KR20190108962A - Apparatus for setting communication adress of digital temperature sensor - Google Patents

Abstract

The present invention relates to a communication address setting device for automatically setting communication addresses of a plurality of digital temperature sensors connected in a single wire manner. According to an embodiment of the present invention, the communication address setting device, in a communication address setting device connected in a single wire manner, comprises: a host controller generating an address and transmitting an address setting message including the generated address in one direction of the single wire; and a plurality of temperature sensors for receiving the address setting message from the host controller through the single wire, and extracting the address from the received address setting message to set a communication address and controls to turn on a switch thereof connected in one direction to a turn-on state.

Description

Communication address setting device of digital temperature sensor {APPARATUS FOR SETTING COMMUNICATION ADRESS OF DIGITAL TEMPERATURE SENSOR}

The present invention relates to a communication address setting device for automatically setting communication addresses of a plurality of digital temperature sensors connected by a single wire.

An air conditioning facility is a concept encompassing air conditioning and heating, ventilation, humidification and dehumidification, and air purification.

The air conditioning and heating equipment includes an outdoor unit and an indoor unit, and the outdoor unit includes a compressor for supplying and compressing a refrigerant and a heat exchanger for exchanging a refrigerant with outdoor air (outer air).

For the control of the outdoor unit, the temperature of the inlet and the outlet of the outdoor unit, the outside air temperature, the inlet and the outlet temperature of the heat exchanger are used. Accordingly, the outdoor unit is provided with a plurality of temperature sensors for measuring the temperature at each position of the outdoor unit.

The conventional main PCB controls the outdoor unit based on the measurement of each temperature sensor, which requires the conventional main PCB to receive the measurement from each temperature sensor.

More specifically, the conventional main PCB is connected to each temperature sensor through a channel, the main PCB controls the outdoor unit based on the measured value received through the channel.

Accordingly, the conventional main PCB should have the same number of channels as the temperature sensor, and if one or more temperature sensors are added to the air conditioning equipment, there is a problem in that the main PCB cannot be used due to the lack of the number of channels.

In addition, since the conventional main PCB must have as many channels as the number of temperature sensors, there is a problem in that the number of fastenings of the temperature sensors for each channel and the complexity of the wirings constituting each channel increase.

On the other hand, when the temperature sensor is a digital temperature sensor, the main PCB performs serial communication with each temperature sensor. More specifically, the main PCB communicates with each temperature sensor by sending data to the communication address of each temperature sensor. Therefore, the communication address of each temperature sensor must be stored in the main PCB in advance.

However, when a temperature sensor is added, changed, or removed at a site where an air conditioning facility is installed, the conventional main PCB cannot identify a communication address of a corresponding temperature sensor and thus cannot perform data communication with the temperature sensor.

On the other hand, in the communication between the main PCB and the temperature sensor, the communication speed is fixed to an arbitrary value set by the user, so that the main PCB and the temperature sensor perform unnecessarily low speed data communication regardless of the performance of the device and the communication environment. do.

As a result, it takes too much time to transmit data between the main PCB and the temperature sensor, which lowers the communication efficiency, slows down the control speed for each temperature sensor, and makes it difficult to monitor the target in real time.

The present invention aims to enable data communication between a host controller and a plurality of digital temperature sensors connected in a single wire manner.

It is also an object of the present invention to automatically set the communication addresses of a plurality of digital temperature sensors connected in a single wire manner.

In addition, an object of the present invention is to control the measurement value reception period differently according to the type of digital temperature sensor.

In addition, an object of the present invention is to set the communication speed differently according to the number of digital temperature sensors connected by a single wire method.

It is also an object of the present invention to set the communication speed at the maximum speed that a plurality of digital temperature sensors connected in a single wire manner can respond.

It is also an object of the present invention to identify whether a digital temperature sensor is connected in a single wire manner and whether or not the location of the failure occurs.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention, which are not mentioned above, can be understood by the following description, and more clearly by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The present invention enables data communication between a plurality of digital temperature sensors connected to a host controller connected in a single wire manner by controlling a switch connected to another adjacent temperature sensor after each temperature sensor sets its communication address. Can be.

According to the present invention, a host controller generates an initial address, transmits the generated address through a single wire, and continuously generates and transmits a new address as a setup completion message is received from a temperature sensor. By setting the communication address of the temperature sensor for transmitting the setup complete message to the host controller, it is possible to automatically set the communication address of the plurality of digital temperature sensors connected in a single wire manner.

In addition, the present invention transmits the request signal to the main temperature sensor a certain number of times in a first cycle, and then transmits the request signal to the second temperature cycle to all the temperature sensors connected to a single wire, so that the measurement value receiving cycle varies according to the type of the digital temperature sensor Can be controlled.

