area to be described later A data area (DAT), an error code check area (CHK), and an end-of-frame area (EOF) indicating the end of the frame.
Then, by specifying a predetermined code in the PRF, whether the message is an information frame (input change information) such as ON / OFF information of the door switch 6 transmitted from the communication node 2A, or an ACTIVE frame described later It is possible to identify whether the frame is a command frame (command information) such as a SLEEP frame.
In the ACTIVE frame and the SLEEP frame, “0” is set in LEN, and a broadcast address (broadcast communication address) is set in DA.
In the embodiment of the present invention, the WAKE-UP frame is a signal for shifting the communication circuit unit in the power saving state in which transmission / reception is stopped to the normal operation state. It is formed as a signal in which the voltage on the multiplex bus 8 is higher than the voltage used for communication for a period of time, and the communication circuit unit shifts to a normal operation state when a voltage exceeding a predetermined value is input from the multiplex bus 8. It is configured.
[0021]
FIG. 3 is a state transition diagram of each of the communication nodes 2A to 2D shown in FIG. Each state will be described by taking the communication node 2D as an example. The normal operation state shown in the figure is an operation state in which the communication node 2D can communicate, and is a state in which timer control that is not self-contained is being executed. The communication node 2D in this state periodically transmits an ACTIVE frame (see FIG. 4) indicating that the communication node 2D itself is in a normal operation state to the other communication nodes 2A to 2C.
[0022]
The power saving possible state is a state in which all load control of the communication node 2D is completed. In this state, the transmission of the ACTIVE frame from the communication node 2D is stopped, and it is detected that the ACTIVE frame from the other communication nodes 2A to 2C has not been received for a certain period of time, and shifts to the sleep command transmission state.
The sleep command transmission state is a state in which the SLEEP frame is transmitted in order to shift the other communication nodes 2A to 2C to the power saving state.
[0023]
The power saving state is a state in which the communication I / F 3D, the CPU 4D, and the peripheral circuit 5D of the communication node 2D are all in the power saving state. In this state, communication between the network systems 1 is also stopped, and power consumption is minimized.
The wake-up command transmission state is a state in which a WAKE-UP frame for causing the other communication nodes 2A to 2C to transition to the normal operation state is transmitted.
[0024]
The communication I / F power saving state is a state in which only the communication I / F 3D of the communication node 2D is in a power saving state, and network communication is stopped. In this state, only the single timer control is executed by the communication node 2D itself.
In the above description, the communication node 2D has been described as an example, but the same may be applied to the other communication nodes 2A to 2C.
[0025]
Next, this state transition condition will be described. First, in the normal operation state, when there is no input change and the load control is finished, the state shifts to a power saving state as indicated by an arrow P1. If there is no input change and the load control of the self-contained control process is being executed, the communication I / F power saving state is entered as indicated by an arrow P2. When the self-contained control process is terminated in the communication I / F power saving enabled state, the state shifts to the power saving enabled state as indicated by an arrow P3.
[0026]
When the active frame is not received from another communication node for a predetermined time in the power saving state, the state shifts to the sleep command transmission state as indicated by an arrow P4. After transmitting the SLEEP frame in the sleep command transmission state, the state shifts to the power saving state as indicated by an arrow P5. Also, when the SLEEP frame is received in the power saving enabled state, the state shifts to the power saving state as indicated by an arrow P10.
[0027]
On the other hand, when the SLEEP frame is received in the communication I / F power saving enabled state, the communication I / F power saving state is shifted as indicated by an arrow P6. When the self-contained control process is terminated in the communication I / F power saving state, the state shifts to the power saving state as indicated by an arrow P7.
[0028]
When there is an activation input other than the self-contained control process in the power saving state, the state shifts to a wakeup command transmission state as indicated by an arrow P8. When the transmission of the WAKE-UP frame is completed in the wake-up command transmission state, the state shifts to the normal operation state as indicated by an arrow P9. In addition, when the WAKE-UP frame is received in the power saving state, the state shifts to the normal operation state as indicated by an arrow P11. On the other hand, when there is a start input for self-contained control in the power saving state, the communication I / F power saving state is entered as indicated by an arrow P12.
[0029]
Although not shown in FIG. 3, when an input change such as a connected input device or a WAKE-UP frame occurs in the power saving enabled state, the normal operation state is restored, and in the communication I / F power saving enabled state. When an input change other than the self-contained control process occurs, it shifts to the normal operation state, and when an input change other than the self-contained control process occurs in the communication I / F power saving state, it shifts to the normal operation state or the wakeup command transmission state. To do.
