JP2020057992A - Communication device - Google Patents

Abstract

To provide a communication device capable of suppressing a rise in temperature caused by communication operation while preventing throughput related to wireless communication from declining.SOLUTION: A communication device includes: a plurality of transmission amplifiers for amplifying a transmission signal; a temperature sensor for detecting vicinity temperature of the transmission amplifiers; and control means for performing control so as to perform time division transmission in which the plurality of transmission amplifiers amplify the transmission signal by time division when the vicinity temperature detected by the temperature sensor is equal to or more than a predetermined threshold value.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a communication device.

  2. Description of the Related Art In recent years, communication devices such as a wireless LAN (Local Area Network) module mounted on an in-vehicle device such as a car navigation device tend to increase power consumption and calorific value along with higher speed communication and higher functionality. On the other hand, in such a communication device, with the diversification of installation locations, a demand for an operation-guaranteed temperature is increasing so that the communication device can operate stably even in a high-temperature environment. Therefore, a technology for suppressing a temperature rise due to a communication operation has been devised for a communication device.

  For example, in the following Patent Document 1, in a mobile wireless device, when the temperature of the transmission unit reaches a predetermined reference temperature, the transmission operation of the transmission unit is stopped or intermittently operated to prevent the temperature of the transmission unit from rising. Techniques are disclosed.

  Patent Document 2 below discloses a technique in a mobile phone, which switches to a communication method that generates less heat according to the temperature detected by a temperature detector.

JP-A-10-190487 JP 2008-244603 A

  However, in the related art, in order to suppress a rise in temperature, it is necessary to shorten the time for performing a communication operation or switch to a communication method that generates less heat, and the throughput related to wireless communication decreases. That is, in the related art, it is not possible to suppress a temperature rise due to a communication operation while suppressing a decrease in throughput related to wireless communication.

  The communication device according to one embodiment includes a plurality of transmission amplifiers for amplifying a transmission signal, a temperature sensor for detecting a temperature near the transmission amplifier, and a plurality of transmission amplifiers when the temperature near the temperature sensor is equal to or higher than a predetermined threshold. Control means for controlling the amplifier to perform time-division transmission in which the transmission signal is amplified in a time-division manner.

  According to one embodiment, it is possible to provide a communication device capable of suppressing a temperature rise due to a communication operation while suppressing a decrease in throughput related to wireless communication.

FIG. 2 is a diagram illustrating a circuit configuration of a communication device according to the first embodiment. FIG. 4 is a diagram illustrating an example of a transmission operation by the communication device according to the first embodiment. FIG. 3 is a diagram illustrating a circuit configuration of a communication device according to a second embodiment. The figure which shows an example of the transmission operation | movement by the communication apparatus which concerns on 2nd Embodiment. The figure which shows the circuit structure of the communication apparatus which concerns on 3rd Embodiment. The figure which shows an example of the transmission operation | movement by the communication apparatus which concerns on 3rd Embodiment. FIG. 9 is a diagram illustrating a circuit configuration of a communication device according to a fourth embodiment. The figure which shows an example of the transmission operation | movement by the communication apparatus which concerns on 4th Embodiment. The figure which shows the circuit structure of the communication apparatus which concerns on 5th Embodiment. The figure which shows an example of the transmission operation | movement by the communication apparatus which concerns on 5th Embodiment. The figure which shows the circuit structure of the communication apparatus which concerns on 6th Embodiment. The figure which shows an example of the transmission operation | movement by the communication apparatus which concerns on 6th Embodiment. The figure which shows the circuit structure of the communication apparatus which concerns on 7th Embodiment. The figure which shows an example of the transmission operation | movement by the communication apparatus which concerns on 7th Embodiment.

  Hereinafter, an embodiment will be described with reference to the drawings.

[First Embodiment]
First, a first embodiment will be described with reference to FIGS. FIG. 1 is a diagram illustrating a circuit configuration of a communication device 100A according to the first embodiment. The communication device 100A illustrated in FIG. 1 is a device that can perform wireless communication with another externally provided communication device 200 using a predetermined wireless communication method such as Wi-Fi. In particular, the communication device 100A includes two antennas ANT1 and ANT2, and performs high-speed wireless communication with the communication device 200 by performing MIMO communication using the two antennas ANT1 and ANT2. It is possible. As the communication device 100A, for example, a wireless LAN module mounted on an in-vehicle device such as a car navigation device can be cited. Examples of the communication device 200 include a portable terminal such as a smartphone possessed by a user, a personal computer having a communication function, a base station capable of communicating with a car navigation device, and the like.

  As shown in FIG. 1, the communication device 100A includes a communication circuit 110A, a SW (switch) circuit 120, a transmission amplifier PA1, a transmission amplifier PA2, an antenna ANT1, an antenna ANT2, a temperature sensor 130, and a control circuit 140A. Although not shown, the communication device 100A may further include a receiving antenna, a receiving amplifier, and the like in addition to the components described above.

  The communication circuit 110A performs various processes on transmission data (baseband signals) supplied from a higher-level application device (not shown) in accordance with a wireless communication system standard (for example, IEEE 802.11b / g / n). (E.g., error correction coding, modulation, filtering, DA conversion, etc.), a transmission signal (RF (Radio Frequency) signal) for wirelessly transmitting the transmission data from the transmission data. ). Then, the communication circuit 110A outputs the transmission signal to the SW circuit 120. As the communication circuit 110A, for example, an IC (Integrated Circuit) can be used.

  The SW (switch) circuit 120 switches the output destination of the transmission signal output from the communication circuit 110A to the transmission amplifier PA1 or the transmission amplifier PA2 under the control of the control circuit 140A. As the SW circuit 120, for example, an electronic circuit using a semiconductor switching element such as a MOSFET (Metal Oxide Semiconductor Field Effect Transistor) can be used.

  The transmission amplifier PA1 amplifies the transmission signal output from the SW circuit 120 and outputs the transmission signal to the antenna ANT1. The antenna ANT1 is connected to the transmission amplifier PA1, and transmits the transmission signal output from the transmission amplifier PA1 to the communication device 200. As the transmission amplifier PA1, for example, a high-frequency power amplifier can be used.

  The transmission amplifier PA2 amplifies the transmission signal output from the SW circuit 120 and outputs the transmission signal to the antenna ANT2. The antenna ANT2 is connected to the transmission amplifier PA2, and transmits the transmission signal output from the transmission amplifier PA2 to the communication device 200. As the transmission amplifier PA2, for example, a high-frequency power amplifier can be used.

  Temperature sensor 130 is provided near transmission amplifier PA1. Temperature sensor 130 detects a temperature near transmission amplifier PA1 and outputs a temperature signal indicating the temperature to control circuit 140A. As the temperature sensor 130, for example, a resistance temperature detector, a linear resistor, a thermistor, or the like can be used.

  The control circuit 140A controls the SW circuit 120 based on the temperature in the vicinity of the transmission amplifier PA1 detected by the temperature sensor 130, thereby controlling the connection destination of the communication circuit 110A (that is, the transmission signal output from the communication circuit 110A). Output destination) is switched to the transmission amplifier PA1 or the transmission amplifier PA2. Thereby, the control circuit 140A performs the transmission operation by the transmission amplifier PA1 (the transmission operation in which the transmission amplifier PA1 amplifies the transmission signal) and the transmission operation by the transmission amplifier PA2 (the transmission operation in which the transmission amplifier PA2 amplifies the transmission signal). Switch). As the control circuit 140A, for example, an IC can be used.

  For example, when the temperature in the vicinity of the transmission amplifier PA1 is lower than a predetermined first threshold th1 (hereinafter, referred to as “normal time”), the control circuit 140A maintains a state in which the transmission amplifier PA1 is connected to the communication circuit 110A. The SW circuit 120 is controlled so as to perform the operation. Thereby, the control circuit 140A normally performs only the transmission operation using the antenna ANT1 by the transmission amplifier PA1.

