JP2015162803A - Management system of termination resistor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow for easy setting (connection, non-connection) of a termination resistor in the on-vehicle network of a working machine.SOLUTION: A management system of a termination resistor includes a plurality of electronic apparatus 2 each having a termination resistor 4 connectable with the on-vehicle network of a working machine 1, and arranged on the on-vehicle network, and setting means 40A, 40B, 40C for setting the connection of the termination resistors 4 in the electronic apparatus 2, on the basis of the position of the electronic apparatus 2 on the on-vehicle network. The setting means 40A, 40B, 40C include position calculation units 41A, 41B, 41C for determining the position of an electronic apparatus, corresponding to the identification information, on the on-vehicle network on the basis of the identification information given to each electronic apparatus, and connection setting units 42A, 42B, 42C for setting connection of the termination resistors on the basis of the positions calculated in the position calculation units 41A, 41B, 41C.

Description

  The present invention relates to a terminal resistance management system that is an electronic device connected to an in-vehicle network in a work machine such as an agricultural machine or a construction machine, and that can manage the terminal resistance of the electronic device.

Conventionally, a work machine such as an agricultural machine is equipped with a plurality of electronic devices, and an in-vehicle network is configured by connecting these electrical components. A termination resistor is connected to this in-vehicle network for stabilization of communication.
For example, in the agricultural machine (work vehicle) of Patent Document 1, a plurality of controllers (electronic devices) are mounted, and at least two of the plurality of controllers have built-in termination resistors to stabilize communication. Yes.

JP 2010-258877 A

  Now, for example, in an agricultural machine, various implements having a controller are attached and detached corresponding to farm work. The attachment and detachment of the implement change the number and positional relationship of the electronic equipment of the agricultural machine, and accordingly, the number and position of the terminating resistors connected to the in-vehicle network may also change. In this case, it is necessary to reset the terminal resistor built in the controller to be invalid or valid. In an agricultural machine such as Patent Document 1, a manual switch for switching the termination resistance is provided between the termination resistance and the communication line of the in-vehicle network in the controller, and the termination resistance is invalidated by switching the manual switch. It can be reset by enabling it. When a controller having a termination resistor is removed, it is necessary to separately prepare a unit having a termination resistor and connect the unit to the in-vehicle network.

As described above, in a working machine such as an agricultural machine, it is necessary to reset the terminal resistance due to attachment / detachment of an implement or the like. Conventionally, as described above, the manual switch is switched or the unit is connected. It was necessary to connect the terminating resistor, which was very difficult.
Therefore, in view of the above problems, the present invention has an object to provide a termination resistance management system that can easily set (connect or disconnect) termination resistance in an in-vehicle network of a work machine. is there.

The technical means of the present invention for solving this technical problem is characterized by the following points.
The invention according to claim 1 is based on a plurality of electronic devices having termination resistors connectable to an in-vehicle network of a work machine and arranged in the in-vehicle network, and positions of the electronic devices on the in-vehicle network, Setting means for setting a connection of a termination resistor included in the electronic device.

In the invention which concerns on Claim 2, the said setting means calculates | requires the position calculation part which calculates | requires the position on the vehicle-mounted network of the electronic device corresponding to the said identification information based on the identification information provided to each electronic device, and the said position A connection setting unit configured to set the connection of the termination resistor based on the position calculated by the calculation unit.
In the invention which concerns on Claim 3, the said position calculation part carries out the identification information of each electronic device arrange | positioned at the said vehicle-mounted network when the number of the electronic devices connected to the vehicle-mounted network changes for every predetermined time. Obtaining and obtaining the position of the electronic device corresponding to the identification information on the in-vehicle network.

In the invention which concerns on Claim 4, the said connection setting part has the connection resistance which the said electronic device has with respect to the electronic device located in the termination | terminus side of the said vehicle-mounted network among the several electronic devices connected to the said vehicle-mounted network. The connection command is output.
In the invention according to claim 5, at least one electronic device connected to the in-vehicle network has the setting means, and one electronic device having the setting means has a termination resistance with respect to the other electronic devices. A connection enable / disable command is output.

  In the invention which concerns on Claim 6, the said setting means is provided in the external device which can communicate with the electronic device connected to the said vehicle-mounted network, The said external device is with respect to the electronic device arrange | positioned in the said vehicle-mounted network. The terminal resistor connection enable / disable command is output.

The present invention has the following effects.
According to the first aspect of the present invention, as described above, in a working machine such as an agricultural machine, the number or arrangement of electronic devices connected to the in-vehicle network changes due to the attachment and detachment of the implement and the like. The connection state of the termination resistor may change. Even in such a case, the termination resistance of the electronic device can be easily set (connected or disconnected) by the setting means, so that communication can be stabilized.

According to the invention of claim 2, the position of the electronic device can be easily obtained using the identification information assigned to the electronic device. For example, a terminal resistor is connected to the electronic device located on the terminal side. However, the terminating resistor can be disconnected from the electronic device that is not located on the terminating side.
According to the invention of claim 3, the positional relationship of the electronic devices connected to the in-vehicle network can be monitored every predetermined time, and the termination resistance is set (connected or disconnected) according to the positional relationship at the time of monitoring. It can be performed. In addition, even when the number of electronic devices connected to the in-vehicle network changes, the positional relationship of the electronic devices can be confirmed, and the termination resistance can be set (connected or disconnected) according to the positional relationship at the time of confirmation. It can be carried out.

According to the invention which concerns on Claim 4, the termination resistance which the electronic device located in a termination | terminus side in a vehicle-mounted network can connect to a vehicle-mounted network easily.
According to the invention which concerns on Claim 5, the arrangement | positioning relationship of the whole electronic device of a vehicle-mounted network can be confirmed with one electronic device among several electronic devices connected to the vehicle-mounted network. In addition, it is possible to easily set (connect or disconnect) the terminating resistor provided in the other electronic device by the one electronic device.

  According to the invention which concerns on Claim 6, the arrangement | positioning relationship of the whole electronic device of a vehicle-mounted network can be confirmed with an external device. In addition, it is possible to easily set (connect or not connect) termination resistors provided in other electronic devices by the external device.