The present invention also identifies a communication speed corresponding to the number of temperature sensors with reference to a look-up table, and sets the identified communication speed as the communication speed between the host controller and the temperature sensor, thereby providing a method of digital temperature sensors connected in a single wire manner. Communication speed can be set differently depending on the number.

In addition, the present invention transmits a request signal while gradually controlling the communication speed from the highest communication speed to the lowest communication speed, and at a maximum speed at which the number of response signals to the request signal is equal to the number of the first identified temperature sensor. By setting the communication speed, it is possible to set the communication speed to the maximum speed that a plurality of digital temperature sensors connected in a single wire manner can respond.

In addition, the present invention determines whether a measurement value is provided from a plurality of temperature sensors and whether the continuous measurement value is equal to a preset temperature, thereby identifying whether the digital temperature sensor connected by a single wire method is broken and the location of the failure. Can be.

According to the present invention, by enabling data communication between a host controller and a plurality of digital temperature sensors connected by a single wire method, it is possible to shorten the process time by reducing the number of fastenings and wiring complexity in connecting a plurality of temperature sensors. There is an effect that additional temperature sensors can be connected without developing a separate PCB.

In addition, according to the present invention, by automatically setting the communication addresses of the plurality of digital temperature sensors connected in a single wire method, it is possible to perform data communication with each temperature sensor without knowing the communication address of the temperature sensor in advance.

In addition, according to the present invention, by controlling the measurement value receiving period differently according to the type of digital temperature sensor, there is an effect that can ensure the accuracy and real-time of the measured value for the measurement point with a large temperature change.

In addition, according to the present invention, by setting the communication speed differently according to the number of digital temperature sensors connected in a single wire method, communication defects can be prevented and communication efficiency can be improved.

In addition, according to the present invention, by setting the communication speed at the maximum speed that a plurality of digital temperature sensors connected in a single wire method can respond, the host controller and each temperature sensor has an effect of performing data communication at the optimum communication speed have.

In addition, according to the present invention, by identifying whether or not the failure location and the location of the digital temperature sensor connected in a single wire method, there is an effect that can determine whether the failure occurs in the temperature sensor and the part of the temperature sensor.

1 is a diagram illustrating a communication address setting device according to an embodiment of the present invention.
FIG. 2 is a diagram showing a connection relationship between the communication address setting device shown in FIG. 1; FIG.
3 is a diagram illustrating a second temperature sensor setting its address as the first temperature sensor controls the first switch.
4 is a flowchart illustrating a communication address setting method of a digital temperature sensor according to an exemplary embodiment of the present invention.
5 is a diagram illustrating a plurality of digital temperature sensors connected to a main PCB equipped with a host controller by a communication line and a power line.
FIG. 6 is a flow chart illustrating a method for setting a communication speed based on the number of digital temperature sensors first identified by the host controller and the number of response signals received at predetermined periods.

The above objects, features, and advantages will be described in detail with reference to the accompanying drawings, whereby those skilled in the art to which the present invention pertains may easily implement the technical idea of the present invention. In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

Hereinafter, a function and a structure of a communication address setting apparatus according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3.

1 is a view showing a communication address setting device according to an embodiment of the present invention, Figure 2 is a view showing a connection relationship of the communication address setting device shown in FIG.

3 is a diagram illustrating a state in which a second temperature sensor sets its own address as the first temperature sensor controls the first switch.

Referring to FIG. 1, the communication address setting apparatus 100 according to an embodiment of the present invention may include a host controller 110, a first temperature sensor 120, and a second temperature sensor 130. The address setting apparatus 100 illustrated in FIG. 1 is according to an exemplary embodiment, and the components thereof are not limited to the exemplary embodiment illustrated in FIG. 1, and some components may be added, changed, or deleted as necessary. have.

In the present invention, the plurality of digital temperature sensors may be respectively installed at an arbitrary measuring point of the air conditioning facility to measure the temperature of the measuring point.

The air conditioning system may include various facilities for performing an air conditioning function. For example, the air conditioning equipment may include air conditioning equipment, ventilation equipment, humidification and dehumidification equipment, air purification equipment, and the like.

The air conditioner may include an outdoor unit and an indoor unit, and the outdoor unit may include a compressor for supplying and compressing a refrigerant and a heat exchanger for exchanging the refrigerant with outdoor air (outside air).

In order to control the outdoor unit, the temperature of the inlet and the outlet of the outdoor unit, the outside temperature, the inlet and the outlet temperature of the heat exchanger may be used. Accordingly, the outdoor unit is provided with a plurality of digital temperature sensors for measuring the temperature at each position of the outdoor unit. Can be.