  On the other hand, when the temperature in the vicinity of transmission amplifier PA1 is equal to or higher than first predetermined threshold th1 (hereinafter, referred to as “high temperature”), control circuit 140A outputs the connection destination of communication circuit 110A (that is, output from communication circuit 110A). The SW circuit 120 is controlled so that the output destination of the transmission signal is switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time-division manner. Thus, at a high temperature, the control circuit 140A alternately performs the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 in a time-division manner. At this time, the control circuit 140A switches the SW circuit 120 at predetermined time intervals, for example. Thus, the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 are performed alternately at predetermined time intervals. Hereinafter, alternately performing the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 in a time division manner is also referred to as “time division transmission between the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2”. .

  Further, when the temperature near the transmission amplifier PA1 becomes equal to or higher than the first threshold th1 and then becomes lower than the second threshold th2, the control circuit 140A returns to the normal operation. That is, the control circuit 140A controls the SW circuit 120 such that the state where the transmission amplifier PA1 is connected to the communication circuit 110A is maintained. For example, the control circuit 140A uses a lower second threshold th2 than the first threshold th1. This prevents the control circuit 140A from frequently switching between normal operation and high temperature operation when the temperature near the transmission amplifier PA1 fluctuates up and down around the first threshold th1. Can be.

  In the communication device 100A, each of the plurality of components illustrated in FIG. 1 may be provided on the same substrate, or may be provided over a plurality of substrates. In the communication device 100A, the function of the control circuit 140A may be provided as an additional function to the communication circuit 110A. Further, each of the plurality of components shown in FIG. 1 may be configured in one IC, and in this case, the temperature near the transmission amplifier may indicate the temperature of the transmission amplifier in the IC.

  FIG. 2 is a diagram illustrating an example of a transmission operation by the communication device 100A according to the first embodiment. As shown in FIG. 2, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is less than a predetermined first threshold th1 (normal time), the state where the transmission amplifier PA1 is connected to the communication circuit 110A. SW circuit 120 is controlled such that is maintained. As a result, in the communication device 100A, only the transmission operation using the antenna ANT1 by the transmission amplifier PA1 is normally performed.

  On the other hand, as shown in FIG. 2, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is equal to or higher than a predetermined first threshold th1 (at high temperature), the connection destination of the communication circuit 110A is the transmission amplifier PA1. The SW circuit 120 is controlled so as to be alternately switched in a time division manner between the transmission amplifier PA2 and the transmission amplifier PA2. Thus, in the communication device 100A, at the time of high temperature, time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 is performed.

  As a result, in the communication device 100A, at the time of high temperature, the heat generating portion related to the transmission of the transmission signal is distributed to the transmission amplifier PA1 and the transmission amplifier PA2. In particular, in the communication device 100A, when the temperature is high, each of the transmission amplifier PA1 and the transmission amplifier PA2 intermittently performs a transmission operation, so that the temperature rise of each of the transmission amplifier PA1 and the transmission amplifier PA2 is suppressed. Becomes

  Further, in the communication device 100A, as shown in FIG. 2, the total time of the operation time of the transmission amplifier PA1 and the operation time of the transmission amplifier PA2 per predetermined period T at high temperature is equal to the predetermined period in the normal time. The operation time per T is equal to the operation time of the transmission amplifier PA1. That is, in the communication device 100A, the amount of transmission data per predetermined period T at high temperature is equal to the amount of transmission data per predetermined period T at normal time.

  Therefore, according to the communication device 100A according to the first embodiment, it is possible to suppress a decrease in throughput associated with the communication operation of the transmission amplifiers PA1 and PA2, while suppressing a decrease in throughput related to wireless communication.

  Note that, when the temperature distribution in the communication device 100A is substantially uniform, the communication device 100A equalizes the transmission operation time of the transmission amplifier PA1 and the transmission operation time of the transmission amplifier PA2 at a high temperature, so that the transmission amplifier PA1 The near temperature and the near temperature of the transmission amplifier PA2 can be made substantially equal. However, the present invention is not limited to this. For example, when the temperature distribution in the communication device 100A is biased due to an external factor, or the heat generation amount per unit time of the transmission amplifier PA1 and the heat generation amount per unit time of the transmission amplifier PA2. The communication device 100A adjusts the transmission operation time of the transmission amplifier PA1 and the transmission operation time of the transmission amplifier PA2 when the temperature is high (that is, shortens the transmission operation time for the one that easily generates heat) when there is an individual difference between By doing so, the bias of the temperature distribution in the communication device 100A may be suppressed. Similarly, communication device 100A outputs the output level of the transmission signal output from transmission amplifier PA1 at a high temperature (hereinafter, also referred to as the “output level of transmission amplifier PA1”) and the output of the transmission signal output from transmission amplifier PA2. By adjusting the level (hereinafter, also referred to as the “output level of the transmission amplifier PA2”) (that is, lowering the output level of the one that easily generates heat), the bias of the temperature distribution in the communication device 100A can be suppressed. Good.

[Second embodiment]
Next, a second embodiment will be described with reference to FIGS. Hereinafter, regarding the communication device 100B according to the second embodiment, changes from the communication device 100A according to the first embodiment will be described. Note that, regarding the communication device 100B, the same components as those of the communication device 100A are denoted by the same reference numerals as those of the communication device 100A, and description thereof will be omitted.

  FIG. 3 is a diagram illustrating a circuit configuration of a communication device 100B according to the second embodiment. As shown in FIG. 3, the communication device 100B includes one antenna ANT1 in place of the two antennas ANT1 and ANT2, further includes a SW circuit 125 (an example of a “second switch circuit”), and The communication device 100A is different from the communication device 100A in that a control circuit 140B is provided instead of the control circuit 140A.

  The SW circuit 125 is provided on the output side of the transmission amplifiers PA1 and PA2. The SW circuit 125 switches the connection destination of the antenna ANT1 (that is, the output source of the transmission signal input to the antenna ANT1) to the transmission amplifier PA1 or PA2 under the control of the control circuit 140B. As the SW circuit 125, for example, a semiconductor switching element such as a MOSFET can be used.

  The control circuit 140B controls the SW circuit 120 based on the temperature near the transmission amplifier PA1 to change the connection destination of the communication circuit 110A (that is, the output destination of the transmission signal output from the communication circuit 110A). Switch to PA1 or transmission amplifier PA2. Further, the control circuit 140B controls the SW circuit 125 in synchronization with the control of the SW circuit 120, thereby changing the connection destination of the antenna ANT1 (that is, the output source of the transmission signal input to the antenna ANT1) to the transmission amplifier. Switch to PA1 or transmission amplifier PA2. Thereby, control circuit 140B switches between the transmission operation by transmission amplifier PA1 and the transmission operation by transmission amplifier PA2.

  Specifically, the control circuit 140B maintains the state in which the transmission amplifier PA1 is connected to the communication circuit 110A when the temperature near the transmission amplifier PA1 is lower than the first threshold th1 (normal time). Next, while controlling the SW circuit 120, the SW circuit 125 is controlled such that the state where the transmission amplifier PA1 is connected to the antenna ANT1 is maintained. As a result, the control circuit 140B normally performs only the transmission operation using the antenna ANT1 by the transmission amplifier PA1.

  On the other hand, when the temperature near the transmission amplifier PA1 is equal to or higher than the first threshold th1 (when the temperature is high), the control circuit 140B outputs the connection destination of the communication circuit 110A (that is, the output of the transmission signal output from the communication circuit 110A). Is switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time-division manner, and the connection destination of the antenna ANT1 (that is, the transmission signal input to the antenna ANT1) is controlled. The SW circuit 125 is controlled such that the output source) is alternately switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time-division manner. At this time, when switching the connection destination of the communication circuit 110A to the transmission amplifier PA1, the control circuit 140B switches the connection destination of the antenna ANT1 to the transmission amplifier PA1. Conversely, when switching the connection destination of the communication circuit 110A to the transmission amplifier PA2, the control circuit 140B switches the connection destination of the antenna ANT1 to the transmission amplifier PA2. Thus, at a high temperature, the control circuit 140B performs time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2.