1 is an overall view of an in-vehicle network in a first embodiment. It is detail drawing of a switch part. It is explanatory drawing explaining the relationship between ID number and a connection permission instruction | indication. It is a general view of the vehicle-mounted network in 2nd Embodiment. (A) It is a figure which shows the case where four electronic devices are mounted on the tractor, and (b) is the case where five electronic devices are mounted on the tractor. It is explanatory drawing explaining the relationship between ID number and connection permission instruction | indication when the electronic device mounted in the tractor becomes five units. It is a general view of the vehicle-mounted network in 3rd Embodiment. It is a figure which shows the relationship between the vehicle-mounted network and external network in 4th Embodiment. It is explanatory drawing explaining a 2nd setting table. It is a figure which shows an example which connected the some electronic device. It is a figure which shows an example of a setting screen. It is a figure which shows the modification in 4th Embodiment. It is the whole tractor side view.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 is an overall view of an in-vehicle network of electronic devices mounted on a work machine.
As shown in FIG. 1, a work machine 1 such as an agricultural machine or a construction machine is equipped with a plurality of electronic devices 2 that perform operations related to the work machine 1, that is, electrical components. The electronic devices 2 are connected to each other via a communication line 3 to form an in-vehicle network. This in-vehicle network is, for example, CAN (Controller Area Network), LIN (Local Interconnect Network), FlexRay, or the like. Specifically, when the in-vehicle network is CAN, the communication line 3 includes a first communication line 3a that is CANH and a second communication line 3b that is CANL, and these first communication line 3a and second communication line. Each electronic device 2 is connected to 3b.

Now, it is necessary to connect the termination resistor 4 between the first communication line 3a and the second communication line 3b in order to stabilize the communication. In this embodiment, at least one or more electronic devices 2 are provided with a termination resistor 4 to stabilize communication.
Hereinafter, the terminator connected to the in-vehicle network will be described in detail. For convenience of explanation, the work machine 1 will be a typical tractor as an agricultural machine, and the electronic device 2 will be explained as a control device mounted on the tractor 1.

  As shown in FIG. 13, the tractor 1 includes a traveling vehicle body 10 having wheels on the front and rear sides. The traveling vehicle body 10 is equipped with an engine (for example, a diesel engine) 11, a transmission device 12, and the like. A three-point link mechanism 13 is provided at the rear portion of the traveling vehicle body 10 so as to be movable up and down. A working device 14 for performing work, that is, an implement, is detachable from the three-point link mechanism 13. Power from the engine 11 is transmitted to the working device 14 via the PTO shaft, and the working device 14 such as a tiller, a seeder, a spreader, and a harvester is driven by this power. In addition, an independently mounted cabin 15 is provided behind the engine 11, and a driver's seat 16 is provided in the cabin 15. Around the driver's seat 16, a display device 17 that displays information related to driving and work is provided.

  As shown in FIG. 1, the control device (electronic device) 2 includes a first control device 2 </ b> A that mainly controls the entire tractor 1, a second control device 2 </ b> B that controls the engine 11, and a third device that controls the display device 17. The control device 2C is a fourth control device 2D that controls the work device 14, and the first control device 2A, the second control device 2B, the third control device 2C, and the fourth control device 2D are connected to an in-vehicle network (communication line 3). )It is connected to the.

  The first control device 2A is a device that controls the entire tractor 1. For example, the first control device 2A includes an operation amount of the accelerator pedal when the accelerator pedal is operated, a shift lever position when the shift lever for shifting is operated, an upper limit value of the engine speed, an operation amount of the accelerator lever, etc. Is entered. The operation amount of the accelerator pedal, the shift lever position, and the operation amount of the accelerator lever are detected by a positioning sensor or the like, and the upper limit value of the engine speed is set by a volume provided in the vicinity of the driver's seat 16.

The first control device 2A obtains the engine speed corresponding to the input operation amount of the accelerator pedal, and outputs the obtained engine speed to the second control device 2B as a control signal. The first control device 2A obtains a shift value corresponding to the input shift lever position, and outputs the obtained shift value as a control signal to the transmission device 12, thereby controlling the transmission device 12.
Further, the first control device 2A outputs the input upper limit value of the engine speed to the second control device 2B as a control signal. When the input operation amount of the accelerator pedal is equal to or greater than the accelerator lever amount, the first control device 2A outputs the engine speed corresponding to the operation amount of the accelerator pedal as a control signal to the second control device 2B. Further, when the input accelerator pedal operation amount is less than the accelerator lever amount, the first control device 2A does not output the engine speed corresponding to the accelerator pedal operation amount to the second control device 2B. In addition to the above, the first control device 2A controls the elevation of the three-point link mechanism 13 by outputting the operation amount of the elevation lever as a control signal to the elevation drive unit. Note that the control by the first control device 2A is not limited to the above-described example.

  The second control device 2B is a device called an engine control unit. The control signal obtained from the engine speed, crank position, cam position, etc. output from the first control device 2A is supplied to the injector, common rail, and supply. The engine is controlled by outputting to a pump or the like. The engine control in the second control device 2B is the same as general diesel engine control. For example, in the control of the injector, a control signal indicating the fuel injection amount, the injection timing, and the fuel injection rate is given to the injector. Output. In the control of the supply pump and common rail, a signal indicating the fuel injection pressure and the like is output to the supply pump and common rail.

Various input information (for example, engine speed, PTO speed, shift value, vehicle speed, fuel, water temperature, etc.) relating to driving and work is input to the third control device 2C via an in-vehicle network or the like. The third control device 2 </ b> C controls the display device 17 by outputting a control signal indicating the display mode of the input information to the display device 17.
4th control apparatus 2D is an apparatus provided in the working apparatus 14, Comprising: When the said working apparatus 14 is a sowing machine, for example, the sowing amount linked (corresponding) to the vehicle speed is used as a control signal for the sowing machine. By outputting to the drive unit, the seeding amount of the seeder is controlled. In addition, 4th control apparatus 2D is not limited to what is provided in a seeder, What kind of thing may be used if it controls the working apparatus 14 with which the tractor 1 is detachably attached.