The present invention relates to an apparatus for setting communication addresses of a plurality of digital temperature sensors described above, and relates to an apparatus for setting communication addresses of a plurality of digital temperature sensors connected in a single wire (1-Wire) manner.

2, the host controller 110, the first temperature sensor 120, and the second temperature sensor 130 may be connected in a single wire manner. Here, the single wire does not mean one conductive wire, but may mean a conductive wire bundle including a transmission / reception line, a power line, and the like as described below. In addition, the first and second temperature sensors 120 and 130 may be included in the plurality of digital temperature sensors described above.

The host controller 110 is a controller that performs a process related to the control of the air conditioning equipment. The host controller 110 may be mounted on the main PCB 10 to collect temperature measurements from the first and second temperature sensors 120 and 130.

To this end, the host controller 110 may perform data communication with the first and second temperature sensors 120 and 130, and more specifically, perform data communication using a serial communication scheme. For example, the host controller 110 may perform data communication with the first and second temperature sensors 120 and 130 using the RS485 protocol (Recommended Standard 485).

In serial communication, each temperature sensor may have a unique communication address, and the host controller 110 may perform data communication with each temperature sensor by transmitting a signal to the communication address of each temperature sensor.

Accordingly, the communication address of each temperature sensor should be stored in the host controller 110 in advance. However, when a temperature sensor is added, changed, or removed at a site where an air conditioner is installed, the host controller 110 cannot determine a communication address of the corresponding temperature sensor and thus cannot perform serial communication with the corresponding temperature sensor. Occurs.

The present invention is an invention for solving the above-described problems, hereinafter, even if the host controller 110 does not know the communication addresses of the plurality of temperature sensors, a process of performing serial communication by giving a communication address to each temperature sensor This will be described in detail.

On the other hand, the temperature sensor to be described later means a digital temperature sensor, it can be described as a concept including the first temperature sensor 120 and the second temperature sensor 130 shown in FIG.

Referring to FIG. 2 again, the first temperature sensor 120 may mean a temperature sensor adjacent to the host controller 110 in one direction. In addition, the second temperature sensor 130 to be described later may mean a plurality of temperature sensors adjacent to the first temperature sensor 120 in one direction.

In other words, the first temperature sensor may refer to any one of the temperature sensors adjacent to the host controller 110. On the other hand, the second temperature sensor 130 does not mean any one of the temperature sensor, as shown in Figure 2 to include a temperature sensor 2 (Digital sensor 2) to a temperature sensor N (Digital sensor N) Can be used.

Accordingly, each of the temperature sensors 2 to N illustrated in FIG. 2 may operate in the same manner as the second temperature sensor 130 described later.

Referring to FIG. 3, the host controller 110 may transmit a first addressing message including a first address (address 1) in one direction. Here, one direction may be defined as a transmission direction of the host controller 110.

The first address address 1 may be any communication address generated by the host controller 110 and may be included in a frame configuring the first addressing message.

When the switch is provided inside the host controller 110, the host controller 110 controls the switch connected in one direction to an on state, and sets the first address to the first temperature sensor 120 connected in one direction through the switch. You can send a message.

In contrast, when no switch is provided inside the host controller 110, the host controller 110 is always connected to the first temperature sensor 120 to transmit the first addressing message to the first temperature sensor 120. It may be.

The first temperature sensor 120 connected in one direction adjacent to the host controller 110 receives the first addressing message, extracts a first address (address 1) from the received first addressing message, and transmits its own address. May be set to a first address (address 1).

More specifically, the first addressing message may be transmitted in a broadcast manner and received by the first temperature sensor 120. The first temperature sensor 120 extracts a first address (address 1) from a frame constituting the first addressing message, and extracts the extracted first address (address 1) from an internal memory (for example, an electrically erasable programmable read). -Only Memory (EEPROM).

The first address address 1 may be stored in a preset memory address, and the corresponding memory address may be a memory address corresponding to the communication address of the first temperature sensor 120.

Accordingly, the first temperature sensor 120 stores the first address (address 1) in a specific memory address of the internal memory, thereby setting its communication address to the first address (address 1).

When the communication address is set, the first temperature sensor 120 may transmit a setting complete message to the host controller 110.

Here, the setup complete message may include any message indicating that the first setup message has been received. For example, the setup complete message may be an acknowledgment message for the first address setup message.

Meanwhile, when the communication address is set, the first temperature sensor 120 may control the first switch 121 connected in one direction to the on state.