[0030]
The communication node 2D roughly has the following three states as operation states. The first is a normal operation state that is an operation state. In this state, the communication node 2D (self-required) requires data received from the network via the bus 8 for load control. In order to execute control that is not a complete control process), an ACTIVE frame for informing the reason to the other communication nodes 2A to 2C is transmitted.
Second, the communication node 2D has a power saving state in which the power consumption of the communication I / F 3D, the CPU 4D, and the peripheral circuit 5D is minimized.
Third, the communication node 2D has a local power saving state in which only the communication I / F 3D is in a power saving state and the CPU 4D and the peripheral circuit 5D are in an operating state. This state consumes less power than the normal operating state, but consumes more power than the power saving state. In this state, a self-contained control process that can be executed independently by the communication node 2D, for example, an internal timer control process is executed. In this state, since the communication to the other communication nodes 2A to 2C is stopped, the ACTIVE frame is not transmitted.
[0031]
When the communication node 2D satisfies the following transition condition when in the normal operation state, the communication node 2D shifts to the power saving state. This transition condition is
1) There is no change in the input of all the input devices to the communication node 2D, for example, a switch connected to the communication node 2D is deactivated.
2) The output control process of the communication node 2D, that is, the control process of the non-control load connected to the communication node 2D is completed.
3) The message frame from the other communication nodes 2A to 2C is monitored, and the ACTIVE frame or the information frame is not received for a certain period, or the SLEEP frame from the other communication nodes 2A to 2C is received.
It is three.
[0032]
Further, when the communication node 2D satisfies the following transition condition when in the normal operation state, the communication node 2D shifts to the communication I / F power saving state. This transition condition is
1) There is no change in the input of all the input devices to the communication node 2D, for example, a switch connected to the communication node 2D is deactivated.
2) The communication node 2D performs only self-contained control processing.
3) The message frames from the other communication nodes 2A to 2C are monitored, and the SLEEP frames from the other communication nodes 2A to 2C are received.
It is three.
[0033]
Further, when the communication node 2D is in the communication I / F power saving state, the communication node 2D shifts to the power saving state when the self-contained control process being executed is completed.
On the other hand, the communication node 2D has a function of determining whether the control activated by the factor is a self-contained control process, for example, an internal timer process, when the activated state is caused by some factor when in the power saving state, In the case of the self-contained control process, the self-contained control process is continued without transmitting the WAKE-UP frame (transition to the communication I / F power saving state). Further, when the activated control is not the self-contained control process, or in the case of a WAKE-UP frame from the network, a transition is made to the normal operation state.
In this way, some of the communication nodes 2D configuring the network can put the other communication nodes 2A to 2C on the network into a power saving state even though the load control process is continued. Electric power can be reduced.
[0034]
FIG. 6 is a flowchart showing the power saving state transition process of the communication node 2A. In performing the power saving state transition process in step S10, it is determined in step S12 whether the door switch 6 is ON. If the determination result is YES, the process proceeds to step S13, and if the determination result is NO, the process proceeds to step S16. When the door switch 6 is ON, in step S13, information that the door switch 6 is ON is transmitted to the communication node 2D, and in step S14, an ACTIVE frame is transmitted at a predetermined interval (for example, every 1 second). The process returns to step S12.
[0035]
In step S16, in order to monitor the reception of the ACTIVE frame for a certain period of time, the T2 timer is started and the process proceeds to step S17. In step S17, it is determined whether the reception data of the door switch 6 is ON information. If a determination result is YES, it will return to Step S12, and if a determination result is NO, it will progress to Step S18. In step S18, it is determined whether a SLEEP frame has been received. If a determination result is YES, it will progress to the process of step S24 mentioned later, and if a determination result is NO, it will progress to step S19. In step S19, it is determined whether an ACTIVE frame has been received. If a determination result is YES, it will return to step S16 again and will restart a T2 timer, and if a determination result is NO, it will progress to step S20. In step S20, it is determined whether the time of the timer T2 has elapsed. If the determination result is YES, the process proceeds to step S22, and if the determination result is NO, the process returns to step S18 again.
In step S22, the SLEEP frame is transmitted to shift the other communication nodes 2B and 2C to the power saving state. And it transfers to a power saving state by step S24, and complete | finishes a process. Steps S12, 13, and 14 indicate a normal operation state, steps S16 to S20 indicate a power saving possible state, step S22 indicates a sleep command transmission state, and step S24 indicates a power saving state.