  FIG. 4 is a diagram illustrating an example of a transmission operation by the communication device 100B according to the second embodiment. As shown in FIG. 4, when the temperature in the vicinity of the transmission amplifier PA1 detected by the temperature sensor 130 is less than a first threshold value th1 (normal time), the state where the transmission amplifier PA1 is connected to the communication circuit 110A. , And the SW circuit 125 is controlled so as to maintain the state where the transmission amplifier PA1 is connected to the antenna ANT1. Accordingly, in the communication device 100B, only the transmission operation using the antenna ANT1 by the transmission amplifier PA1 is normally performed.

  On the other hand, as shown in FIG. 4, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is equal to or higher than a predetermined first threshold th1 (when the temperature is high), the connection destination of the communication circuit 110A is the transmission amplifier PA1. The SW circuit 120 is controlled so as to alternately switch between the transmission amplifier PA2 and the transmission amplifier PA2, and the connection destination of the antenna ANT1 is alternately switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time division manner. , The SW circuit 125 is controlled. Accordingly, in the communication device 100B, at the time of high temperature, time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 is performed.

  Thus, the communication device 100B disperses the heat generating portion related to the transmission of the transmission signal to the transmission amplifier PA1 and the transmission amplifier PA2 at the time of high temperature and transmits the transmission signal at the time of high temperature, similarly to the communication device 100A according to the first embodiment. Since each of the amplifier PA1 and the transmission amplifier PA2 can perform the transmission operation intermittently, local heat generation of the transmission amplifiers PA1 and PA2 can be suppressed. Further, the communication device 100B, like the communication device 100A according to the first embodiment, can make the transmission data amount per predetermined period T at high temperature equal to the transmission data amount per predetermined period T at normal time. Therefore, it is possible to suppress a decrease in throughput related to wireless communication.

  In particular, since the communication device 100B can alternately use (shared) the transmission amplifiers PA1 and PA2 by using the one antenna ANT1 as the shared antenna by the SW circuit 125, the communication device 100B uses the transmission antenna by using the one antenna ANT1. Time-division transmission by PA1 and PA2 can be performed. Such a configuration of the communication device 100B is particularly suitable in a case where a sufficient space for disposing the antenna cannot be secured.

[Third embodiment]
Next, a third embodiment will be described with reference to FIGS. Hereinafter, regarding the communication device 100C according to the third embodiment, changes from the communication device 100A according to the first embodiment will be described. Note that, regarding the communication device 100C, the same components as those of the communication device 100A are denoted by the same reference numerals as those of the communication device 100A, and description thereof will be omitted.

  FIG. 5 is a diagram illustrating a circuit configuration of a communication device 100C according to the third embodiment. As shown in FIG. 5, the communication device 100C includes two communication circuits 110B and 110C in place of the communication circuit 110A, a point in which the SW circuit 120 is not provided, and a control circuit 140C in place of the control circuit 140A. It differs from the communication device 100A in that it is provided.

  The communication circuits 110B and 110C perform various processes (for example, error correction coding, DA conversion, modulation, and filtering) on transmission data supplied from a higher-level application device (not shown). Then, a transmission signal for wirelessly transmitting the transmission data is generated from the transmission data. Then, communication circuit 110B outputs the transmission signal to transmission amplifier PA1. On the other hand, communication circuit 110C outputs the transmission signal to transmission amplifier PA2.

  The control circuit 140C controls the communication circuits 110B and 110C based on the temperature in the vicinity of the transmission amplifier PA1, thereby outputting the transmission signal from the communication circuit 110B to the transmission amplifier PA1 and transmitting the transmission amplifier PA2 from the communication circuit 110C. And the output of the transmission signal to the control. Thereby, control circuit 140C can switch between the transmission operation by transmission amplifier PA1 and the transmission operation by transmission amplifier PA2.

  Specifically, the control circuit 140C outputs a transmission signal from the communication circuit 110B to the transmission amplifier PA1 when the temperature near the transmission amplifier PA1 is lower than the first threshold th1 (normal time). It controls the communication circuit 110B. As a result, the control circuit 140C normally performs only the transmission operation using the antenna ANT1 by the transmission amplifier PA1.

  On the other hand, when the temperature in the vicinity of the transmission amplifier PA1 is equal to or higher than the first threshold th1 (when the temperature is high), the control circuit 140C time-divides the output destination of the transmission signal between the transmission amplifier PA1 and the transmission amplifier PA2. The communication circuits 110B and 110C are controlled so as to be alternately switched. That is, at high temperature, the control circuit 140C alternates the output timing of the transmission signal from the communication circuit 110B to the transmission amplifier PA1 and the output timing of the transmission signal from the communication circuit 110C to the transmission amplifier PA2 in a time-division manner. The communication circuits 110B and 110C are controlled so as to be switched. Thus, at the time of high temperature, control circuit 140C performs time-division transmission of the transmission operation by transmission amplifier PA1 and the transmission operation by transmission amplifier PA2.

  FIG. 6 is a diagram illustrating an example of a transmission operation by the communication device 100C according to the third embodiment. As shown in FIG. 6, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is less than a predetermined first threshold th1 (normal time), a transmission signal is output from the communication circuit 110B to the transmission amplifier PA1. Thus, the communication circuit 110B is controlled. Thereby, in the communication device 100C, only the transmission operation using the antenna ANT1 by the transmission amplifier PA1 is normally performed.

  On the other hand, as shown in FIG. 6, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is equal to or higher than a predetermined first threshold th1 (at high temperature), transmission from the communication circuit 110B to the transmission amplifier PA1 is performed. The communication circuits 110B and 110C are controlled such that the output of the signal and the output of the transmission signal from the communication circuit 110C to the transmission amplifier PA2 are alternately switched in a time-division manner. Thus, in the communication device 100C, at the time of high temperature, time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 is performed.

  As a result, the communication device 100C disperses the heat generating portion related to the transmission of the transmission signal to the transmission amplifier PA1 and the transmission amplifier PA2 at a high temperature and transmits the transmission signal at the time of high temperature, similarly to the communication device 100A according to the first embodiment. Since each of the amplifier PA1 and the transmission amplifier PA2 can perform the transmission operation intermittently, local heat generation of the transmission amplifiers PA1 and PA2 can be suppressed. Further, the communication device 100C can make the amount of transmission data per predetermined period T at high temperature equal to the amount of transmission data per predetermined period T at normal time, similarly to the communication device 100A according to the first embodiment. Therefore, it is possible to suppress a decrease in throughput related to wireless communication.

  In particular, since the communication device 100C includes the two communication circuits 110B and 110C, the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 can be performed independently. Time-division transmission by the transmission amplifiers PA1 and PA2 can be performed without using the first embodiment).

  In the present embodiment, the two communication circuits 110B and 110C are described as separate circuits for easy understanding of the functions. However, for example, the functions of the communication circuits 110B and 110C may be replaced by the functions of the control circuit 140C. They may be integrated in one IC.

[Fourth embodiment]
Next, a fourth embodiment will be described with reference to FIGS. Hereinafter, regarding the communication device 100D according to the fourth embodiment, changes from the communication device 100A according to the first embodiment will be described. Regarding the communication device 100D, the same components as those of the communication device 100A are denoted by the same reference numerals as those of the communication device 100A, and description thereof will be omitted.

  FIG. 7 is a diagram illustrating a circuit configuration of a communication device 100D according to the fourth embodiment. As shown in FIG. 7, the communication device 100D differs from the communication device 100A in that it has two temperature sensors 130A and 130B instead of the temperature sensor 130, and that it has a control circuit 140D instead of the control circuit 140A. .

