JP2003244013A - Transmitter-receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmitter-receiver for a keyless entry system and a tire pneumatic pressure monitor apparatus or the like capable of more effectively reducing a means consumed current of a battery and easily correcting characteristics of an RSSI signal. <P>SOLUTION: A transmission section 20 transmits a binary pulse signal including at least a start bit and a unique identification code by operation of a user. A reception section 12 has a function of outputting the electric field strength of a received radio wave as the RSSI signal and receives the signal from the transmission section 20. A control section 11 compares the identification code received by the reception section 12 with a registration code stored in a storage section 14 and outputs an output signal by which the user makes its intended desirable operation when the identification code is coincident with the registration code. The control section 11 uses a criterion of the electric field strength of the received radio wave for discrimination as to whether or not the signal from the transmission section 20 is a legitimate signal and automatically obtains the specified values used for the criterion under its operating environment. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmitter / receiver such as a keyless entry system or a tire pressure monitoring device, and more particularly to a transmitter / receiver capable of reducing its average current consumption.

[0002]

2. Description of the Related Art As a transmitter / receiver, for example, Japanese Patent Laid-Open No. 8-
There is one disclosed in Japanese Patent No. 289372, and a wireless keyless entry system using weak radio waves used in a vehicle is known.

This is the case when a signal including an identification code output by a transmission section configured as a portable electronic key is received by a reception section provided in the vehicle by the operation of a user such as a driver, and it is judged to be normal. In the above, the controlled part performs desired operations intended by the user, such as opening and closing a door lock of a vehicle.

In such a keyless entry system, since the power source in the receiving section is a battery mounted in the vehicle, it is desirable to reduce the average current consumption in order to suppress the consumption of the battery when the vehicle is stopped. ing.

Regarding the reduction of the average current consumption, Japanese Patent Application Laid-Open No. 12-265721 and Japanese Patent Application Laid-Open No. 8-3322 are cited.
It is disclosed in Japanese Patent Publication No. 841. The former relates to a start bit determination method by software, and aims to reduce the average current consumption by shortening the power supply time to the receiver and the wakeup state (startup state) of the controller. The latter is intended to reduce the average current consumption by using the electric field strength judgment of the received radio wave.

[0006]

[Problems to be Solved by the Invention] The latter RSSI (Rece
The specified value used for the determination of the ived Signal Strength Indicator) signal generally has to be set so as to have a certain allowable range. This is because the RSSI signal itself varies due to manufacturing or operating environment.
This is because a proper transmission signal may be erroneously excluded unless a certain allowable range is provided. Therefore (especially,
In a strong electric field area), only by the determination of the RSSI signal,
There is a problem that the state of waiting for a data frame (identification code) is mistakenly caused, resulting in an increase in average current consumption.

[0007] The applicant of the present invention intends to absorb the variation in the characteristics of the RSSI signal by applying for a patent application 2001-380.
No. 604 is proposed. This is to measure the characteristics of the RSSI signal in advance and correct (calibrate) it. However, this method uses an operating environment (electric field strength, temperature, etc.)
There was room for improvement in terms of dealing with variations caused by the above or reducing the number of steps required for calibration.

Therefore, the present invention focuses on the above-mentioned problems,
It is an object of the present invention to provide a transmitter / receiver that can reduce the average current consumption of a battery more effectively and that can easily correct the characteristics of an RSSI signal.

[0009]

In order to solve the above-mentioned problems, the transmitting / receiving apparatus of the present invention has the following structure.
A signal from the transmitting unit having a transmitting unit for transmitting a binarized pulse signal including at least a start bit and a unique identification code and a function for outputting the electric field strength of a received radio wave as an RSSI signal by a user operation. Comparing the identification code received by the receiving section with the registration code stored in the storage section, and when the identification code and the registration code match, the user intends And a control unit that outputs an output signal for performing a desired operation, wherein the control unit determines whether the signal from the transmission unit is a normal signal or not. It is characterized in that the determination based on the strength is used and the specified value used for this determination is automatically obtained under the operating environment.