As shown in FIG. 1, each electronic device 2 (each control device 2), that is, each of the first control device 2A, the second control device 2B, the third control device 2C, and the fourth control device 2D is terminated. A resistor 4, a switch unit 5, a control unit 6, and a storage unit 7 are provided.
As shown in FIGS. 1 and 2, the termination resistor 4 can be connected to an in-vehicle network (communication line 3). The switch unit 5 is a switch that switches between a connection state in which the termination resistor 4 is connected to the in-vehicle network and a non-connection state in which the termination resistor 4 is not connected to the in-vehicle network.

  As shown in FIG. 2, the switch unit 5 switches the termination resistor 4 between a connected state and a non-connected state by three switching elements (for example, a transistor TR). Specifically, the switch unit 5 includes a transistor TR1 connected to the control unit 6, a transistor TR2 connected to the transistor TR1, and a transistor TR3 connected between the output terminal of the control unit 6 and the transistor TR1. I have.

  The base of the transistor TR1 is connected to the output terminal of the control unit 6, the emitter is connected to the ground, and the collector is connected to the base of the transistor TR2. The base of the transistor TR2 is connected to the same power supply line of 5V or the like as the control unit 6, the emitter is connected to the first communication line 3a, and the collector is connected to one end of the termination resistor 4. The collector of the transistor TR3 is connected to the other end of the termination resistor 4, the emitter is connected to the second communication line 3b, and the base is connected to a line connecting the base of the transistor TR1 and the output terminal of the control unit 6. Has been.

  When a connection signal (for example, 5V) is output from the output terminal of the control unit 6 to the transistor TR1, in the case of CAN communication, the potential of the first communication line 3a, which is CANH, is always in the range of 2.5 to 5V. Since the potential of a certain second communication line 3b is always in the range of 0 to 2.5 V, the transistor TR1, the transistor TR2, and the transistor TR3 are turned on, and both ends of the termination resistor 4 are connected to the first communication line 3a and the second communication line 3b. Connect to. On the other hand, when the control unit 6 stops outputting the connection signal to the transistor TR1, that is, outputs a non-connection signal (for example, 0 V), the transistor TR1, the transistor TR2, and the transistor TR3 are turned off, and the first communication line 3a and the first communication line 3a 2 Termination resistor 4 is disconnected from communication line 3b. That is, when the control unit 6 outputs a connection signal to the switch unit 5, the termination resistor 4 is brought into a connected state, and when the control unit 6 stops outputting the connection signal (outputs a non-connection signal), the termination resistor 4 is turned off. Connected.

In the above-described embodiment, the switch unit 5 is configured by the three transistors TR. However, the switch unit 5 is configured with respect to the termination resistor 4 disposed between the first communication line 3a and the second communication line 3b. Any configuration may be used as long as it is configured to connect or disconnect (disconnect) based on a signal output from the control unit 6.
In addition, as shown in FIG. 2, it is desirable to provide a compensation resistor 8 for compensating communication in at least one control device 2 among a plurality of control devices (electronic devices) 2. That is, the input / output unit of the control unit 6 connected to the in-vehicle network, the first line L1 connecting the first communication line 3a, and the second line L2 connecting the control unit 6 and the second communication line 3b. It is desirable to provide a compensation resistor 8 having a resistance value (for example, 2 kΩ) that is 3 kΩ or less and has little influence on the bus impedance.

The control unit 6 is composed of a CPU or the like, and outputs a control signal to a control target based on various input signals as described above. Also. The control unit 6 outputs a connection signal or a non-connection signal to the switch unit 5 and performs a switching operation of the switch unit 5.
The control unit 6 outputs connection signals and non-connection signals (switching operation of the switch unit 5) based on information stored in the storage unit 7 in advance.

First, the switching operation of the switch unit 5 based on information stored in the storage unit 7 in advance will be described.
The memory | storage part 7 is comprised from a non-volatile memory etc., and has memorize | stored the identification information for identifying the control apparatus 2 (electronic device). This identification information is, for example, an ID given to the control device 2 individually. This ID is indicated by a number or the like, and the ID number is assigned according to the arrangement of the in-vehicle network.

  In this embodiment, as shown in FIG. 1, the first control device 2A, the second control device 2B, the third control device 2C, and the fourth control device 2D are sequentially arranged from one end side to the other end of the communication line 3 of the in-vehicle network. Is arranged. Therefore, the ID number of the first control device 2A located at one end of the communication line 3 is assigned the smallest value (for example, ID = 000) among all the IDs assigned on the in-vehicle network. . The ID number of the fourth control device 2A located at the other end of the communication line 3 is assigned the largest value (for example, ID = 300) among all ID numbers assigned on the in-vehicle network. Yes. The ID number of the second control device 2B is assigned the second smallest value (ID = 100), and the ID number of the third control device 2C is assigned the third smallest value (ID = 200). Yes.

  That is, when viewing each control device 2 arranged on the in-vehicle network, the ID number of each control device 2 is set to a large value in order from one end to the other end of the communication line 3. That is, the ID number of each control device 2 located on the terminal side of the in-vehicle network (communication line 3) is set to the largest value or the smallest value among all the ID numbers. As described above, the storage unit 7 of each control device 2 stores an ID number predetermined according to the arrangement of the in-vehicle network.

Now, the storage unit 7 of each control device 2 stores a command (connection command) for setting the termination resistor 4 in a connected state or a command (disconnection command) for setting the termination resistor 4 in a disconnected state. FIG. 3 is a diagram summarizing the relationship between the ID number of each control device 2 and a connection permission / inhibition command (connection command, non-connection command).
As shown in FIG. 3, the storage unit 7 of the first control device 2A and the fourth control device 2D stores a connection command, and the storage unit 7 of the third control device 2B and the third control device 2C stores The connection command is stored. That is, when the communication line 3 is viewed as a whole, a connection command is set for the first control device 2A and the fourth control device 2D located on one end side and the other end side, and the communication command is set in the middle of the communication line 3. For the second control device 2B and the third control device 2C, a connection command is set instead of a connection command.