Referring to FIG. 3 again, the first temperature sensor 120 and the second temperature sensor 130 may be connected by the first switch 121. The first switch 121 may include any switching element for blocking or connecting the first temperature sensor 120 and the second temperature sensor 130, and may be, for example, a relay.

In FIG. 3, the first switch 121 is illustrated as being provided outside the first temperature sensor 120, but the first switch 121 may be provided inside the first temperature sensor 120.

After setting the communication address, the first temperature sensor 120 may provide a switching signal to the first switch 121 to control the first switch 121 in an on state. Accordingly, the host controller 110 may be connected to the second temperature sensor 130.

On the other hand, when the setting completion message transmitted from the first temperature sensor 120 is received by the host controller 110, the host controller 110 generates a second address (address 2), the second address (address 2) The included second address setting message may be transmitted in one direction.

The second address address 2 may be any communication address generated by the host controller 110 and may be set differently from the above-described first address address 1. For example, the host controller 110 may generate a second address (address 2) by subtracting or adding a preset address value to a previously generated first address (address 1).

The frame configuring the second addressing message may include a second address (address 2), and the second addressing message may be transmitted in a broadcast manner as in the first addressing message.

The second temperature sensor 130 connected adjacent to the first temperature sensor 120 in one direction receives the second address setting message through the first switch 121, and the second address message is received from the second address setting message. By extracting (address 2), it is possible to set its own communication address to the second address (address 2).

More specifically, the second address setting message transmitted by the broadcast method may be received by the second temperature sensor 130 for which the communication address is not set. The second temperature sensor 130 may extract a second address (address 2) from a frame constituting the second addressing message and store the extracted second address (address 2) in an internal memory.

The second address address 2 may be stored in a preset memory address, and the corresponding memory address may be a memory address corresponding to the communication address of the second temperature sensor 130.

Accordingly, like the first temperature sensor 120, the second temperature sensor 130 stores the second address (address 2) in a specific memory address of the internal memory, thereby storing its communication address in the second address (address 2). Can be set to

When the communication address is set, the second temperature sensor 130 may transmit a setting complete message to the host controller 110. Since the setting completion message has been described above, a detailed description thereof will be omitted.

Meanwhile, when the communication address is set, the second temperature sensor 130 may control the second switch 131 connected in one direction to the on state.

Referring to FIG. 3 again, the second temperature sensor 130 may be connected to another temperature sensor (not shown) adjacent in one direction by the second switch 131. The second switch 131 is a switching element that blocks or connects the second temperature sensor 130 and another temperature sensor adjacent in one direction, and may be provided outside or inside the second temperature sensor 130.

After setting the communication address, the second temperature sensor 130 may provide the switching signal to the second switch 131 to control the second switch 131 in the on state. Accordingly, the host controller 110 may be connected to another temperature sensor adjacent to the second temperature sensor 130 in one direction.

The address setting method of another temperature sensor adjacent to the second temperature sensor 130 in one direction may be the same as the address setting method of the second temperature sensor 130 described above. Accordingly, the host controller 110 can set a communication address to all temperature sensors connected in a single wire manner.

Hereinafter, an operation process of the host controller 110, the first temperature sensor 120, and the second temperature sensor 130 described above will be described in detail with reference to FIG. 4.

4 is a flowchart illustrating a communication address setting method of a temperature sensor according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the host controller 110 may first generate a first address (S110) and transmit a first address setting message including the first address in one direction (S120).

The first temperature sensor 120 adjacent to the host controller 110 in one direction receives the first address setting message, extracts the first address from the received first address setting message, and sets the first address as its own address. It may be (S210).

When the address setting is completed, the first temperature sensor 120 may transmit a setting completion message to the host controller 110 (S220), and control the first switch 121 connected in one direction to an on state (S230).

In this case, step S230 may be performed before step S220, may be performed after step S220, or may be performed simultaneously with step S220.

When the host controller 110 receives the setting completion message from the first temperature sensor 120, the host controller 110 may generate a second address having a communication address different from the first address (S130). Subsequently, the host controller 110 may transmit a second address setting message including the second address in one direction (S140).

The second temperature sensor 130 adjacent in one direction to the first temperature sensor 120 receives the second address setting message, extracts the second address from the received second address setting message, and sets the second address as its own address. Can be set to (S310).

When the address setting is completed, the second temperature sensor 130 may transmit a setting completion message to the host controller 110 (S320) and control the second switch 131 connected in one direction to an on state (S330). .

Similarly, step S330 may be performed before step S320, may be performed after step S320, or may be performed simultaneously with step S320.

As described above, the host controller 110 may continuously generate a new address as the setup completion message is received from any one of the temperature sensors.