Further, as described in claim 2, the control unit is activated at predetermined time intervals to bring the receiving unit into a power supply state capable of receiving a signal from the transmitting unit, and in this power supply state. , Determines whether the RSSI signal is greater than or equal to a specified value, and when the RSSI signal is greater than or equal to the specified value, extends the power supply state so that the identification code can be received and receives the identification code. After processing, R
When the SSI signal is less than the specified value, the power supply is cut off, and the specified value used for determining the RSSI signal at the next startup is determined based on the RSSI signal.

Further, as described in claim 3, when the control unit determines the prescribed value used for the determination of the RSSI signal at the next startup, the RSSI signal is based on the reception of a normal transmission signal. If determined, the specified value is not updated.

Further, as described in claim 4, the controller determines that the RSSI signal is a normal transmission signal, the RSSI signal is a specified value or more, and the identification code is It is based on the fact that it is a regular code system.

According to a fifth aspect of the present invention, a transmitter for transmitting a binarized pulse signal containing at least a start bit and a unique identification code and a field strength of a received radio wave by an RSSI signal by a user operation. And a reception unit that receives a signal from the transmission unit, the identification code received by the reception unit, and a registration code stored in a storage unit are compared, and the identification code and A transmission / reception device having a control unit that outputs an output signal for performing a desired operation intended by the user when the registration code matches, wherein the control unit controls the signal from the transmission unit. The judgment based on the electric field strength of the received radio wave and the start bit judgment by software are used together to judge whether it is a normal signal, and the specified value used for the judgment based on the electric field strength of the received radio wave In are those that automatically seek.

Further, as described in claim 6, the control unit is activated at a predetermined time interval to bring the receiving unit into a power supply state capable of receiving a signal from the transmission unit, and in this power supply state. , If the RSSI signal is greater than or equal to a specified value, and if the RSSI signal is greater than or equal to the specified value, the power supply state is extended so that the start bit can be received, and the start by the software is started. Bit determination is performed, and when it is determined to be a normal bit in this determination, the power supply state is further extended so that the identification code can be received, and the identification code receiving process is performed.
When the RSSI signal is less than the specified value, or when it is determined that the start bit is not a normal bit, the power is cut off, and based on the RSSI signal, the RSSI signal can be determined at the next startup. It determines the specified value to be used.

Further, as described in claim 7, when the control unit determines a prescribed value to be used for the determination of the RSSI signal at the next startup, based on the RSSI signal, the RSSI signal is a normal value. When it is determined that the transmission signal is received, the specified value is not updated.

Further, as described in claim 8, the controller determines that the RSSI signal is a normal transmission signal, and the RSSI signal is a specified value or more and the start bit is It is based on the fact that it is a regular bit.

Further, according to a ninth aspect, the receiving section is mounted on a meter unit for displaying various types of coasting information.

Further, as described in claim 10, the control section is also used as the control section of the meter unit for displaying various information.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the accompanying drawings. A keyless entry system will be described as an example of a transmitting / receiving device.

FIG. 1 shows a keyless entry system according to an embodiment of the present invention. Reference numeral 10 is a meter unit that incorporates various electrical equipment units and also serves as a receiver that receives a signal including an identification code from a transmission unit, which will be described later, 11 is a control unit that includes a microcomputer that performs both meter drive processing and keyless processing, and the like. Reference numeral 12 is a receiving unit that receives the signal D from the portable transmitting unit 20 via the antenna 13, and 14 is an EEP that stores the identification code and the like.
A storage unit including a storage element such as a ROM, and 15 is a control unit 11
A drive unit for driving a drive unit 30 such as a door lock motor based on a command from the driver, for example, an output signal for performing a predetermined operation, and 16 is a pointer instruction of an analog meter for running information such as running speed and engine speed. A first instrument (electrical unit) to be displayed, 17 is a second instrument (electrical unit) to be displayed with a multi-digit digital number or a design similar thereto, for example, similar to a 6-digit digital number. An odometer or segment distance meter (trip meter) consisting of a sun-shaped segment is used.