  As described above, when the connection enable / disable command is stored in the storage unit 7 of each control device 2, the control unit 6 operates to perform the switch operation of the switch unit 5 as follows. For example, when a key cylinder installed around the driver's seat 16 of the tractor 1 is operated and battery power is supplied to each control device 2, the control unit 6 first accesses the storage unit 7 to connect to it. Refer to the availability command.

Here, when the connection command is stored in the storage unit 7, the control unit 6 outputs a connection signal to the switch unit 5 to switch the switch unit 5 to the connected state, and the non-connection command is stored in the storage unit 7. Is stored in the switch unit 5, the non-connection signal is output to the switch unit 5 to switch the switch unit 5 to the non-connection state.
Note that it is desirable to store the connection permission / instruction command to the storage unit 7 at the time of manufacturing the tractor 1 or at the time of maintenance for adding a new control device (electronic device) 2. For example, when manufacturing the tractor 1, first, an ID number is set for each control device 2 mounted on the tractor 1. When setting the ID number, the ID number of the control device 2 located on the terminal side of the communication line 3 is set to the maximum value or the minimum value.

  Then, a connection command is associated with the control device 2 having the maximum ID number and the control device 2 having the minimum ID number, and a non-connection command is associated with the other control devices 2. Create a written table. After the writing table is created, a writing device (for example, a writer) having the writing table (data in which an ID number and a connection permission / inhibition instruction are associated) is connected to the in-vehicle network of the tractor 1 to perform writing. A connection enable / disable command is written in the storage unit 7 of the control device 2 corresponding to the ID number indicated in the table. Thereby, at the time of manufacture of the tractor 1, it is possible to store a connectability instruction in the storage unit 7 of each control device 2.

  At the time of maintenance for adding a new control device (electronic device) 2, the writing device is connected to the in-vehicle network of the tractor 1, and the ID number of the control device 2 mounted on the tractor 1 is read (extracted). Then, the ID number of the control device 2 to be added is compared with the extracted ID number, and if the ID number of the control device 2 to be added is the maximum value or the minimum value, the control to be added using the writing device Write a connection command to the device 2. When writing a connection command to the control device 2 to be added, the connection command written in the control device 2 having the maximum or minimum ID number before adding the control device 2 is deleted (rewritten to a non-connection command). . When the ID number of the control device 2 to be added is compared with the extracted ID number, if the ID number of the control device 2 to be added is not the maximum value or the minimum value, the connection command is not written. As a result, it is possible to write a connection enable / disable command to the control device 2 during maintenance for adding a new control device (electronic device) 2.

  As described above, according to the control device (electronic device) 2, the connection enable / disable command is stored in the storage unit 7 in advance, and the control unit 6 refers to the connection enable / disable command stored in the storage unit 7 when the engine is started. Then, since the termination resistor 4 to the in-vehicle network is set based on the connection enable / disable command, the termination resistor 4 is switched by the control of the control unit 6 without manually switching the termination resistor 4 as in the past. be able to.

In the first embodiment described above, the connection enable / disable command is stored in the storage unit 7 in advance before starting the engine, and the switch unit 5 is switched based on the connection enable / disable command stored in the storage unit 7. The switch unit 5 may be switched based on a connection enable / disable command input to the control unit 6 from the outside.
[Second Embodiment]
The second embodiment is an embodiment in which switching of the switch unit 5 is performed based on a connection enable / disable command input to the control unit 6 from the outside.

FIG. 4 is an overall view of the in-vehicle network in the second embodiment. In the description of the second embodiment, the description of the same configuration as that of the first embodiment described above is omitted.
As shown in FIG. 4, at least one control device (electronic device) 2 among the plurality of control devices (electronic devices) 2 includes setting means 40 </ b> A. The setting means 40 </ b> A is configured by a program stored in the control unit 6 of the control device 2.

  Specifically, among the first control device 2A, the second control device 2B, the third control device 2C, and the fourth control device 2D arranged in the in-vehicle network, the first control device 2A includes a setting unit 40A. Yes. For convenience of explanation, the first control device 2A provided with the setting means 40A is referred to as a “setting control device”, and the control devices (the second control device 2B, the third control device 2C, and the second control device provided with no setting means 40A). 4 control device 2D) may be referred to as “non-setting control device”.

The setting means 40A of the first control device 2A sets the connection of the termination resistor 4 of each control device 2 based on the position of the control device 2 on the in-vehicle network. The position calculation unit 41A and the connection setting unit 42A.
The position calculation unit 41A acquires the ID number of each control device 2 arranged in the in-vehicle network, and obtains the position of the predetermined control device 2 on the in-vehicle network based on the acquired ID number. For example, if the battery power is supplied to each control device 2 when the engine is started (at the time of key cylinder operation) and each control device 2 is activated, first, the position calculation unit 41A first sets the setting control device 2A. The ID number is acquired from the storage unit 7, and the ID numbers of the non-setting control devices 2B, 2C, and 2D are acquired through communication. That is, the position calculation unit 41A acquires all ID numbers assigned to the control device 2.

  The ID number of the non-setting control device can be obtained by requesting the ID number from the setting control device 2A to the non-setting control devices 2B, 2C, and 2D and acquiring the ID number returned in response to the request. It may be performed by acquiring the ID number automatically output to the communication line 3 by the non-setting control devices 2B, 2C, and 2D when the engine is started. At this time, there is a possibility that the termination resistor is not in a normal connection state, and in order to enable communication even when all the control devices 2 are in the non-connection state, the above-described compensation resistor 8 is provided. Yes.

  After acquiring the ID number, the position calculation unit 41A refers to all the acquired ID numbers, and selects the minimum ID number (minimum ID number) and the maximum ID number (maximum ID number) from the ID numbers. To extract. In the position calculation unit 41A, the first control device 2A corresponding to the minimum ID number and the fourth control device 2D corresponding to the maximum ID number are located on the end side of the communication line 3 (end of the in-vehicle network). It is determined that In other words, out of the four control devices 2 arranged on the in-vehicle network, the second control device 2B and the third control device 2C except for the first control device 2A and the fourth control device 2D are not in the end but in the middle. Determine that it is located.