Here, the communication node 2 </ b> A has been described as a communication node that does not have a communication I / F power saving state in which the power supply of only the communication I / F is stopped.
[0036]
7 to 9 are flowcharts showing the power saving state transition process of the communication node 2D. The power saving state transition process in step S30 first determines whether or not the ON data of the door switch 6 has been received in step S32. If the determination result is YES, the process proceeds to step S34, and if the determination result is NO, the process proceeds to step S34. Proceed to S33.
[0037]
In step S34, the load of the room light 7 is controlled to be ON. Then, the process proceeds to step S36, and transmission of the ACTIVE frame is started or continued at one second intervals, and the process returns to step S32.
In step S33, it is determined whether the door switch 9 is ON. If the determination result is YES, the process proceeds to step S34, and if the determination result is NO, the process proceeds to step S35. In step S35, it is determined whether or not the room light 7 load is ON. If the determination result is YES, the process proceeds to step S38, and if the determination result is NO, the process proceeds to step S59 described later.
[0038]
In step S38, the T1 timer is started to turn on the room light 7 for a predetermined time after the door switch 9 is turned off. In step S39, it is determined whether the timer time T1 has elapsed. If the determination result is YES, the process proceeds to step S54, and if the determination result is NO, the process proceeds to step S40. In step S40, it is determined whether or not the ON data of the door switch 6 has been received. If the determination result is YES, the process returns to step S32, and if the determination result is NO, the process proceeds to step S41.
[0039]
In step S41, it is determined whether the door switch 9 is ON. If the determination result is YES, the process proceeds to step S55, and if the determination result is NO, the process proceeds to step S42.
In step S55, the room light 7 load is controlled to be ON. In step S56, it is determined whether the ON data of the door switch 6 has been received. If the determination result is YES, the process returns to step S32, and if the determination result is NO, the process proceeds to step S57. In step S57, it is determined whether a SLEEP frame is received. If the determination result is YES, the process proceeds to step S44, and if the determination result is NO, the process proceeds to step S58. In step S58, it is determined whether the door switch 9 is ON. If the determination result is YES, the process proceeds to step S59, and if the determination result is NO, the process proceeds to step S38 and the T1 timer is restarted.
In step S42, it is determined whether a SLEEP frame is received. If the determination result is YES, the process proceeds to step S44, and if the determination result is NO, the process returns to step S39.
[0040]
In step S44, communication with the other communication nodes 2A to 2C is stopped. In step S46, the communication I / F power saving state is entered, and the process proceeds to step S47. In step S47, it is determined whether or not the door switch 9 is ON. If the determination result is YES, the process proceeds to step S49, and if the determination result is NO, the process proceeds to step S47-2.
In step S47-2, it is determined whether the WAKE-UP frame has been received. If YES, the process proceeds to step S32, and the process proceeds to a normal operation state. If NO, the process proceeds to step S48.
In step S49, the room light 7 load is turned on, and the process proceeds to step S51. In step S51, it is determined whether the door switch 9 is ON. If the determination result is YES, the process returns to step S51-2, and if the determination result is NO, the process proceeds to step S53. In step S51-2, it is determined whether a WAKE-UP frame has been received. If YES, the process proceeds to step S32. If NO, the process returns to step S57. In step S53, the T1 timer is activated and the process returns to step S47.
In step S48, it is determined whether the timer time T1 has elapsed. If the determination result is YES, the process proceeds to step S50, and if the determination result is NO, the process returns to step S48 again. In step S50, the room light 7 (load) is turned off. And it transfers to a power saving state by step S52, and complete | finishes a process.