The receiver 12 calculates the electric field strength of the received radio wave as RS.
It is output as an SI signal and transmitted to the A / D conversion input of the control unit 11. The control unit 11 determines the presence / absence of a transmission signal based on whether the voltage value of the RSSI signal is equal to or more than a specified value, and calculates the specified value used for the RSSI signal determination based on the voltage value (for details, See below). Further, the meter unit 10 is provided with a power supply unit 18 that converts the voltage from the vehicle-mounted battery 40 into a predetermined level and supplies the voltage to the control unit 11 and the reception unit 12. Further, the meter unit 10 is provided with an on / off switching unit 19 that controls switching of power supply from the power supply unit 18 between an on state (power supply state) and an off state (power cutoff state) by a predetermined method described later. The switching control of the on / off switching unit 19 is performed by software preset in the control unit 11. The on / off switching unit 19 causes the receiving unit 1 to perform the switching control.
When the power supply to 2 is controlled and is in the ON state, the power is supplied from the power supply unit 18 to set the receiving unit 12 to the reception mode in which the signal can be received. In the OFF state, The power is cut off from the power supply unit 18 to put the reception unit 12 into a standby mode in which the signal cannot be received, and thus the “intermittent reception system” in the reception unit 12 is set.
To realize.

Each bit forming the signal D, which is the code information sent from the transmitting section 20, is usually formed by a binarized pulse signal, and is disclosed in, for example, the above-mentioned prior art, Japanese Patent Laid-Open No. 10-155187. A pulse signal as shown in FIG. 4 (see paragraph number 0023 of the publication) is used. The data structure of the signal D includes a synchronization frame including a plurality of start bits as shown in FIG. 5 of the publication (see paragraph number 0024 of the publication) and an identification code stored in the storage unit 14. It has an identification code having the same content as the collation code, and is composed of a data frame including various codes such as a vehicle type code and a manufacturer code. In the present embodiment, in order to facilitate comparison with the prior art, the same binarized pulse signal and data structure as in the above publication are used as the signal D in the following description.

Next, the operation of the keyless entry system will be described with reference to FIG. 2 (a) and 2 (b) are RSS
The reception state of the transmission signal using I signal determination is shown.

Point A is in a no signal state in which no transmission signal exists. During the period T1, the on / off switching unit 19 causes the receiving unit 12 to operate.
After permitting power supply from the power supply unit 18 to the receiving unit 1
2 is the stabilization waiting time required for stabilization (Fig. 2
(Common in (a) and FIG. 5 (a)).

After that, in the period T20, the RSSI signal is judged. The control unit 11 measures the voltage value of the RSSI signal (here, the voltage value VA) and compares it with the specified value. Here, an initial value (a value lower than the voltage value of the normally assumed RSSI signal in the no-signal state) is set as the specified value. Therefore, in the determination of the RSSI signal, the voltage value (VA) of the RSSI signal becomes the specified value (initial value) or more, and the process shifts to the data frame (identification code) wait.

After that, in the period T3, the data frame is received. However, because of no signal, the data frame cannot be received normally, the power supply to the receiving unit 12 is stopped (power-off state), and the state shifts to the sleep state. However, the control unit 11 stores the voltage value (VA) of the RSSI signal as a signalless state. The sleep period is T5.

Next, the operation at point B will be described. Similar to point A, no signal is present and no signal is transmitted. In the period T20, the RSSI signal is determined. The control unit 11 measures the voltage value of the RSSI signal (here, the voltage value VB) and compares it with the specified value. As the specified value, a value obtained by adding a predetermined value (ΔV) to the voltage value (VA) of the RSSI signal when there is no signal measured in the previous wakeup (startup) state (point A) is used. Thus, in this embodiment, RSS
The characteristic of the I signal is corrected by using the voltage value in the non-signal state (under the operating environment). Since the result of the RSSI signal determination here is that there is no signal, the RSSI signal is less than the specified value, the power supply to the receiving unit 12 is stopped (power cutoff state), and the sleep state is entered. Similarly, the control unit 11
Stores the voltage value (VB) of the RSSI signal as a signalless state.