The connection setting unit 42A sets the connection of the termination resistor 4 of each control device 2 arranged on the in-vehicle network based on the position of the control device 2 calculated by the position calculation unit 41A. That is, the connection setting unit 42 </ b> A creates a first setting table (see FIG. 3) that associates the ID number with the connection permission / inhibition command based on the position of the control device 2.
Specifically, since the first control device 2A and the fourth control device 2D are considered to be at the end of the communication line 3, the connection setting unit 42A determines the ID number (ID = 000) of the first control device 2A and the connection command. And the ID number (ID = 300) of the fourth control device 2D is associated with the connection command. Further, the connection setting unit 42A associates the ID number (ID = 100) of the second control device 2B with the non-connection command, and associates the ID number (ID = 200) of the third control device 2C with the non-connection command. . Then, the connection setting unit 42A stores the created first setting table in the storage unit 7 and the like after creating the first setting table in which all ID numbers are associated with the connection permission / inhibition commands.

Further, the connection setting unit 42A outputs a connection command to the control unit 6 in the first control device 2A and the fourth control device 2D which are supposed to be located on the terminal side of the communication line 3. The connection setting unit 42A outputs a non-connection command to the control unit 6 in the second control device 2B and the third control device 2C that are not located on the terminal end side of the communication line 3.
When the connection command is input, the control unit 6 of the first control device 2A and the fourth control device 2D outputs a connection signal to the switch unit 5 and switches the switch unit 5 to the connected state. When the disconnection command is input, the control unit 6 of the second control device 2B and the third control device 2C outputs a disconnection signal to the switch unit 5 to switch the switch unit 5 to the disconnected state.

  As described above, according to the second embodiment, at least one control device 2 connected to the in-vehicle network includes the setting unit 40A, and one control device (setting control device) 2A including the setting unit 40A is not set. A connection permission instruction is output to the control devices 2B, 2C, and 2D. Therefore, among the plurality of control devices 2 connected to the in-vehicle network, the setting control device 2 can easily connect the termination resistor 4 provided in the non-setting control device 2.

In the second embodiment described above, the position calculation unit 41A of the setting control device 2A obtains the position of the control device 2 when the engine is started. However, after the engine is started, for example, every predetermined time (for example, every few minutes). Alternatively, the position of the control device 2 may be obtained. The predetermined time includes not only the case where the time interval is constant but also the case where the time interval is variable.
Further, it is desirable that the connection setting unit 42A sets the connection of the termination resistor 4 of each control device 2 (creates a first setting table) every time the position calculation unit 41A obtains the position of the control device 2. Then, when the connection of the termination resistor 4 has changed from the previous time (when the contents of the first setting table have changed from the previous time), the connection setting unit 42A indicates to each control device 2 in the first setting table. The connected permission / inhibition command is output. In this way, the position of the control device 2 connected to the in-vehicle network can be monitored every predetermined time. When the position of the control device 2 changes, the position of the termination resistor 4 with respect to the in-vehicle network is changed. It can be changed to an appropriate position.

In the above-described embodiment, the position of the control device 2 is obtained every predetermined time, and the connection setting is performed based on the position obtained every predetermined time. When the number of control devices 2 connected to the network changes, the position of the control device 2 on the in-vehicle network may be obtained.
For example, as shown in FIG. 5A, it is assumed that four control devices 2A, 2B, 2C, and 2D are connected to the in-vehicle network. In such a situation, the work device 14 is removed and another work device 14 is mounted. As a result, as shown in FIG. It is assumed that 4 control devices 2D-1 and 2D-1 are connected. In this case, the first control device (setting control device) 2A is connected to the two fourth control devices 2D-1 and 2D-1 due to a change in communication contents, that is, the control device 2 is added. Is detected.

When it is detected that the control device 2 has been added, the position calculation unit 41A detects each control device 2 (the first control device 2A, the second control device 2B, the third control device 2C, the fourth control device) arranged in the in-vehicle network. The ID numbers of the control device 2D-1 and the fourth control device 2D-2) are acquired. After acquiring the ID numbers, the position calculation unit 41A refers to all the acquired ID numbers.
For example, as shown in FIG. 5B, the ID number (ID = 000) corresponding to the first control device 2A is the “minimum ID number” and the ID number corresponding to the fourth control device 2D-2 ( When ID = 400) is “maximum ID number”, the position calculation unit 41A determines that the first control device 2A corresponding to the minimum ID number and the fourth control device 2D-2 corresponding to the maximum ID number are It is determined that the communication line 3 is located on the terminal side (terminal of the in-vehicle network). Then, the connection setting unit 42A creates a first setting table as shown in FIG. 6 and outputs a connection enable / disable command to each control device 2 based on the first setting table.

  According to the above, the state (position, number) of the control device 2 in the in-vehicle network changes from FIG. 5A to FIG. 5B by replacing the work device 14 attached to the tractor 1. There is. Even in such a case, the termination resistance 4 of the fourth control device 2D-2 newly connected to the in-vehicle network is changed to the termination resistance 4 of the fourth control device 2D before the installation, and the in-vehicle network Since it is connected, communication of the in-vehicle network can be stabilized.

  In the second embodiment, the setting unit 40A is provided in the first control device 2A, but may be provided in other control devices 2B, 2C, and 2D. The setting means 40A is preferably provided in a device (device) that is basically not supposed to be replaced among all the electronic devices (control devices) 2 mounted on the tractor 1. For example, the setting unit 40A is preferably provided in any of the first control device 2A that controls the entire tractor 1, the second control device 2B that controls the engine 11, and the control device 2C that controls the display device.

In the second embodiment described above, the control unit 6 of the control device 2 performs the switching operation of the switch unit 5 based on the connection enable / disable command input to the control unit 6, but instead of this, the identification information Based on the (ID number), the switching operation of the switch unit 5 may be performed.
[Third Embodiment]
The third embodiment is an embodiment in which the switching operation of the switch unit 5 is performed based on the identification information (ID number) input to the control unit 6. In the description of the third embodiment, the description of the same configuration as that of the first embodiment or the second embodiment described above is omitted. For convenience of explanation, in each control device 2, the control device 2 indicating itself (self) is referred to as “self-control device”, and the position of this self-control device is referred to as “self-position”. Explains another control device as "other control device".