In addition, each temperature sensor may set its own address to a newly generated address in the host controller 110, and then control on a switch connected in one direction.

Accordingly, another temperature sensor adjacent to one temperature sensor in one direction may receive an address setting message including a new address from the host controller 110 through a switch, and set its own address to the corresponding address.

Since the host controller 110 generates a new address in response to the setup complete message, if the setup complete message is not received from any temperature sensor, the host controller 110 may no longer generate a new address.

As described above, according to the present invention, by automatically setting the communication addresses of a plurality of digital temperature sensors connected in a single wire manner, it is possible to perform data communication with each temperature sensor without knowing the communication address of the temperature sensor in advance. There is.

In the conventional main PCB, the same number of channels as the temperature sensor should be provided, and if one or more temperature sensors are added to the air conditioning equipment, there is a problem in that the main PCB cannot be used due to the lack of the number of channels.

In addition, since the conventional main PCB should have as many channels as the number of temperature sensors, there is a problem in that the number of fastenings of the temperature sensor for each channel and the complexity of wirings constituting each channel increase.

However, as described above, the present invention enables data communication between a plurality of digital temperature sensors and a host controller 110 connected in a single wire manner, thereby reducing the number of fastenings and wiring complexity in connecting a plurality of temperature sensors, thereby reducing process time. In addition to shortening the circuit, temperature sensors can be added without additional PCB development.

Hereinafter, a method of controlling the communication speed and a method of diagnosing a failure of a temperature sensor by the host controller 110 will be described in detail with reference to FIGS. 5 and 6.

FIG. 5 is a diagram illustrating a plurality of temperature sensors connected to a main PCB equipped with a host controller by a communication line and a power line.

6 is a flowchart illustrating a method of setting a communication speed based on the number of firstly identified temperature sensors and the number of response signals received at regular intervals.

The host controller 110 may set communication addresses of all temperature sensors connected in a single wire manner through the address setting process described with reference to FIGS. 1 to 4.

Thereafter, the host controller 110 may transmit a request signal to each address set in the plurality of temperature sensors according to a predetermined period.

Referring to FIG. 5, in one example, the host controller 110 may be mounted on the main PCB 10 and may be connected to nine temperature sensors a to i in a single wire manner.

The single wire connected to the single channel 11 provided in the main PCB 10 may be composed of a power line V _DD , a ground line V _GND , and a communication line T _x / R _x . A single wire is connected to the signal conversion module connected to each sensor, and the signal conversion module is connected to the sensor through a power line (V _DD ), a ground line (V _GND ), a transmission line (T _x ) and a reception line (R _x ). It can be connected with.

The wiring shown in FIG. 5 is only for the purpose of illustrating the invention, and the wiring connecting the host controller 110 and each sensor is not limited to the example shown in FIG. 5.

The host controller 110 may sequentially transmit request signals to respective temperature sensors at predetermined intervals.

In other words, the host controller 110 may transmit a request signal to the sensor a in the first transmission period, transmit a request signal to the sensor b in the second transmission period, and request the sensor c in the third transmission period. You can send a signal.

In this way, the host controller 110 may sequentially transmit request signals to the last sensor i, the temperature sensor.

The request signal is a message for requesting a measurement value of each temperature sensor, and the request signal may include a communication address of the previously set temperature sensor. For example, when the communication address of the sensor a is set to address 1, the request signal may include request data requesting a measurement value of the sensor a and address 1 which is the communication address of the sensor a.

The plurality of temperature sensors may transmit the measured value to the host controller 110 in response to the request signal transmitted from the host controller 110.

Each temperature sensor determines whether the communication address included in the request signal is the same as its own communication address, and if it is the same, transmits its measurement value to the host controller 110 in response to the request signal. It may not respond to the request signal.

As described above, since the plurality of request signals are transmitted to different temperature sensors at regular intervals, the host controller 110 may receive measurement values from different temperature sensors at predetermined intervals.

For example, you can receive measurement a from sensor a in the first reception period, you can receive measurement b from sensor b in the second reception period, and measure c from sensor c in the third reception period. Can be received.

In this manner, the host controller 110 may sequentially collect all the measured values measured by the sensors a to i.

Meanwhile, the host controller 110 transmits the request signal to the address of the main temperature sensor among the plurality of temperature sensors in a preset number of times according to the first period, and then sends the request signal to all addresses of the plurality of temperature sensors according to the second period. I can send it.

Here, the main temperature sensor is a temperature sensor having a relatively large change in the measured value over time, and may be predetermined by the user.

For example, when a plurality of temperature sensors are installed in a heating / heating facility, a temperature sensor measuring a temperature of a discharge port for discharging air into a room and a temperature sensor measuring a temperature of a suction port for sucking outside air may be preset as main temperature sensors. Can be.