  In the present embodiment, the transmission amplifier PA1 and the transmission amplifier PA2 are arranged apart from each other (at a predetermined interval). The temperature sensor 130A is provided near the transmission amplifier PA1 (for example, a position closer to the transmission amplifier PA1 than the distance between the transmission amplifier PA1 and the transmission amplifier PA2). Temperature sensor 130A detects a temperature near transmission amplifier PA1, and outputs a temperature signal indicating the temperature to control circuit 140D. Temperature sensor 130B is provided near transmission amplifier PA2 (for example, a position closer to transmission amplifier PA2 than the distance between transmission amplifier PA1 and transmission amplifier PA2). Temperature sensor 130B detects a temperature near transmission amplifier PA2, and outputs a temperature signal indicating the temperature to control circuit 140D. As the temperature sensors 130A and 130B, for example, a resistance temperature detector, a linear resistor, a thermistor, or the like can be used.

  The control circuit 140D determines that both the temperature near the transmission amplifier PA1 detected by the temperature sensor 130A and the temperature near the transmission amplifier PA2 detected by the temperature sensor 130B are less than a predetermined first threshold th1 (hereinafter, referred to as “threshold”). In the “normal state”, the SW circuit 120 is controlled so as to maintain the state where the transmission amplifier PA1 is connected to the communication circuit 110A. Thus, the control circuit 140D normally performs only the transmission operation using the antenna ANT1 by the transmission amplifier PA1.

  On the other hand, the control circuit 140D determines that one of the temperature in the vicinity of the transmission amplifier PA1 detected by the temperature sensor 130A and the temperature in the vicinity of the transmission amplifier PA2 detected by the temperature sensor 130B is equal to or higher than a predetermined first threshold th1. (Hereinafter referred to as “high temperature”), the connection destination of the communication circuit 110A (that is, the output destination of the transmission signal output from the communication circuit 110A) is time division between the transmission amplifier PA1 and the transmission amplifier PA2. The SW circuit 120 is controlled so as to be alternately switched. Thus, at a high temperature, the control circuit 140D performs time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2.

  Here, when the temperature is high, the control circuit 140D adjusts the operation time of the transmission amplifier PA1 and the operation time of the transmission amplifier PA2 based on the temperature difference between the temperature near the transmission amplifier PA1 and the temperature near the transmission amplifier PA2. I do. That is, when the temperature near the transmission amplifier PA1 is different from the temperature near the transmission amplifier PA2, the operation time of the transmission amplifier PA1 and the operation time of the transmission amplifier PA2 are changed according to the temperature difference. , SW circuit 120. Accordingly, when the distance from the heat source 300 to the transmission amplifier PA1 is different from the distance from the heat source 300 to the transmission amplifier PA2, the time ratio according to the distance from the heat source 300 to the transmission amplifiers PA1 and PA2 is determined. It is possible to efficiently suppress heat generation in accordance with the temperature distribution in the inside.

  For example, when the distance L1 from the heat source 300 to the transmission amplifier PA1 is equal to the distance L2 from the heat source 300 to the transmission amplifier PA2, that is, when the temperature near the transmission amplifier PA1 is substantially equal to the temperature near the transmission amplifier PA2. In addition, the control circuit 140D controls the SW circuit 120 such that the operation time of the transmission amplifier PA1 and the operation time of the transmission amplifier PA2 in the predetermined cycle T are equal.

  Further, for example, when the distance L1 from the heat source 300 to the transmission amplifier PA1 is longer than the distance L2 from the heat source 300 to the transmission amplifier PA2, that is, the temperature near the transmission amplifier PA1 is lower than the temperature near the transmission amplifier PA2. In this case, the control circuit 140D controls the SW circuit 120 such that the operation time of the transmission amplifier PA1 in the predetermined cycle T is longer than the operation time of the transmission amplifier PA2.

  Further, for example, when the distance L1 from the heat source 300 to the transmission amplifier PA1 is shorter than the distance L2 from the heat source 300 to the transmission amplifier PA2, that is, the temperature near the transmission amplifier PA1 is higher than the temperature near the transmission amplifier PA2. In this case, the control circuit 140D controls the SW circuit 120 such that the operation time of the transmission amplifier PA1 in the predetermined cycle T is shorter than the operation time of the transmission amplifier PA2.

  FIG. 8 is a diagram illustrating an example of a transmission operation by the communication device 100D according to the fourth embodiment. As shown in FIG. 8, when both the temperature near the transmission amplifier PA1 and the temperature near the transmission amplifier PA2 are less than the first threshold th1 (normal state), the transmission amplifier PA1 is connected to the communication circuit 110A. The SW circuit 120 is controlled so as to maintain the state in which it is in the state. As a result, in the communication device 100D, only the transmission operation using the antenna ANT1 by the transmission amplifier PA1 is normally performed.

  On the other hand, as shown in FIG. 8, when one of the temperature in the vicinity of the transmission amplifier PA1 and the temperature in the vicinity of the transmission amplifier PA2 is equal to or higher than a predetermined first threshold th1 (high temperature), the connection destination of the communication circuit 110A ( That is, the SW circuit 120 is controlled such that the output destination of the transmission signal output from the communication circuit 110A is alternately switched in a time-division manner between the transmission amplifier PA1 and the transmission amplifier PA2. Accordingly, in the communication device 100D, at the time of high temperature, time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 is performed.

  As a result, the communication device 100D disperses the heat generating portion related to the transmission of the transmission signal to the transmission amplifier PA1 and the transmission amplifier PA2 at a high temperature and transmits the transmission signal at the time of high temperature, similarly to the communication device 100A according to the first embodiment. Since each of the amplifier PA1 and the transmission amplifier PA2 can perform the transmission operation intermittently, local heat generation of the transmission amplifiers PA1 and PA2 can be suppressed. Further, the communication device 100D can make the transmission data amount per predetermined period T at high temperature equal to the transmission data amount per predetermined period T at normal time, similarly to the communication device 100A according to the first embodiment. Therefore, it is possible to suppress a decrease in throughput related to wireless communication.

  Here, in the example shown in FIG. 7, the distance L1 from the heat source 300 to the transmission amplifier PA1 is longer than the distance L2 from the heat source 300 to the transmission amplifier PA2. That is, in this example, under the influence of the heat source 300, the transmission amplifier PA2 is more likely to generate heat (the neighborhood temperature is more likely to rise) than the transmission amplifier PA1. For this reason, in the example shown in FIG. 8, at the time of high temperature, the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA1 are performed such that the operation time of the transmission amplifier PA1 in the predetermined period T is longer than the operation time of the transmission amplifier PA2. The operation by the amplifier PA2 is alternately performed in a time-division manner at different time ratios.

  Thus, the transmission amplifier PA2 provided relatively close to the heat source 300 (that is, easily generates heat) is provided relatively far from the heat source 300 (that is, hardly generates heat). By making the operation time shorter than that of the transmission amplifier PA1, it is possible to suppress an increase in the vicinity temperature.

  That is, the communication device 100D adjusts the operation time of each of the transmission amplifiers PA1 and PA2 in accordance with the distances L1 and L2 from the heat source 300 to the transmission amplifiers PA1 and PA2, so that the amount of heat generated by the transmission amplifier PA1 and the transmission amplifier The control can be performed so that the calorific value of PA2 is substantially the same. Therefore, according to the communication device 100D, it is possible to suppress the bias of the temperature distribution in the communication device 100D caused by the difference in the distance from the heat source 300 to the transmission amplifiers PA1 and PA2.

  In the communication device 100D, the operation time of each of the transmission amplifiers PA1 and PA2 at the time of high temperature is preferably set in advance in the control circuit 140D in advance based on, for example, simulation results.