FIG. 7 is an overall view of the in-vehicle network in the third embodiment.
As shown in FIG. 7, each control device (electronic device) 2 includes setting means 40 </ b> B. The setting means 40B is composed of a program stored in the control unit 6.
Specifically, each of the first control device 2A, the second control device 2B, the third control device 2C, and the fourth control device 2D is provided with setting means 40B. The setting means 40B (the control unit 6 of each control device 2) includes identification information (first identification information) given to the self-control device 2 and identification information (second identification information) given to the other control device 2. Based on the above, the switching operation of the switch unit 5 is controlled. In other words, the setting unit 40B obtains the self-position of the self-control device 2 on the in-vehicle network based on the first identification information and the second identification information, and sets the termination resistor 4 according to the obtained self-position. .

Specifically, the setting unit 40B of each control device 2 includes a position calculation unit 41B and a connection setting unit 42B.
The position calculation unit 41B acquires the ID number (first identification information) of the self-control device 2 from the storage unit 7 and the ID number (second identification information) of the other control device 2 through communication when the power is turned on. . For example, in the case of the position calculation unit 41B of the third control device 2C, “ID = 200” as the first identification information is acquired and “ID = 000, 100, 300” as the second identification information is acquired.

The acquisition of the second identification information may be performed by requesting an ID number from the self-control device 2 to the other control device 2 and acquiring the ID number returned as a response to the request. You may carry out by acquiring the ID number which the other control apparatus 2 output to the communication line 3 automatically at the time of starting.
After acquiring the ID numbers, the position calculating unit 41B refers to all the acquired ID numbers and obtains the rank of the first identification information (ID number of the self-control device 2) for all the ID numbers. For example, in the case of the third control apparatus 2C, the first identification information is “ID = 200”, the second identification information is “ID = 000, 100, 300”, and the first identification information is the head (ID = 000), the position calculation unit 41 of the third control device 2C sets the first identification information (ID number) as the third rank.

  Next, the position calculation unit 41B determines that the self-position of the self-control device 2 is located not in the end but in the middle when the rank of the first identification information is not the highest or lowest. For example, as described above, since the rank of the first identification information (ID number) of the third control device 2C is third and not first or fourth, the position calculation unit 41B of the third control device 2C The self-position of the self-control device 2 is determined to be “intermediate”.

On the other hand, the position calculation unit 41B determines that the self-position of the self-control device 2 is “end” when the rank of the first identification information is the highest or lowest. For example, since the ID number of the first control device 2A is “ID = 000”, the ranking is first. In this case, the position calculation unit 41B of the first control device 2A determines that the self-position of the self-control device 2 is “termination”.
The connection setting unit 42B sets the connection of the termination resistor 4 of the self-control device 2 based on the position of the control device 2 calculated by the position calculation unit 41B. For example, the connection setting unit 42B of the third control device 2C outputs a non-connection command to the control unit 6 of the third control device 2C because the self position is not the end but an intermediate state, and the switch unit 5 is in the non-connection state. Hold on. On the other hand, the connection setting unit 42B of the fourth control device 2D outputs a connection command to the control unit 6 of the fourth control device 2D and holds the switch unit 5 in the connected state because the self-position is the end.

As described above, according to the third embodiment, the self-control is obtained by obtaining the self-position based on the first identification information (ID number) of the self-control device 2 and the second identification information (ID number) of the other control device 2. The terminal resistor 4 provided in the device 2 can be easily connected.
In the third embodiment described above, the position calculation unit 41B refers to all the acquired ID numbers and obtains the ranks of the ID numbers of the self-control device 2 for all the ID numbers. It is possible to omit and directly determine whether the self-position of the self-control device 2 is the end.
[Fourth Embodiment]
The fourth embodiment is an embodiment in which the switching operation of the switch unit 5 is performed based on a connectability instruction output from the outside of the in-vehicle network. Also in the description of the fourth embodiment, the description of the same configurations as those of the first to third embodiments described above will be omitted.

FIG. 8 is an overall view of the communication network showing the relationship between the in-vehicle network and the external network.
As shown in FIG. 8, in addition to the electronic device 2, an external device 20 and a communication device 21 that can be connected to the external device 20 are arranged in the communication network. Here, the external device 20 is a device arranged outside as viewed from the tractor 1 (vehicle-mounted network). The external device 20 includes, for example, an information terminal 20A that can be connected to the communication device 21 and a server 20B that can be connected to the information terminal 20A. Hereinafter, the information terminal 20A and the server 20B are taken as an example of the external device 20, and the description will proceed.

The communication device 21 is one of electronic devices mounted on the tractor 1 and has a wireless communication function. Specifically, the communication device 21 connects the in-vehicle network of the tractor 1 and an external network composed of the information terminal 20A, the server 20B, and the like, and is connected to the in-vehicle network of the tractor 1 by a connector or the like.
The communication device 21 includes a communication unit (communication module) 22 that performs wireless communication with the information terminal 20A, and a control unit 23 that controls the communication unit.

  The communication unit 22 performs wireless communication based on Wi-Fi (registered trademark) conforming to the IEEE 802.11 series which is a communication standard, or performs wireless communication based on a mobile phone communication network or the like. The communication unit 22 converts the received data (signal) into the communication method of the communication device 21 and outputs it to the control unit 23, or the data (signal) transmitted from the control unit 23 as an IEEE802.11 series communication method. Or change to the communication method of the mobile phone communication network and output to the external network. That is, the communication unit 22 receives the data (signal) transmitted from the information terminal 20A or the server 20B and outputs the data (signal) to the control unit 23, or the data (signal) output from the control unit 23 to the information terminal 20A or the server 20B. Send to.