The plurality of temperature sensors may transmit their identification information to the host controller 110 together with the above-described measured values. The host controller 110 may determine whether the received identification information is the same as the identification information of the main temperature sensor with reference to the internal memory. To this end, identification information of the main temperature sensor may be previously stored in the internal memory of the host controller 110.

If it is determined that the identification information received from the at least one temperature sensor is the same as the identification information of the main temperature sensor, the host controller 110 may identify the corresponding temperature sensor as the main temperature sensor.

The host controller 110 may transmit a request signal to the main temperature sensor according to the first period. The host controller 110 may count the number of request signals transmitted in the first period, and if the counted number is the same as a preset number, the host controller 110 may transmit the request signal according to the second period to all temperature sensors connected by a single wire. .

To this end, the request signal transmitted in the first period may include the communication address of the main temperature sensor, and the request signal transmitted in the second period may include the communication addresses of all the temperature sensors.

In this case, the first period may be set shorter than the second period. In other words, the host controller 110 quickly collects the measured values from the main temperature sensor according to the first period, and if the measured values are collected over a certain amount, the host controller 110 collects the measured values from all the temperature sensors according to the second period. Can be collected.

As described above, according to the present invention, by controlling the reception period of the measured value differently according to the type of the digital temperature sensor, it is possible to secure the accuracy and real-time of the measured value for the measurement point having a large temperature change.

Meanwhile, the host controller 110 and the plurality of temperature sensors perform data communication at a specific communication speed. When the plurality of temperature sensors support different communication speeds, a request signal transmitted at a specific speed does not support the speed. It may not be received by the temperature sensor. For example, the request signal transmitted at 19,200 bps may not be received by a temperature sensor supporting up to 9,600 bps.

In addition, when a plurality of temperature sensors are connected to one host controller 110, the communication line impedance between the host controller 110 and each of the temperature sensors may increase, so that the host controller 110 and the temperature sensors are limited. Data communication can be performed only within the communication speed.

Accordingly, the host controller 110 may set a communication speed according to the number of the plurality of temperature sensors.

The host controller 110 may determine the number of the plurality of temperature sensors as the number of reception of the setting completion message.

As described above, the temperature sensor that has set its own communication address to the address generated by the host controller 110 may transmit a setting completion message to the host controller 110.

In other words, each temperature sensor connected to the host controller 110 through a single wire may transmit a setting completion message to the host controller 110 once.

Accordingly, the number of setting completion messages received by the host controller 110 may be equal to the number of temperature sensors connected to the host controller 110.

The host controller 110 may count the number of receptions each time a setup completion message is received, and if the setup completion message is no longer received, the host controller 110 may set the number of pre-set setup completion messages to the number of temperature sensors.

The host controller 110 may set a communication speed in inverse proportion to the number of temperature sensors. In other words, the host controller 110 may set the communication speed slower as the number of temperature sensors increases, and set the communication speed faster as the number of temperature sensors decrease.

More specifically, the host controller 110 may set a communication speed to a communication speed corresponding to the number of temperature sensors with reference to a look-up table (LUT) stored in a memory.

For example, when the host controller 110 and the temperature sensor are connected as shown in FIG. 5, a lookup table as shown in Table 1 below may be stored in the memory of the host controller 110 in advance.

Number of temperature sensors Communication speed 1 to 2 56,200 bps 3 to 5 38,400 bps 6 to 7 19,200 bps 8 to 9 9,600 bps

The host controller 110 can set the communication speed to 56,200bps if the number of temperature sensors is 1 to 3, and if the number of temperature sensors is 3 to 5, the host controller 110 sets the communication speed to 38,400. Can be set to bps.

In addition, the host controller 110 may set the communication speed to 19,200bps if the number of temperature sensors is 6 to 7, and may set the communication speed to 9,600bps if the number of temperature sensors is 8 to 9.

Accordingly, according to the present invention, by setting the communication speed differently according to the number of digital temperature sensors connected in a single wire method, communication defects can be prevented and communication efficiency can be improved.

Unlike the above, the host controller 110 may first identify the number of the plurality of temperature sensors, and then transmit the request signal while gradually controlling the communication speed from the highest communication speed to the lowest communication speed with reference to the memory. Thereafter, the host controller 110 may set a communication speed at a maximum speed at which the number of response signals to the request signal is the same as the number of the plurality of temperature sensors initially identified.

As described above, the host controller 110 may initially identify the number of temperature sensors by counting the number of setup completion messages.