  In the communication device 100D, the operating time of each of the transmission amplifiers PA1 and PA2 at the time of high temperature depends on, for example, the current nearby temperature of each of the transmission amplifiers PA1 and PA2 detected by each of the temperature sensors 130A and 130B. Thus, the adjustment may be made dynamically by the control circuit 140D.

  For example, at a high temperature, the current temperature near the transmission amplifier PA1 is changed to the current temperature near the transmission amplifier PA2 in spite of the fact that the transmission amplifiers PA1 and PA2 perform time division transmission according to the distances L1 and L2. If it becomes higher, the ratio of the operation time of the transmission amplifier PA1 may be reduced.

  On the contrary, at the time of high temperature, the temperature near the current transmission amplifier PA2 becomes close to the current transmission amplifier PA1 in spite of performing the time division transmission by the transmission amplifiers PA1 and PA2 according to the distances L1 and L2. When the temperature becomes higher than the temperature, the ratio of the operation time of the transmission amplifier PA2 may be reduced.

  When the distance L1 from the heat source 300 to the transmission amplifier PA1 is longer than the distance L2 from the heat source 300 to the transmission amplifier PA2, the control circuit 140D controls the transmission amplifier The gain of the transmission amplifier PA1 and the gain of the transmission amplifier PA2 may be controlled such that the output level of PA1 is higher than the output level of transmission amplifier PA2. Thereby, it is easier to further suppress the bias of the temperature distribution in the communication device 100D caused by the difference in the distance from the heat source 300 to the transmission amplifiers PA1 and PA2.

  Conversely, when the distance L1 from the heat source 300 to the transmission amplifier PA1 is shorter than the distance L2 from the heat source 300 to the transmission amplifier PA2, the control circuit 140D performs transmission in addition to adjusting the operation time described above. The gain of the transmission amplifier PA1 and the gain of the transmission amplifier PA2 may be controlled such that the output level of the amplifier PA1 is lower than the output level of the transmission amplifier PA2.

[Fifth Embodiment]
Next, a fifth embodiment will be described with reference to FIGS. 9 and 10. Hereinafter, regarding the communication device 100E according to the fifth embodiment, changes from the communication device 100A according to the first embodiment will be described. Note that, regarding the communication device 100E, the same components as those of the communication device 100A are denoted by the same reference numerals as those of the communication device 100A, and description thereof will be omitted.

  FIG. 9 is a diagram illustrating a circuit configuration of a communication device 100E according to the fifth embodiment. As shown in FIG. 9, the communication device 100E is different from the communication device 100A in that a control circuit 140E is provided instead of the control circuit 140A.

  As shown in FIG. 9, communication circuit 110 </ b> A receives a received signal strength in wireless communication between antenna ANT <b> 1 and communication device 200, that is, an RSSI (Received Signal Strength Indicator) value (hereinafter, “first RSSI value”). ) And an RSSI value in a wireless communication between the antenna ANT2 and the communication device 200 (hereinafter, referred to as a “second RSSI value”). The RSSI value detection unit 112 includes, for example, a circuit including a receiving circuit and a detection circuit connected to each of the antennas ANT1 and ANT2 (detects the signal strength of a signal transmitted from the communication device 200 to the communication device 100E), A circuit that receives and stores information on the RSSI value transmitted from the communication device 200 (detects the signal strength of a signal transmitted from the communication device 100E to the communication device 200) or the like can be used.

  The control circuit 140E performs the SW circuit based on the temperature near the transmission amplifier PA1, the first RSSI value detected by the RSSI value detection unit 112, and the second RSSI value detected by the RSSI value detection unit 112. By controlling 120, the connection destination of communication circuit 110A (that is, the output destination of the transmission signal output from communication circuit 110A) is switched to transmission amplifier PA1 or transmission amplifier PA2. Thereby, control circuit 140E switches between the transmission operation by transmission amplifier PA1 and the transmission operation by transmission amplifier PA2.

  When the temperature in the vicinity of the transmission amplifier PA1 is lower than the first threshold th1 (normal time), the control circuit 140E controls the SW circuit 120 to maintain the state where the transmission amplifier PA1 is connected to the communication circuit 110A. Control. Thus, the control circuit 140E normally performs only the transmission operation using the antenna ANT1 by the transmission amplifier PA1.

  On the other hand, when the temperature near the transmission amplifier PA1 is equal to or higher than the predetermined first threshold th1 (when the temperature is high), the control circuit 140E outputs the connection destination of the communication circuit 110A (that is, the output of the transmission signal output from the communication circuit 110A). Is switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time-division manner. Thus, at a high temperature, the control circuit 140E performs time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2.

  Here, the control circuit 140E controls each of the transmission amplifiers PA1 and PA2 according to the first RSSI value detected by the RSSI value detection unit 112 and the second RSSI value detected by the RSSI value detection unit 112. And the output levels of the transmission amplifiers PA1 and PA2.

  For example, when the first RSSI value is equal to the second RSSI value, the control circuit 140E sets the operation time of the transmission amplifier PA1 and the operation time of the transmission amplifier PA2 in the predetermined cycle T to be equal. It controls the SW circuit 120. At the same time, the control circuit 140E controls the transmission amplifiers PA1 and PA2 so that the output level of the transmission amplifier PA1 is equal to the output level of the transmission amplifier PA2.

  Further, for example, when the first RSSI value is larger than the second RSSI value, that is, the transmission signal transmitted from the antenna ANT1 is transmitted to the communication device 200 more than the transmission signal transmitted from the antenna ANT2. When the environment is easy to reach, the control circuit 140E controls the SW circuit 120 so that the operation time of the transmission amplifier PA1 in the predetermined cycle T is longer than the operation time of the transmission amplifier PA2. At the same time, the control circuit 140E controls the transmission amplifiers PA1 and PA2 such that the output level of the transmission amplifier PA1 is lower than the output level of the transmission amplifier PA2.

  Further, for example, when the first RSSI value is smaller than the second RSSI value, that is, the transmission signal transmitted from the antenna ANT1 is transmitted to the communication device 200 more than the transmission signal transmitted from the antenna ANT2. If the environment is difficult to reach, the control circuit 140E controls the SW circuit 120 so that the operation time of the transmission amplifier PA1 in the predetermined cycle T is shorter than the operation time of the transmission amplifier PA2. At the same time, the control circuit 140E controls the transmission amplifiers PA1 and PA2 such that the output level of the transmission amplifier PA1 is higher than the output level of the transmission amplifier PA2.

  FIG. 10 is a diagram illustrating an example of a transmission operation by the communication device 100E according to the fifth embodiment. As shown in FIG. 10, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is less than a predetermined first threshold th1 (normal time), the state where the transmission amplifier PA1 is connected to the communication circuit 110A. SW circuit 120 is controlled such that is maintained. As a result, in the communication device 100E, normally, only the transmission operation using the antenna ANT1 by the transmission amplifier PA1 is performed.

  On the other hand, as shown in FIG. 10, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is equal to or higher than a predetermined first threshold th1 (at high temperature), the connection destination of the communication circuit 110A (that is, the communication circuit The SW circuit 120 is controlled such that the output destination of the transmission signal output from 110A is alternately switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time-division manner. Accordingly, in the communication device 100E, at the time of high temperature, time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 is performed.

  Accordingly, the communication device 100E disperses the heat generating portion related to the transmission of the transmission signal to the transmission amplifier PA1 and the transmission amplifier PA2 at the time of high temperature and transmits the transmission signal at the time of high temperature, similarly to the communication device 100A according to the first embodiment. Since each of the amplifier PA1 and the transmission amplifier PA2 can perform the transmission operation intermittently, local heat generation of the transmission amplifiers PA1 and PA2 can be suppressed. Further, the communication device 100E can make the transmission data amount per predetermined period T at the time of high temperature equal to the transmission data amount per predetermined period T at the normal time, similarly to the communication device 100A according to the first embodiment. Therefore, it is possible to suppress a decrease in throughput related to wireless communication.