Next, the operation at point C will be described. Here, it is assumed that the transmission signal exists. In the period T20, the RSSI signal is determined. The control unit 11 uses the RS
Measure the voltage value of the SI signal (here, voltage value VC),
Compare with the specified value. As the prescribed value, a value obtained by adding a predetermined value (ΔV) to the voltage value (VB) of the RSSI signal measured in the previous wakeup state (point B) is used. Since the transmission signal exists, the voltage value (VC) of the RSSI signal becomes equal to or higher than the specified value (VB + ΔV), and the data frame (identification code) waits. After that, in the period T3, the control unit 11 receives the data frame, determines the identification code in the period T4, and when the data code matches the registration code, drives the drive unit 30 according to the function code. Then, it shifts to the sleep state. However, here, the control unit 11 continues to store the previous voltage value (VB) of the RSSI signal.

Next, the operation at point D will be described. Similar to point A, no signal is present and no signal is transmitted. In the period T20, the RSSI signal is determined. The control unit 11 measures the voltage value of the RSSI signal (here, the voltage value VD) and compares it with the specified value. As the prescribed value, a value obtained by adding a predetermined value (ΔV) to the voltage value (VB) of the RSSI signal measured in the wake-up state (point B) two times before last is used. As described above, in this embodiment, when it is determined that the voltage value of the RSSI signal is when the transmission signal is present,
The default value is not updated. That is, the RSSI signal used to calculate the specified value is in a non-signal state. Whether or not there is no signal is determined based on the reception result of the data frame in the period T3. Specifically, it is determined whether or not the code system is regular (regardless of whether or not the identification code matches the registration code). RS here
Since the result of the SI signal determination is that there is no signal, the RSSI signal is less than the specified value, the power supply to the reception unit 12 is stopped (power cutoff state), and the sleep state is entered. Similarly,
The control unit 11 stores the voltage value (VD) of the RSSI signal as a signalless state.

Next, the operation at point E will be described. Similar to point A, no signal is present and no signal is transmitted. In the period T20, the RSSI signal is determined. The control unit 11 measures the voltage value of the RSSI signal (here, the voltage value VE) and compares it with the specified value. The specified value is VD + ΔV
To use. Since the result of the RSSI signal determination here is that there is no signal, the RSSI signal is less than the specified value, the power supply to the receiving unit 12 is stopped (power cutoff state), and the sleep state is entered. Similarly, the control unit 11 stores the voltage value (VE) of the RSSI signal as a non-signal state.

3 and 4 show the relationship between the measured value of the RSSI signal and the specified value of the RSSI signal. FIG. 3 shows a normal electric field region, and FIG. 4 shows a strong electric field region. RS
The specified value of the SI signal has a relationship in which a predetermined value (ΔV) is added to the measured values (VA, VB, VD, VE) of the RSSI signal when there is no signal. If there is a transmitted signal (VC), R
The specified value of the SSI signal is not updated. In FIG. 4, the measured values (VA ′, VB ′, VD ′, VE ′) of the RSSI signal when there is no signal are shifted due to the influence of the strong electric field, and the specified value of the RSSI signal is Is added with a predetermined value (ΔV).

Next, another embodiment will be described with reference to FIG. FIGS. 5A and 5B show a reception state of a transmission signal in which the RSSI signal determination and the start bit determination by software are used together.