  The information terminal 20A is configured by, for example, a smart phone (multifunctional mobile phone) or a tablet PC having a relatively high computing ability. The information terminal 20A also performs wireless communication with the communication device 21 (communication unit 22) by Wi-Fi (registered trademark) compliant with the IEEE 802.11 series which is a communication standard. The information terminal 20A can be connected to the server 20B via a mobile phone communication network or a data communication network.

The server 20B manages the connection of the termination resistor 4 in the in-vehicle network of the tractor 1, and for example, a maintenance company that sells the tractor 1, a manufacturing company that manufactures the tractor, or maintenance that performs maintenance of the tractor after the sale. It is installed in companies. The server 20B includes a first management database 25.
The first management database 25 has data in which the ID number of the electronic device (control device) 2 mounted on the tractor 1 and the connection permission / inhibition command of the termination resistor 4 are associated with each other. First, the first management database 25 will be described.

  As shown in FIG. 9, the first management database 25 includes a second setting table in which the ID number of the electronic device 2 and the connection permission / inhibition command of the termination resistor 4 are set for each tractor. That is, the first management database 25 associates identification information (machine identification information) for identifying the tractor 1, the ID number of the electronic device 2 mounted on the tractor 1 corresponding to the machine identification information, and the connection permission / inhibition command. The second setting table is provided.

The second setting table is created when the tractor 1 is manufactured, when the tractor is sold, or when the tractor is maintained. The second setting table is created by connecting a computer such as the information terminal 20A to the server 20B. This is done by connecting.
For example, it is assumed that a plurality of electronic devices 2 as shown in FIG. 10 are mounted on a tractor having machine identification information “M135-0154889”. In this case, as shown in FIGS. 9 and 10, among the plurality of electronic devices 2, the electronic device 2 in the leading end group connected to one end side (the leading end side) of the communication line 3 (for example, the electrons surrounded by the range A) The ID number of the device 2) is reduced, and the ID number of the electronic device 2 in the rear end group (for example, the electronic device 2 surrounded by the range B) connected to the other end side (rear end side) of the communication line 3 is increased. To do.

  The assignment to the front end group or the rear end group among the plurality of electronic devices 2 is an electronic that can be mounted on the tractor 1 at the stage of designing or manufacturing a tractor whose machine identification information is “M135-0154889”. It is desirable that the device 2 is assumed in advance and determined based on the assumed arrangement of the electronic device 2. That is, at the stage of designing or developing the tractor 1, the maximum number of electronic devices 2 that can be mounted on the tractor 1 and the arrangement of the electronic devices 2 are assumed in advance. And it is desirable to determine the electronic device 2 which belongs to a front end group or a rear end group based on arrangement | positioning of each electronic device 2. FIG.

Next, a connection command is set for the ID number of at least one of the electronic devices 2 belonging to the front end group (the electronic device 2 surrounded by the range A). Further, a connection command is set for at least one electronic device 2 (for example, ID = 1000) among the electronic devices 2 belonging to the rear end group (the electronic device 2 surrounded by the range B).
Specifically, as shown in FIG. 11, a computer such as the information terminal 20A is connected to the server 20B, and a setting screen Q1 is displayed on the computer. The setting screen Q1 displays a list of ID numbers of the electronic devices 2 mounted on the tractor 1 and a setting unit 26 that sets a connection permission / inhibition command associated with the ID number. For example, when “connection” is input in the setting unit 26 a corresponding to the ID number “ID = 000” of the electronic device 2, a connection command is set for ID = 000. Similarly, when “connection” is input in the setting unit 26b corresponding to the ID number of the electronic device 2 “ID = 1000”, a connection command is set for ID = 1000.

In this way, by connecting the computer to the server 20B, the connection setting of the termination resistor 4 of the electronic device 2 and the creation of the second setting table can be performed. Note that the connection availability setting (creation of the second setting table) is not limited to the above-described example, and other methods may be used.
After creating the second setting table, the information terminal 20A is connected to the server 20B, and the second setting table, that is, the ID number and the connection permission / inhibition command are transmitted to the information terminal 20A. Then, the ID number and the connection permission / inhibition command are transmitted from the information terminal 20A to the communication device 21. When receiving the ID number and the connection enable / disable command, the communication device 21 outputs the ID number and the connection enable / disable command to the control unit 23, and the control unit 23 outputs the ID number and the connection enable / disable command to the in-vehicle network. Then, when the ID number and the connection enable / disable command are input to the in-vehicle network, the control unit 6 of each electronic device 2 acquires the ID number corresponding to itself and the connection enable / disable command from the in-vehicle network. When a connection command is indicated, a connection signal is output to the switch unit 5. Moreover, the control part 6 of each electronic device 2 outputs a non-connection signal to the switch part 5 when the non-connection instruction is indicated in the connection permission / inhibition instruction.

  As described above, according to the fourth embodiment, the server 20B has the second setting table associated with the ID number and the connection enable / disable command, and therefore transmits the ID number and the connection enable / disable command to the tractor 1. Thus, the connection setting of the terminal resistor of the electronic device 2 mounted on the tractor 1 can be performed. Note that the server 20B has the second setting table, but instead, the information terminal 20A has the second setting table, and the information terminal 20A has the ID number shown in the second setting table and whether or not connection is possible. A command may be transmitted.

In the fourth embodiment described above, the connection setting of the termination resistor 4 is performed using the second setting table in which the ID number and the connection permission / inhibition command are associated. Instead, the termination resistance 4 is mounted on the tractor. Based on the ID number of the electronic device 2, the connection setting of the termination resistor 4 may be performed.
Hereinafter, modified examples of the fourth embodiment will be described. Note that the description of the same configuration as the above-described embodiment is omitted.

  As shown in FIG. 12, the server 20 </ b> B has a second management database 27 that stores the ID number of the electronic device 2 mounted on the tractor 1. Each ID number shown in the second management database 27 can be set, for example, when the tractor 1 is manufactured, or can be added or deleted when the tractor is sold or when the tractor is maintained. For example, when the tractor 1 is manufactured, when the tractor is sold, or when the tractor is maintained, a computer such as the information terminal 20A is connected to the server 20B, and a list of ID numbers corresponding to the predetermined tractor is connected to the computer. refer. Then, the ID number shown in the list can be deleted or the ID number can be added to the list using a computer.