  Here, in the example illustrated in FIG. 9, the first RSSI value detected by the RSSI value detection unit 112 is smaller than the second RSSI value detected by the RSSI value detection unit 112. That is, the transmission signal transmitted from the antenna ANT1 is less likely to reach the communication device 200 than the transmission signal transmitted from the antenna ANT2.

  For this reason, in the example shown in FIG. 10, at the time of high temperature, the output level of the transmission amplifier PA1 is higher than the output level of the transmission amplifier PA2. As a result, in the communication device 100E, the decrease in the first RSSI value can be compensated for by increasing the output level of the transmission amplifier PA1, so that stable wireless communication by the antenna ANT1 can be secured.

  In the example shown in FIG. 10, when the temperature is high, the transmission operation of the transmission amplifier PA1 and the transmission amplifier PA1 are performed such that the operation time of the transmission amplifier PA1 in the predetermined cycle T is shorter than the operation time of the transmission amplifier PA2. The operation by the PA2 is performed alternately in a time sharing manner at different time ratios. As a result, in the communication device 100E, the temperature near the transmission amplifier PA1 is easily increased by increasing the output level of the transmission amplifier PA1, but by shortening the operation time of the transmission amplifier PA1, the vicinity of the transmission amplifier PA1 is reduced. A rise in temperature can be suppressed.

  In the example shown in FIG. 10, the output level of the transmission amplifier PA2 is lower than the output level of the transmission amplifier PA1, but the wireless communication using the antenna ANT2 originally has a sufficient second RSSI value. Since the communication device 200 is expected to receive the transmission signal from the communication device 100E with a sufficient strength, stable wireless communication can be continuously performed without being affected by the influence.

  Further, in the example shown in FIG. 10, the operation time of the transmission amplifier PA2 is longer than the operation time of the transmission amplifier PA1, but the unit time of the transmission amplifier PA2 is reduced due to the lowered output level of the transmission amplifier PA2. Since the calorific value per unit area is reduced, it is possible to suppress an increase in the temperature near the transmission amplifier PA2.

  As described above, the communication device 100E can change the operation time and the output level of each of the transmission amplifiers PA1 and PA2 according to the first RSSI value and the second RSSI value. Thereby, the communication device 100E can secure the stability of wireless communication by each of the antennas ANT1 and ANT2, and controls the temperature near the transmission amplifier PA1 and the temperature near the transmission amplifier PA2 to be almost the same. can do. Therefore, according to the communication device 100E, it is possible to suppress a local temperature rise of the transmission amplifiers PA1 and PA2.

  In the communication device 100E, the operation time and the output level of each of the transmission amplifiers PA1 and PA2 at the time of high temperature are preferably set in advance in the control circuit 140E in advance based on, for example, simulation results. .

  In the communication device 100E, the output level of each of the transmission amplifiers PA1 and PA2 at the time of high temperature is controlled by the control circuit 140E according to, for example, the current RSSI value (first RSSI value and second RSSI value). It may be made to adjust appropriately.

  For example, when the current first RSSI value is less than a predetermined value at a high temperature, the output level of the transmission amplifier PA1 is increased, and the operation time of the transmission amplifier PA1 is shortened accordingly. You may. Conversely, when the current first RSSI value is sufficiently larger than the predetermined value at the time of high temperature, the output level of the transmission amplifier PA1 is lowered, and the operating time of the transmission amplifier PA1 is prolonged accordingly. You may make it.

  Similarly, when the current second RSSI value is less than the predetermined value at a high temperature, the output level of the transmission amplifier PA2 is increased, and the operating time of the transmission amplifier PA2 is shortened accordingly. It may be. Conversely, when the current second RSSI value is sufficiently larger than the predetermined value at the time of high temperature, the output level of the transmission amplifier PA2 is lowered, and the operating time of the transmission amplifier PA1 is accordingly prolonged. You may make it.

  In the present embodiment, when the amount of heat generated at a high temperature falls within an allowable range by performing time-division transmission, the transmission amplifiers PA1 and PA1 are used in accordance with the first RSSI value and the second RSSI value. Only the output level of each of PA2 may be changed. Also, depending on the type of communication, there is a case where the probability that a transmission signal cannot be transmitted can be reduced only by shortening the operation time of the transmission operation with the lower RSSI value, and the stability of wireless communication can be ensured. In such a case, only the operation time of each of the transmission amplifiers PA1 and PA2 may be changed at a high temperature. That is, in the present embodiment, at least one of the operation time and the output level of each of the transmission amplifiers PA1 and PA2 is changed based on the first RSSI value and the second RSSI value at a high temperature. Good.

[Sixth embodiment]
Next, a sixth embodiment will be described with reference to FIGS. Hereinafter, regarding the communication device 100F according to the sixth embodiment, changes from the communication device 100A according to the first embodiment will be described. Regarding the communication device 100F, the same components as those of the communication device 100A are denoted by the same reference numerals as those of the communication device 100A, and description thereof will be omitted.

  FIG. 11 is a diagram illustrating a circuit configuration of a communication device 100F according to the sixth embodiment. As shown in FIG. 11, the communication device 100F includes a communication circuit 110D instead of the communication circuit 110A, does not include the SW circuit 120, and includes a control circuit 140F instead of the control circuit 140A. Different from the communication device 100A. Although not illustrated, the communication device 100F may further include a circuit (a receiving antenna, a receiving amplifier, and the like) other than the above-described components.

  The communication circuit 110D has two output terminals capable of outputting a transmission signal. One of the two output terminals is connected to the transmission amplifier PA1, and the other is connected to the transmission amplifier PA2. The communication circuit 110D can output two types of transmission signals from each of the two output terminals or output one type of transmission signal from the two output terminals simultaneously. In addition, the communication circuit 110D can selectively output one type of transmission signal from one of the two output terminals.

  The control circuit 140F controls the communication circuit 110D when the temperature near the transmission amplifier PA1 is lower than the first threshold value th1 (normal time), so that the transmission operation is performed on the transmission amplifier PA1 and the transmission amplifier PA2. Let them be done at the same time. That is, the control circuit 140F controls the communication circuit 110D to perform parallel transmission of a transmission signal using two transmission amplifiers and two antennas. Such a transmission operation is suitable when performing MIMO (Multi Input Multi Output) communication or the like.

  For example, when receiving an instruction from the control circuit 140F to perform MIMO communication, the communication circuit 110D transmits two types of transmission signals having different phases and amplitudes to a first transmission signal for the transmission amplifier PA1 and a transmission signal for the transmission amplifier PA2. Is output from each of the two output terminals. Then, the communication circuit 110D simultaneously outputs the first transmission signal to the transmission amplifier PA1 and outputs the second transmission signal to the transmission amplifier PA2. As a result, the transmission operation of the first transmission signal using the antenna ANT1 by the transmission amplifier PA1 and the transmission operation of the second transmission signal using the antenna ANT2 by the transmission amplifier PA2 are performed simultaneously. Can be performed. The description of the receiving operation corresponding to the MIMO communication is omitted.

  On the other hand, when the temperature near the transmission amplifier PA1 is equal to or higher than the predetermined first threshold th1 (at high temperature), the control circuit 140F instructs the communication circuit 110D to perform time-division SISO (Single Input Single Output) communication. put out. When receiving an instruction from the control circuit 140F to perform time division SISO communication, the communication circuit 110D selectively outputs one type of transmission signal from two output terminals in a time division manner. That is, the control circuit 140F controls the communication circuit 110D to perform time-division transmission of a transmission signal using two transmission amplifiers and two antennas.