Point A is in a no signal state in which no transmission signal exists. In the question T20, the RSSI signal is judged. The control unit 11 measures the voltage value of the RSSI signal (here, the voltage value VA) and compares it with the specified value. here,
Initial value as the specified value (normally assumed RS in the no-signal state)
A value lower than the voltage value of the SI signal) is set. Therefore, the voltage value of the RSSI signal (V
A) is equal to or greater than the specified value (initial value) and continues for the period T2
Start bit judgment is performed at 1. However, since there is no signal, a normal start bit cannot be detected, and the receiving unit 12
Stops power supply to the power supply (power cutoff state) and shifts to sleep mode. However, the control unit 11 stores the voltage value (VA) of the RSSI signal as a signalless state. The sleep period is T5.

Next, the operation at point B will be described. Similar to point A, no signal is present and no signal is transmitted. In the period T20, the RSSI signal is determined. The control unit 11 measures the voltage value of the RSSI signal (here, the voltage value VB) and compares it with the specified value. Specified value is VA + ΔV
To use. Since the result of the RSSI signal determination here is that there is no signal, the RSSI signal is less than the specified value, the power supply to the receiving unit 12 is stopped (power cutoff state), and the sleep state is entered. Similarly, the control unit 11 stores the voltage value (VB) of the RSSI signal as a non-signal state.

Next, the operation at point C will be described. Here, it is assumed that the transmission signal exists. In the period T20, the RSSI signal is determined. The control unit 11 uses RSS
The voltage value of the I signal is measured (here, the voltage value VC) and compared with a specified value. VB + ΔV is used as the specified value. Since the transmission signal exists, the voltage value (VC) of the RSSI signal becomes equal to or higher than the specified value (VB + ΔV), and the period T2 continues.
Start bit determination is made at 1. Here, the start bit is detected, and the process shifts to a data frame wait.

After that, in the period T3, the data frame is received, the identification code is determined in the period T4, and if it coincides with the registration code, the drive unit 30 is driven according to the function code. Then, it shifts to the sleep state. However, here, the control unit 11 determines that the previous RSSI
The voltage value (VB) of the signal is continuously stored.

Next, the operation at point D will be described. Similar to point A, no signal is present and no signal is transmitted. In the period T20, the RSSI signal is determined. Specifically, the voltage value of the RSSI signal is measured (here, the voltage value VD) and compared with a specified value. As the prescribed value, a value obtained by adding a predetermined value (ΔV) to the voltage value (VB) of the RSSI signal measured in the wake-up state (point B) two times before last is used.
Thus, in this embodiment, the voltage value of the RSSI signal is
If it is determined that the transmission signal exists, the specified value is not updated. That is, RS used to calculate the specified value
The SI signal is in a non-signal state. Whether or not there is no signal is determined by whether or not a normal start bit can be detected in the period T21. Since the result of the RSSl signal determination here is that there is no signal, the RSSI signal is less than the specified value, the power supply to the receiver 12 is stopped (power cutoff state), and the sleep state is entered. Similarly, the control unit 11
Stores the voltage value (VD) of the RSSI signal as a signalless state.

Next, the operation at point E will be described. Similar to point A, no signal is present and no signal is transmitted. In the period T20, the RSSI signal is determined. The control unit 11 measures the voltage value of the RSSI signal (here, the voltage value VE) and compares it with the specified value. The specified value is VD + ΔV
To use. Since the result of the RSSI signal determination here is that there is no signal, the RSSI signal is less than the specified value, the power supply to the receiving unit 12 is stopped (power cutoff state), and the sleep state is entered. Similarly, the control unit 11 stores the voltage value (VE) of the RSSI signal as a non-signal state.

In each of the above-described embodiments, a predetermined value is added to the voltage value of the RSSI signal in the non-signal state as a method for calculating the specified value of the RSSI signal. However, for example, the predetermined value is added according to the electric field strength of the operating environment. You may change the value.

In each of the above-mentioned embodiments, the RSSI
Although the method of updating the specified value of the signal is performed every time when it is determined that there is no signal, the method may be updated according to the determination results of a plurality of times, for example.