Further, the server 20B includes setting means 40C that sets the connection of the terminating resistor based on the ID number of the second management database 27 described above. The setting unit 40C is configured by a program stored in the server 20B. The setting unit 40C includes a position calculation unit 41C and a connection setting unit 42C.
The position calculation unit 41C acquires the ID number indicated in the second management database 27, and obtains the position of the predetermined control device 2 on the in-vehicle network based on the acquired ID number. For example, when machine identification information is input to the server 20 </ b> B, the ID number of the electronic device 2 mounted on the tractor 1 corresponding to the machine identification information is acquired from the second management database 27. Then, the position calculation unit 41C refers to all the acquired ID numbers, and extracts the minimum ID number (for example, ID = 000) and the maximum ID number (for example, ID = 1000) from the ID numbers. To do.

In the position calculation unit 41C, the electronic device 2 corresponding to the minimum ID number (ID = 000) and the maximum ID number (ID = 1000) is located on the terminal side of the communication line 3 (terminal of the in-vehicle network). And decide.
The connection setting unit 42C creates a second setting table in which the ID number is associated with the connection permission / inhibition command. For example, since the electronic device 2 whose ID number is “000” and the electronic device 2 whose ID number is “1000” are located at the end, as shown in FIG. A second setting table in which a connection command is set for 000 and a connection command is set for ID = 1000 is created.

  After creating the second setting table, the connection setting unit 42C transmits the ID number and the connection permission / inhibition command to the information terminal 20A. Then, the ID number and the connection permission / inhibition command are transmitted from the information terminal 20A to the communication device 21. When receiving the ID number and the connection enable / disable command, the communication device 21 outputs the received ID number and the connection enable / disable command to the in-vehicle network. Then, when the ID number and the connection enable / disable command are input to the in-vehicle network, the control unit 6 of each electronic device 2 acquires the ID number corresponding to itself and the connection enable / disable command from the in-vehicle network. When a connection command is indicated, a connection signal is output to the switch unit 5. Moreover, the control part 6 of each electronic device 2 outputs a non-connection signal to the switch part 5 when the non-connection instruction is indicated in the connection permission / inhibition instruction.

As described above, according to the modification of the fourth embodiment, when the tractor is sold or the tractor is maintained, the in-vehicle network can be changed by simply changing the ID number stored in the second management database 27 by the server 20B or the like. The terminal resistor 4 of the electronic device 2 connected to can be easily set.
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims. In the embodiment described above, the identification information is desirably given to all electronic devices arranged in the in-vehicle network, but may be given to some electronic devices 2. In other words, not all electronic devices 2 need to have identification information. Further, the setting means 40A and 40B may be given to all the electronic devices 2 arranged in the in-vehicle network or may be given to some of the electronic devices 2. Similarly, the termination resistor 4 may be provided in all the electronic devices 2 arranged in the in-vehicle network, or may be provided in some electronic devices 2.

Furthermore, in the in-vehicle network, it is desirable to connect the terminal resistor of the electronic device located at the end to the in-vehicle network. However, the terminal resistor of the electronic device on the termination side (near the end) is actually connected to the in-vehicle network. Also good.
In the above-described embodiment, the compensation resistor 8 for compensating communication is provided in at least one electronic device 2, but instead of this, when communication is performed for the first time, that is, the termination resistor 4 is set. Before performing, it is possible to output a connection signal from the control unit 6 of the at least one electronic device 2 to the switch unit 5 and connect the termination resistor 4 to the in-vehicle network so that the termination resistor 4 functions as a compensation resistor. Good. In this case, it is desirable that the termination resistor 4 that has acted as a compensation resistor is disconnected after the termination resistor 4 is set.

1 Work implement (tractor)
2 Electronic equipment 2A 1st control apparatus 2B 2nd control apparatus 2C 3rd control apparatus 2D 4th control apparatus 3 Communication line 3a 1st communication line 3b 2nd communication line 4 Termination resistance 5 Switch part 6 Control part 7 Memory | storage part 8 Compensation Resistance 10 Traveling vehicle body 11 Engine 12 Transmission device 13 Three-point link mechanism 14 Working device 15 Cabin 16 Driver's seat 17 Display device 20 External device 20A Information terminal 20B Server 21 Communication device 22 Communication unit 23 Control unit 25 First management database 27 Second Management database 40A, 40B, 40C Setting means 41A, 41B, 41C Position calculation unit 42A, 42B, 42C Connection setting unit

Claims (6)

A plurality of electronic devices having termination resistors connectable to the vehicle-mounted network of the work machine and arranged in the vehicle-mounted network;
Based on the position of the electronic device on the in-vehicle network, setting means for setting the connection of the termination resistor of the electronic device;
A termination resistance management system comprising: The setting means includes
Based on the identification information given to each electronic device, a position calculation unit for obtaining the position on the in-vehicle network of the electronic device corresponding to the identification information;
A connection setting unit for setting a connection of a termination resistor based on the position calculated by the position calculation unit;
The termination resistance management system according to claim 1, further comprising:   The position calculation unit obtains identification information of each electronic device arranged in the in-vehicle network every predetermined time or when the number of electronic devices connected to the in-vehicle network changes, and corresponds to the identification information The terminal resistance management system according to claim 2, wherein a position of the electronic device on the vehicle-mounted network is obtained.   The connection setting unit outputs a connection command for a connection resistance of the electronic device to an electronic device located on a terminal side of the in-vehicle network among a plurality of electronic devices connected to the in-vehicle network. The terminal resistance management system according to claim 2 or 3,   At least one electronic device connected to the in-vehicle network has the setting unit, and the one electronic device having the setting unit outputs a termination resistance connection enable / disable command to another electronic device. The terminal resistance management system according to any one of claims 1 to 4,   The setting means is provided in an external device that can communicate with an electronic device connected to the in-vehicle network, and the external device outputs a termination resistor connection permission instruction to the electronic device arranged in the in-vehicle network. The termination resistance management system according to claim 1, wherein:

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