  FIG. 12 is a diagram illustrating an example of a transmission operation by the communication device 100F according to the sixth embodiment. As shown in FIG. 12, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is lower than a predetermined first threshold th1 (normal time), the communication circuit 110D transmits the first transmission signal to the transmission amplifier PA1. The output to PA1 and the output of the second transmission signal to transmission amplifier PA2 are performed simultaneously. As a result, in the communication device 100F, normally, as shown in FIG. 12, the transmission operation of the first transmission signal using the antenna ANT1 by the transmission amplifier PA1 and the second operation using the antenna ANT2 by the transmission amplifier PA2, as shown in FIG. The transmission operation of the transmission signal is performed simultaneously.

  On the other hand, as shown in FIG. 12, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is equal to or higher than the first threshold th1 (at high temperature), the communication circuit 110D transmits one type of transmission signal. Are output as transmission signals for the transmission amplifier PA1 and the transmission amplifier PA2. Then, the output destination of the transmission signal is alternately switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time-division manner. Thus, in the communication device 100F, at the time of high temperature, time-division transmission of the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 is performed as shown in FIG.

  Thus, at the time of high temperature, the communication device 100F disperses the heat generating portion related to the transmission of the transmission signal to the transmission amplifier PA1 and the transmission amplifier PA2, similarly to the communication device 100A according to the first embodiment, and Since each of the transmission amplifiers PA1 and PA2 can perform the transmission operation intermittently, local heat generation of the transmission amplifiers PA1 and PA2 can be suppressed. Further, the communication device 100F increases the amount of transmission data per predetermined period T at high temperature by about twice as compared with the case where the transmission operation is performed intermittently using only one of the transmission amplifiers PA1 and PA2 at high temperature. Thus, it is possible to suppress a decrease in throughput related to wireless communication.

  Furthermore, the communication device 100F can perform the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 in parallel in the normal state, so that only one of the transmission amplifiers PA1 and PA2 is used in the normal state. As compared with the case where the transmission operation is continuously performed, the throughput related to the wireless communication can be further increased.

  Since a communication device that performs MIMO communication basically includes two transmission amplifiers, it is possible to suppress a decrease in throughput related to wireless communication without adding a new transmission amplifier, and to reduce a temperature associated with a communication operation. The effect of the present invention of suppressing the rise can be easily obtained.

[Seventh embodiment]
Next, a seventh embodiment will be described with reference to FIGS. Hereinafter, regarding the communication device 100G according to the seventh embodiment, changes from the communication device 100F according to the sixth embodiment will be described. Note that, regarding the communication device 100G, the same components as those of the communication device 100F are denoted by the same reference numerals as those of the communication device 100F, and description thereof will be omitted.

  FIG. 13 is a diagram illustrating a circuit configuration of a communication device 100G according to the seventh embodiment. As shown in FIG. 13, the communication device 100G further includes antennas ANT3 and ANT4 and reception amplifiers LNA1 and LNA2, a communication circuit 110E instead of the communication circuit 110D, and a control circuit instead of the control circuit 140A. It is different from the communication device 100F in that the communication device 100F is provided.

  The antenna ANT3 receives a transmission signal transmitted from the communication device 200 as a reception signal. Receiving amplifier LNA1 amplifies the received signal received by antenna ANT3, and outputs the received signal to communication circuit 110E. As the receiving amplifier LNA1, for example, a low noise amplifier can be used.

  The antenna ANT4 receives a transmission signal transmitted from the communication device 200 as a reception signal. Receiving amplifier LNA2 amplifies the received signal received by antenna ANT4, and outputs the received signal to communication circuit 110E. As the receiving amplifier LNA2, for example, a low noise amplifier can be used.

  The communication circuit 110 </ b> E performs various processes (for example, error correction) based on wireless communication system standards (for example, IEEE802.11b / g / n) on transmission data supplied from a higher-level application device (not shown). By performing an encoding process, a DA conversion process, a modulation process, a filtering process, and the like, a transmission signal for wirelessly transmitting the transmission data is generated from the transmission data. Then, communication circuit 110E outputs the transmission signal to transmission amplifiers PA1 and PA2.

  In addition, the communication circuit 110E performs various processes (for example, error correction decoding) on the reception signals output from the reception amplifiers LNA1 and LNA2 in accordance with the wireless communication system standard (for example, IEEE802.11b / g / n). , An A / D conversion process, a demodulation process, a filtering process, etc.) to generate received data to be supplied to a higher-level application device from the received signal. Then, the communication circuit 110E outputs the received data to a higher-level application device.

  The control circuit 140G controls each of the transmission operation by the transmission amplifier PA1, the transmission operation by the transmission amplifier PA2, the reception operation by the reception amplifier LNA1, and the reception operation by the reception amplifier LNA2 by controlling the communication circuit 110E.

  For example, when the temperature near the transmission amplifier PA1 is lower than the first threshold th1 (normal time), the control circuit 140G controls the communication circuit 110E to output a transmission signal to the transmission amplifiers PA1 and PA2. By alternately switching the band and the time zone for receiving the received signals from the receiving amplifiers LNA1 and LNA2 in a time-division manner, the transmitting amplifiers PA1 and PA2 perform the parallel transmitting operation and the receiving amplifiers LNA1 and LNA2 perform the parallel receiving operation. And the operation are alternately performed in a time-sharing manner.

  Here, in the parallel transmission operation by the transmission amplifiers PA1 and PA2, as in the sixth embodiment, the communication circuit 110E transmits two types of transmission signals having different phases and amplitudes under the control of the control circuit 140G. , A first transmission signal for the transmission amplifier PA1 and a second transmission signal for the transmission amplifier PA2. That is, the control circuit 140G controls the communication circuit 110E to cause the transmission amplifiers PA1 and PA2 to perform a transmission operation corresponding to the MIMO communication. Similarly, the control circuit 140G controls the communication circuit 110E to cause the receiving amplifiers LNA and LNA2 to perform a receiving operation corresponding to the MIMO communication.

  On the other hand, when the temperature near the transmission amplifier PA1 is equal to or higher than the first threshold th1 (at high temperature), the control circuit 140G controls the communication circuit 110E to transmit one type of transmission signal to the transmission amplifier PA1. Output as a transmission signal for transmission amplifier PA2. Then, the communication circuit 110E is controlled such that the output destination of the transmission signal is alternately switched between the transmission amplifier PA1 and the transmission amplifier PA2 in a time-division manner. As a result, the transmission operation by the transmission amplifier PA1, the transmission operation by the transmission amplifier PA2, the reception operation by the reception amplifier LNA1, and the reception operation by the reception amplifier LNA2 can be sequentially performed in a time-division manner.

  FIG. 14 is a diagram illustrating an example of a transmission operation by the communication device 100G according to the seventh embodiment. As shown in FIG. 14, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is less than a predetermined first threshold th1 (normal time), the operation of the communication circuit 110E is controlled by the transmission amplifiers PA1 and PA2. The operation is such that the operation is switched in a time-division manner between the parallel transmission operation and the parallel reception operation by the reception amplifiers LNA1 and LNA2.

  On the other hand, as shown in FIG. 14, when the temperature near the transmission amplifier PA1 detected by the temperature sensor 130 is equal to or higher than a predetermined first threshold th1 (at a high temperature), the operation of the communication circuit 110E is controlled by the transmission amplifier PA1. The transmitting operation, the transmitting operation by the transmitting amplifier PA2, the receiving operation by the receiving amplifier LNA1, and the receiving operation by the receiving amplifier LNA2 are performed sequentially in a time-division manner. Note that the order of the transmission operation by the transmission amplifier PA1, the transmission operation by the transmission amplifier PA2, the reception operation by the reception amplifier LNA1, and the reception operation by the reception amplifier LNA2 may be appropriately changed.