[0041]
If the determination result in step S39 is YES, the room light 7 (load) is turned off in step S54, and the process proceeds to step S59. In step S59, the T2 timer is started. In step S60, it is determined whether or not ON data of the door switch 6 is received. If the determination result is YES, the process proceeds to step S32. If the determination result is NO, the process proceeds to step S61. In step S61, it is determined whether or not the door switch 9 is ON. If the determination result is YES, the process proceeds to step S55, and if the determination result is NO, the process proceeds to step S62. In step S62, it is determined whether a SLEEP frame is received. If the determination result is YES, the process proceeds to step S66 described later, and if the determination result is NO, the process proceeds to step S63. In step S63, it is determined whether an ACTIVE frame is received. If the determination result is YES, the process returns to step S59 to restart the T2 timer, and if the determination result is NO, the process proceeds to step S64. In step S64, it is determined whether the timer time T2 has elapsed. If the determination result is YES, the process proceeds to step S65, and if the determination result is NO, the process returns to step S60. In step S65, the SLEEP frame is transmitted to cause the other communication nodes 2A to 2C to shift to the power saving state. In step S66, the communication node 2D itself shifts to the power saving state, and the process ends. In the figure, steps S32 to S36 are normal operation states, steps S38 to 42 and 54 to 58 are communication I / F power saving possible states, and steps S44 to 51, 51-2 and 53 are communication I / F power savings. Steps S59 to S64 indicate a power saving state, Step S65 indicates a sleep command transmission state, and Steps S52 and 66 indicate processing in a power saving state.
[0042]
FIG. 10 is a flowchart showing processing at the time of wakeup of the communication node 2D. In performing the wake-up process in step S70, the activation factor is investigated in step S72, and the process proceeds to step S74. In step S74, it is determined whether or not the activation input is a self-contained control processing factor, that is, whether or not the door switch 9 is ON. If the determination result is YES, the process proceeds to step S76, and if the determination result is NO, step S80 is performed. Proceed to
In addition, as a specific determination method of whether or not the activation input in step S74 is a factor of the self-contained control process,
a) Whether a WAKE-UP frame has been received,
b) The activated factor is an input change from a switch or sensor other than the WAKE-UP frame, and is transmitted as input change information to another communication node.
c) Check whether the input terminal that has caused the input change from the switch or sensor other than the WAKE-UP frame is selected as the input terminal that wakes up the network,
There is a technique such as.
In step S76, the communication I / F power saving state is entered, and control of the room light 7 is executed in step S78. Specifically, the processing after step S40 shown in FIG. 7 is executed. In step S80, a wake-up signal is transmitted, and in step S82, the process shifts to the normal control state.
[0043]
Here, as shown in steps S40, S41, S47, S47-2, S60, S61, and S74, the communication node 2D has an input corresponding to the self-contained control process in an operation state other than the normal operation state. If the input is a self-contained control process, power is saved in the network so as not to shift to the normal operation state.
[0044]
FIG. 14 is a time chart showing state changes of the door switches 6 and 9 and the room light 7 shown in FIG. When the communication node 2D detects that the door switch 6 or the door switch 9 is turned on, the room light 7 is controlled to be turned on by the communication node 2D (time t1). When the communication node 2D detects that the door switches 6 and 9 have returned to OFF (time t2), the room light 7 is controlled to be turned OFF by the communication node 2D after the timer T1 has elapsed (time t3). The state change of the communication nodes 2A to 2D in this control will be described more specifically.
[0045]
FIG. 11 is a time chart showing state changes of the door switch 6 and the room light 7 shown in FIG. FIG. 12 is a time chart showing state changes of the communication nodes 2A to 2D in the present embodiment. FIG. 13 is a time chart showing state changes of the communication nodes 2A to 2D in the comparative example (conventional example) corresponding to FIG.
First, when the door switch 6 is ON, the communication nodes 2A and 2D are in a normal operation state (WUP) and transmit an ACTIVE frame (ACF-A and ACF-D), respectively. Further, since the communication nodes 2B and 2C are irrelevant to the control of the room light 7, they are held in a power saving enabled state (SDK).
[0046]
When the door switch 6 is turned off (time t2), the communication node 2A shifts to a power saving state (see arrow P1 in FIG. 3), stops periodic transmission of the ACTIVE frame, and the communication node 2D is self-contained. Since only the timer control of the type control process is performed, the communication I / F power saving state (I / F SDK) is entered (see arrow P2 in FIG. 3), and the cyclic transmission of the ACTIVE frame is stopped.
[0047]
Therefore, since the ACTIVE frame is not received, for example, after a predetermined time (T2 timer) elapses, the communication node 2A shifts to the sleep command transmission state, transmits the SLEEP frame (SLF-A) (time t4), and the power saving state ( SLP) (see arrow P5 in FIG. 3). When the communication nodes 2B and 2C receive the SLEEP frame transmitted by the communication node 2A, the communication nodes 2B and 2C shift from the power saving possible state to the power saving state (see arrow P10 in FIG. 3). After receiving the SLEEP frame transmitted from the communication node 2A, the communication node 2D stops the power supply of the communication I / F and shifts to the communication I / F power saving state (I / F SLP) (arrow P6 in FIG. 3).