After the number of temperature sensors is first identified, the host controller 110 may transmit the request signal while gradually controlling the communication speed of the request signal from the maximum communication speed according to a predetermined period with reference to the memory.

Communication speed information may be previously stored in the internal memory of the host controller 110, and the host controller 110 may identify the highest communication speed, which is the highest communication speed supported by the host controller 110, with reference to the communication speed information. Can be.

The host controller 110 may first transmit a request signal at the highest communication speed, and count the number of response signals corresponding to the request signal. Thereafter, the host controller 110 may transmit the request signal at a communication rate lower than the communication rate of the previous period for every period in which the request signal is transmitted, and count the number of response signals for the corresponding request signal.

The host controller 110 may set, as the communication speed, the maximum speed at which the speed is the highest among the communication speeds in which the number of response signals received in each cycle is counted equal to the number of temperature sensors first identified.

For example, when a total of six temperature sensors are connected to the host controller 110, the host controller 110 may initially identify the number of temperature sensors as six. On the other hand, the host controller 110 may support the four communication speeds described in Table 1 above.

In this case, the host controller 110 may first transmit a request signal to the six temperature sensors at 56,200 bps, and count the number of response signals to the corresponding request signal. Subsequently, the host controller 110 may transmit request signals to the six temperature sensors at 38,400, 19,200, and 9,600 bps according to each cycle, and count the number of response signals for each request signal.

The number of response signals counted at each communication speed by the host controller 110 may be as shown in Table 2 below.

Cycle Communication speed Number of response signals One 56,200 bps 2 2 38,400 bps 3 3 19,200 bps 6 4 9,600 bps 6

Referring to [Table 2], the host controller 110 may identify communication speeds counted as 19,200 bps and 9,600 bps such that the number of response signals received in each period is the same as the number of the firstly identified temperature sensors.

The host controller 110 may set a relatively high speed of 19,200bps as the new communication speed among the identified communication speeds.

Referring to FIG. 6, referring to the above-described operation of the host controller 110, the host controller 110 first identifies the number of digital temperature sensors (S610), and then controls each temperature sensor while gradually controlling the communication speed. In step S620, a request signal may be transmitted.

Thereafter, when a response signal to the request signal is received, the number of the received response signals may be counted, and whether the counted number and the number of the firstly identified temperature sensors are the same (S630).

As a result of the comparison, when the number of the received response signals is smaller than the number of the first identified temperature sensors, the request signal may be transmitted while continuously controlling the communication speed to be slow (S620).

On the other hand, if the number of the received response signal is the same as the number of the first identified temperature sensor, the communication speed may be set to the controlled communication speed in the current period (S640).

As described above, according to the present invention, the host controller 110 and each temperature sensor communicate data at an optimum communication speed by setting a communication speed at a maximum speed at which a plurality of digital temperature sensors connected in a single wire method can respond. This has the effect of performing.

Meanwhile, the host controller 110 may diagnose a failure of the plurality of temperature sensors according to the measured values provided from the plurality of temperature sensors.

More specifically, the host controller 110 may determine that the reception line of the at least one temperature sensor is disconnected when a measurement value is not provided from the at least one temperature sensor.

The host controller 110 may be provided with a buffer for temporarily storing measured values received from each sensor. The temporary memory is initialized at each reception period of the response signal, and a value stored in the buffer at initialization of the buffer may be a reset value, for example, zero.

Referring back to FIG. 5, the host controller 110 may sequentially transmit a request signal from the sensor a to the sensor i, and identify the measured value received at each sensor by referring to the value stored in the buffer.

For example, when the receiving line of the sensor d is disconnected, the sensor d does not receive the request signal from the host controller 110 and thus cannot transmit a response signal to the host controller 110. Accordingly, the measured value measured by the sensor d may not be stored in the buffer and the value stored in the buffer may be initialized to a reset value.

The host controller 110 may determine that the reception line of the sensor d is disconnected when the value stored in the buffer is a reset value in the reception period of the response signal for the sensor d.

In addition, the host controller 110 may determine that the transmission line of any one of the temperature sensors is disconnected when the measurement value is not provided from all temperature sensors connected to one of the temperature sensors in one direction.

As shown in FIG. 4, any one temperature sensor may be connected to an adjacent temperature sensor in one direction through a switch provided in its transmission line.

Accordingly, when the transmission line of any one of the temperature sensors is disconnected due to a switch failure or the like, all the temperature sensors connected in one direction with the corresponding temperature sensor may not receive the request signal transmitted from the host controller 110.

Accordingly, the host controller 110 may not receive the measured values measured by all the sensors connected to the temperature sensor in which the transmission line is disconnected in one direction. In this case, the host controller 110 may determine that the transmission line of the last temperature sensor at which the measurement value is received is disconnected.