  Thus, the communication device 100G disperses the heat generating portion related to signal transmission and reception to the transmission amplifier PA1, the transmission amplifier PA2, the reception amplifier LNA1, and the reception amplifier LNA2 in both the normal state and the high temperature state, and transmits the signal. Since each of the amplifier PA1, the transmission amplifier PA2, the reception amplifier LNA1, and the reception amplifier LNA2 can intermittently perform the transmission and reception operation, local heat generation of the transmission amplifiers PA1, PA2 and the reception amplifier LNA is suppressed. can do.

  In addition, the communication device 100G can normally perform the transmission operation by the transmission amplifier PA1 and the transmission operation by the transmission amplifier PA2 at the same time, so that the throughput related to wireless communication can be further increased.

  In the present embodiment, when the conditions of the transmission operation are changed between normal time and high temperature, the time distribution between the operation time of the transmission operation and the operation time of the reception operation in one cycle is changed in accordance with the change. It does not matter. This makes it possible to optimize the suppression of heat generation and the improvement of the throughput in the overall communication operation including the transmission operation and the reception operation.

  In the present embodiment, the communication device 100G includes four antennas so as to correspond to two transmission amplifiers and two reception amplifiers. For example, the communication device 100G includes a transmission amplifier PA1 and a reception amplifier LNA1. The communication device may be configured with two antennas including a corresponding first shared antenna and a second shared antenna corresponding to the transmission amplifier PA2 and the reception amplifier LNA2.

  Further, in the present embodiment, the communication device 100G uses two transmission amplifiers and two reception amplifiers to perform MIMO communication at normal times and to perform time-division SISO communication at high temperatures. Is not as large as that of the transmission amplifier, so that even at high temperatures, the reception operations of the reception amplifiers LNA1 and LNA2 are maintained in parallel, and MISO (Multi Input Single Output) communication may be performed.

  Further, in the present embodiment, the communication device 100G includes two reception amplifiers, but may include only one reception amplifier. At normal times, SIMO (Single Input Multi Output) communication is performed in which parallel transmission operation by two transmission amplifiers and reception operation by one reception amplifier are performed, and at high temperature, one type of transmission signal is transmitted to two transmission amplifiers. May be used to perform time-division transmission and time-division SISO communication in which reception operation by one receiving amplifier is performed.

  As described above, one embodiment of the present invention has been described in detail, but the present invention is not limited to these embodiments, and various modifications or changes may be made within the scope of the present invention described in the claims. Changes are possible.

  For example, the present invention is applicable to a communication device used in an in-vehicle device, but is not limited thereto. Is also applicable.

  Also, for example, the present invention is applicable to wireless communication based on Wi-Fi, but is not limited thereto. The present invention is applicable to other wireless communication standards (for example, Bluetooth (registered trademark), LTE (Long Term Evolution)). , Etc.).

  Further, for example, in each of the above embodiments, at the time of high temperature, time-division transmission is performed by two transmission amplifiers. However, the present invention is not limited to this, and time-division transmission is performed by three or more transmission amplifiers. Is also good. In this case, when the temperature is high, the output destination of the transmission signal is sequentially switched among the plurality of transmission amplifiers.

  Further, in each of the above embodiments, the communication device includes the communication circuit that outputs the transmission signal and the antenna connected to the transmission amplifier. However, an essential object of the present invention is to use a plurality of transmission amplifiers at high temperatures. This is to disperse the heat generation portion by using a control circuit, a plurality of transmission amplifiers, and a temperature sensor, and a high-frequency circuit, an antenna, and the like other than the baseband processing circuit and the transmission amplifier may be omitted. That is, the target product of the present invention may be a part of the communication device such as an amplifier module interposed between the main body of the communication device and the antenna.

100A to 100G Communication device 110A to 110E Communication circuit 112 RSSI value detection unit (received signal strength detection means)
120 SW circuit (first switch circuit)
125 SW circuit (second switch circuit)
130, 130A, 130B Temperature sensors 140A to 140G Control circuit (control means)
ANT1, ANT2, ANT3, ANT4 Antenna LNA1, LNA2 Receive amplifier PA1, PA2 Transmit amplifier

Claims (8)

A plurality of transmission amplifiers for amplifying a transmission signal;
A temperature sensor for detecting a temperature near the transmission amplifier,
When the near temperature detected by the temperature sensor is equal to or higher than a predetermined threshold, the plurality of transmission amplifiers control the time division transmission to amplify the transmission signal in a time division manner. Communication device. Further comprising a communication circuit that outputs the transmission signal,
The control means includes:
When the near temperature detected by the temperature sensor is equal to or more than the predetermined threshold, the output destination of the transmission signal from the communication circuit is sequentially switched among the plurality of transmission amplifiers, thereby providing the plurality of transmission amplifiers. The communication device according to claim 1, wherein the communication device controls so as to perform the time division transmission. The plurality of transmission amplifiers are arranged apart from each other,
The temperature sensor detects a temperature near each of the plurality of transmission amplifiers,
The control means includes:
When the adjacent temperature detected by the temperature sensor is equal to or higher than the predetermined threshold, the plurality of transmission amplifiers are controlled to perform the time-division transmission, and the time between the respective adjacent temperatures of the plurality of transmission amplifiers is controlled. Based on the difference, at least one of an operation time of each of the plurality of transmission amplifiers and an output level of the transmission signal output from each of the plurality of transmission amplifiers is changed. 3. The communication device according to 1 or 2. A plurality of antennas provided for each of the plurality of transmission amplifiers,
For each of the plurality of antennas, further comprising a reception signal strength detection means for detecting a reception signal strength,
The control means includes:
When the nearby temperature detected by the temperature sensor is equal to or more than the predetermined threshold, the plurality of transmission amplifiers are controlled to perform time-division transmission of a transmission signal, and are detected by the reception signal strength detection unit. Based on a difference between the received signal strengths of each of the plurality of antennas, an operation time of each of the plurality of transmission amplifiers and an output level of the transmission signal output from each of the plurality of transmission amplifiers. The communication device according to claim 1, wherein at least one of them is changed. The control means includes:
When the nearby temperature detected by the temperature sensor is less than the predetermined threshold, the plurality of transmission amplifiers perform the parallel transmission of the transmission signal,
The method according to any one of claims 1 to 4, wherein when the near temperature detected by the temperature sensor is equal to or more than the predetermined threshold, the plurality of transmission amplifiers perform control so as to perform the time-division transmission of the transmission signal. The communication device according to claim 1. Further comprising a plurality of receiving amplifiers for amplifying the received signal,
The control means includes:
When the nearby temperature detected by the temperature sensor is less than the predetermined threshold, the plurality of transmission amplifiers perform the parallel transmission of the transmission signal, and the plurality of reception amplifiers perform the parallel reception of the reception signal,
When the near temperature detected by the temperature sensor is equal to or higher than the predetermined threshold, the plurality of transmission amplifiers perform the time division transmission of the transmission signal, and the plurality of reception amplifiers perform time division reception of the reception signal. The communication device according to claim 5, wherein the communication device is controlled to perform the following. A first switch circuit that switches a connection destination of the communication circuit to one of the plurality of transmission amplifiers;
The control means includes:
When the near temperature detected by the temperature sensor is equal to or more than the predetermined threshold, by controlling the first switch circuit, by sequentially switching the connection destination of the communication circuit among the plurality of transmission amplifiers, The communication device according to claim 2, wherein the plurality of transmission amplifiers perform control so as to perform the time division transmission. A shared antenna shared by the plurality of transmission amplifiers,
A second switch circuit for connecting any one of the plurality of transmission amplifiers to the shared antenna,
The control means includes:
When the near temperature detected by the temperature sensor is equal to or more than the predetermined threshold, the first switch circuit is controlled to sequentially switch a connection destination of the communication circuit among the plurality of transmission amplifiers, Controlling the second switch circuit so as to sequentially switch the connection destination of the shared antenna among the plurality of transmission amplifiers, so that the plurality of transmission amplifiers perform the time division transmission. The communication device according to claim 7,

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