[0048]
Then, at the time when the timer T1 ends (time t3), the communication node 2D has shifted from the communication I / F power saving state to the power saving state (see arrow P7 in FIG. 3) since all the load control has been completed. The communication nodes 2A to 2D are in the power saving state.
On the other hand, in the comparative example (conventional example), as shown in FIG. 11, even after the communication node 2D detects that the door switch 6 is turned off (time t2), the ACTIVE frame is transmitted from the communication node 2D. Therefore, the communication nodes 2A to 2C are maintained in a power saving state and cannot shift to the power saving state. Each of the communication nodes 2A to 2D shifts to the power saving state because the timer control of the room light 7 by the T1 timer of the communication node 2D ends (time t3), and the transmission of the ACTIVE frame from the communication node 2D is stopped. After the predetermined time (timer T2) has elapsed, the communication node 2A transmits the SLEEP frame (time t6).
[0049]
As described above, in the conventional example, after a predetermined time by the time measurement of the T1 timer has elapsed and the room light 7 is turned off (time t3), at a time t6 after a predetermined time has elapsed by the time measurement of the T2 timer, In contrast to the communication nodes 2A to 2D that simultaneously shift to the power saving state, in the embodiment of the present invention, communication is performed from time t2 when the door switch 6 is turned off to time t4 that is a predetermined time after counting by the T2 timer. The nodes 2A to 2C are in a power saving state, the communication node 2D is in a communication I / F power saving state, and the power consumption of the network can be reduced even though the timer control of the room light 7 is being executed. At a time t3 when the room light 7 is turned off after a certain period of time has elapsed, the communication node 2D is also in a power saving state. Since the over-click can be shifted to the power saving state, it is possible to further reduce the power consumption of the network.
[0050]
FIG. 14 is a time chart showing state changes of the door switch 9 and the room light 7 shown in FIG. FIG. 15 is a time chart showing a state change of each of the communication nodes 2A to 2D in the present embodiment. FIG. 16 is a time chart showing state changes of the communication nodes 2A to 2D in the comparative example (conventional example) corresponding to FIG.
First, when the door switch 9 is OFF, the communication nodes 2A to 2D are in a power saving state.
[0051]
As shown in FIG. 15, when the communication node 2D detects that the door switch 9 is turned on (time t1), the communication node 2D shifts to the communication I / F power saving state, and transmits a WAKE-UP frame. No (see arrow P12 in FIG. 3). For this reason, the other communication nodes 2A to 2C are maintained in the power saving state, and the communication node 2D controls the room light 7 with its own internal timer. When the control of the room light 7 ends (time t3), the communication node 2D immediately shifts to the power saving state (arrow P7 in FIG. 3).
In contrast, in the comparative example (conventional example), as shown in FIG. 16, when the communication node 2D detects that the door switch 9 is turned on (time t1), the communication node 2D shifts to the normal operation state. While the WAKE-UP frame (WUF-D) is transmitted and the room light 7 is controlled to be turned on, the ACTIVE frame is periodically transmitted. The other communication nodes 2A to 2C are returned to the normal operation state by the reception of the WAKE-UP frame, and then are put on standby in a power saving enabled state. Then, the transmission of the ACTIVE frame from the communication node 2D is stopped (time t3), and after the predetermined time (timer T2) has elapsed, the communication node 2A transmits the SLEEP frame (time t7). 2D shifts to a power saving state.
[0052]
As described above, when the activation input is generated in the communication node 2D when the communication nodes 2A to 2D are in the power saving state, in the conventional example, all the communication nodes on the network until the timer control of the room light 7 is completed. However, in the embodiment of the present invention, when the activation input is a self-contained control process, the communication nodes 2A to 2C irrelevant to the control process for the activation input can save power. Since the timer control of the room light 7 can be performed while maintaining the state, waste of battery power can be efficiently prevented. Further, since the communication node 2D shifts to the communication I / F power saving state in which the power supply of the communication I / F is stopped, it is possible to more efficiently prevent battery power from being wasted.
[0053]
【The invention's effect】
As described above, according to the invention described in claim 1, when the activation input is an activation input of a self-contained control process, a communication node unrelated to the activation input quickly shifts to a power saving state. Alternatively, the power saving state can be continued, and waste of battery power can be efficiently prevented.