For example, when the transmission line of the sensor d shown in FIG. 5 is disconnected, the sensors e through i do not receive the request signal from the host controller 110, and thus the host controller 110 receives the sensor a through the sensor. Only the measured value of d can be received.

At this time, the host controller 110 may determine that the transmission line of the sensor d, which is located last in one direction, among the temperature sensors from which the measured value is received, as a disconnection.

In addition, the host controller 110 may determine that a short circuit has occurred in the at least one temperature sensor when the measured value provided in a continuous cycle from the at least one temperature sensor is equal to the preset short circuit temperature.

As shown in FIG. 5, the sensor may be provided with a plurality of power lines and communication lines. For example, each sensor may be provided with a power line V _DD , a ground line V _GND , a transmission line T _x , and a reception line R _x .

At this time, if a short circuit occurs in at least two of each line, the measured value measured by the sensor may be fixed to a specific temperature.

For example, if a short circuit occurs in the transmission line T _x and the ground line V _{GND of} the sensor, the measured value measured by the sensor may be fixed at 70 ^° C. In addition, when a short circuit occurs between the transmission line T _x and the power line V _{DD of} the sensor, the measured value measured by the sensor may be fixed to 29 ^° C.

As described above, the short circuit of at least two lines changes the measured value of the sensor to a fixed value, and the fixed value determined by the experiment is set to the short circuit temperature and stored in the internal memory of the host controller 110 in advance.

However, since the measured value of the actual sensor may be equal to the preset short-circuit temperature, the host controller 110 may determine that the measured value provided in a continuous cycle from the specific sensor, that is, the measured value continuously provided for a predetermined period or more is the same as the short-circuit temperature. It can be determined that a short circuit has occurred in the sensor.

As described above, according to the present invention, by identifying whether the digital temperature sensor is connected in a single wire manner and whether or not the location of the failure occurs, it is possible to determine which part of the temperature sensor and the corresponding temperature sensor has failed. .

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by.

Claims (12)

In the communication address setting device connected by a single wire,
A host controller for generating an addressing message and transmitting the generated addressing message in one direction of the single wire; And
Receiving the address setting message from the host controller through the single wire, extracting an address included in the received address setting message, setting a communication address, and then controlling the switch connected to the one direction in its on state; Including a plurality of temperature sensors
Communication address setting device.
The method of claim 1,
The plurality of temperature sensors
A communication temperature setting including a first temperature sensor connected to the host controller in one direction and connected to the first temperature sensor through a switch connected to the first temperature sensor in the one direction; Device.
The method of claim 1,
The plurality of temperature sensors set their communication address to the extracted address, and then transmit a setting completion message to the host controller.
And the host controller generates an addressing message including a new address in response to the setting complete message.
The method of claim 1,
The host controller transmits a request signal to each communication address set in the plurality of temperature sensors at regular intervals,
And the plurality of temperature sensors transmits measurement values to the host controller in response to the request signal.
The method of claim 4, wherein
The host controller
After transmitting the request signal to the communication address of the main temperature sensor of the plurality of temperature sensors in a predetermined number of times according to a first period, the request signal is transmitted to all communication addresses of the plurality of temperature sensors according to the second period. Communication address setting device.
The method of claim 3,
The host controller
And determining the number of the plurality of temperature sensors as the number of reception of the setting completion message.
The method of claim 6,
The host controller
Communication address setting device for setting the communication speed in accordance with the number of the plurality of temperature sensors.
The method of claim 1,
The host controller
After first identifying the number of the plurality of temperature sensors, a request signal is transmitted to the plurality of temperature sensors while gradually controlling the communication speed from the highest communication speed to the lowest communication speed with reference to a memory, and responds to the request signal. And setting the communication speed at the maximum speed at which the number of signals is equal to the number of the plurality of initially identified temperature sensors.
The method of claim 1,
The host controller
And a communication address setting device for diagnosing a failure of the plurality of temperature sensors according to the measured values provided from the plurality of temperature sensors.
The method of claim 9,
The host controller
And determining that the receiving line of the at least one temperature sensor is disconnected when the measured value is not provided from at least one of the plurality of temperature sensors.
The method of claim 9,
The host controller
And when the measured value is not provided from all temperature sensors connected to any one of the plurality of temperature sensors in the one direction, the transmission line of the one temperature sensor is determined to be disconnected.
The method of claim 9,
The host controller
And determining that a short circuit has occurred in the at least one temperature sensor if the measured values provided in a continuous cycle from at least one temperature sensor of the plurality of temperature sensors are equal to a preset short circuit temperature.

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