[0054]
According to the second aspect of the present invention, the other communication nodes can shift to the power saving state while executing the self-contained processing, and the network system is shifted to the local power saving state. Even when activated for self-contained control, the communication stop state with other communication nodes is continued and the network system maintains the local power saving state, so that waste of battery power can be efficiently prevented.
[0055]
According to the invention described in claim 3, the current consumption of the communication node alone can be reduced, and the other communication nodes unnecessary for the load control are shifted to the power saving state to locally reduce the power consumption of the network. Since the state can be shifted, waste of battery power can be efficiently prevented.
[0056]
According to the fourth aspect of the present invention, load control can be performed without any influence even if the communication circuit unit is shifted to a power saving state and communication with the other communication node is stopped.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a network system 1 according to an embodiment of the present invention.
FIG. 2 is a detailed explanatory diagram of communication nodes 2A to 2D shown in FIG.
3 is a state transition diagram of each communication node 2A to 2D shown in FIG.
FIG. 4 is an explanatory diagram of frames transmitted and received between the communication nodes 2A to 2D.
5 is a time chart showing state changes of the door switches 6 and 9 and the room light 7 shown in FIG. 1. FIG.
FIG. 6 is a flowchart showing a power saving state transition process of the communication node 2A.
FIG. 7 is a flowchart showing a power saving state transition process of a communication node 2D.
FIG. 8 is a flowchart showing a power saving state transition process of a communication node 2D.
FIG. 9 is a flowchart showing a power saving state transition process of the communication node 2D.
FIG. 10 is a flowchart showing a wake-up process of the communication node 2D.
FIG. 11 is a time chart showing the state changes of the door switch 6 and the room light 7 shown in FIG.
FIG. 12 is a time chart showing state changes of communication nodes 2A to 2D in the present embodiment.
FIG. 13 is a time chart corresponding to FIG. 12 showing a state change of each communication node 2A to 2D in a comparative example (conventional example).
14 is a time chart showing state changes of the door switch 9 and the room light 7 shown in FIG. 1. FIG.
FIG. 15 is a time chart showing state changes of communication nodes 2A to 2D in the present embodiment.
FIG. 16 is a time chart corresponding to FIG. 15 showing state changes of the communication nodes 2A to 2D in the comparative example (conventional example).
[Explanation of symbols]
1 Network system
2 Communication node
8 Multiple buses

Claims (4)

In a network system having a plurality of communication nodes connected via a common transmission path and capable of transitioning between a power saving state and a normal state,
In the network system, when a transition condition from a normal state to a power saving state is established when all of the plurality of communication nodes are in a normal state, a communication node other than the communication node that is executing a self-contained control process Will shift to the power saving state,
When all of the plurality of communication nodes are in the power saving state, if the activation input of at least one communication node is the activation input of the self-contained control process, communication nodes other than the communication node in which the activation input has occurred are omitted. A network system having a local power saving state for maintaining a power state. The communication node includes a control circuit unit that controls a load connected to the communication node, a communication circuit unit that transmits and receives information to and from each other via the transmission path, and a peripheral circuit unit that includes an input / output circuit.
If the self-contained control process is being executed when the transition condition from the normal state to the power saving state is established, the communication circuit unit is shifted to the power saving state and the network system is shifted to the local power saving state. And make it possible to
When the communication node is in a power saving state and the start input is a self-contained control processing input, the control circuit unit and the peripheral circuit unit are shifted to a normal state, and the communication circuit unit is maintained in a power saving state. The network system according to claim 1, wherein the network system is maintained in a local power saving state. In a network system having a plurality of communication nodes connected via a common transmission path and capable of transitioning between a power saving state and a normal state,
At least one of the plurality of communication nodes includes a control circuit unit that controls a load connected to the communication node itself, and a communication circuit unit that transmits and receives information to and from other communication nodes via the transmission path. And a peripheral circuit portion including an input / output circuit,
When the transition condition from the normal state to the power saving state is established, if the communication node itself is executing the self-contained control process, the communication circuit unit is shifted to the power saving state, and the process is completed. The control circuit unit and the peripheral circuit unit are shifted to a power saving state later,
In the power saving state, when the startup input is a self-contained control processing input, the control circuit unit and the peripheral circuit unit are shifted to a normal state, and the communication circuit unit maintains the power saving state. Network system. The self-contained processing is load control that does not require information of other communication nodes via the common transmission path in order to control a load connected to the one communication node. The network system according to any one of claims 1 to 3.

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