Such a keyless entry system has a function of outputting a binarized pulse signal including at least a start bit and a unique identification code and a field strength of a received radio wave as an RSSI signal by a user's operation. The receiving unit 12 having the following: the receiving unit 12 receiving the signal from the transmitting unit 20, the identification code received by the receiving unit 12, and the registration code stored in the storage unit 14 are compared, and the identification code and the registration are registered. A transmission / reception device having a control unit 11 that outputs an output signal for performing a desired operation intended by the user when the codes match, the control unit 11 is a signal in which a signal from the transmission unit 20 is a normal signal. The determination based on the electric field strength of the received radio wave is used to determine whether or not the specified value used for this determination is automatically obtained in the operating environment. Starts at a predetermined time interval, the receiving unit 1
2 is a power supply state capable of receiving a signal from the transmission unit 20, and in this power supply state, it is determined whether the RSSI signal is a specified value or more, and when the RSSI signal is a specified value or more, Based on the RSSI signal, the power supply state is extended so that the identification code can be received and the reception processing of the identification code is performed. When the RSSI signal is less than the specified value, the power is cut off. Since the specified value used to judge the RSSI signal at the next start is determined, the average current consumption is reduced by using the electric field strength judgment of the received radio wave, and the specified value is set in the operating environment. Since it is automatically calculated by R
It is possible to correct the variation caused by manufacturing the SSI signal or under the operating environment without using a special calibration work.

Further, the control unit 11 controls the R at the next startup.
In determining the prescribed value used for the determination of the SSI signal,
When it is determined that the RSSI signal is due to the reception of a regular transmission signal, the RSSI signal is prescribed as a condition for determining that the RSSI signal is due to the regular transmission signal without updating the prescribed value. Greater than or equal to the value, and
Since the identification code uses a normal code system, in addition to the above-mentioned effect, when determining the specified value used for the judgment of the RSSI signal, the measured RSSI signal depends on the reception of the normal transmission signal. By determining whether it is a signal or a signalless signal, it is possible to prevent the specified value from being updated (rewritten) by mistake when a normal transmission signal is received.

Further, in another embodiment of the keyless entry system, the control unit 11 determines whether the signal from the transmission unit 20 is a normal signal or not based on the electric field strength of the received radio wave and the start bit determination by software. Together with
A power supply state in which a specified value used for determination by the electric field strength of the received radio wave is automatically obtained under an operating environment, and the receiving unit 20 is activated every predetermined time and the receiving unit 20 can receive a signal from the transmitting unit 20. In this power supply state, it is determined whether the RSSI signal is greater than or equal to a specified value, and if the RSSI signal is greater than or equal to the specified value, the power supply state is extended so that the start bit can be received. Then, the start bit judgment by the software is performed, and when it is judged that the bit is a normal bit by this judgment, the power supply state is further extended so that the identification code can be received, and the reception processing of the identification code is performed. , If the RSSI signal is less than the specified value, or if it is determined that the start bit is not a normal bit, the power is cut off, and Since the stipulated value used for the determination of the RSSI signal at the next startup is determined based on the RSSI signal, the average current consumption can be reduced by using the electric field strength determination of the received radio wave and the start bit determination by software together. In addition to the above, the RSSI signal is automatically calculated in the operating environment to determine the specified value.
It is possible to correct the variation caused by the manufacturing of the signal or the operating environment without using a special calibration work.

Further, the control unit 11 determines that the RSSI signal is due to the reception of a proper transmission signal when determining the prescribed value used for the determination of the RSSI signal at the next startup based on the RSSI signal. In this case, the specified value is not updated, and the RSSI
In addition to the above effects, the condition for determining that the signal is a normal transmission signal is that the RSSI signal is a specified value or more and the start bit is a normal bit. , When measuring the specified value used for the RSSI signal determination, the measured RS
By determining whether the SI signal is due to the reception of the normal transmission signal or not, it is possible to prevent the specified value from being erroneously updated when the normal transmission signal is received.

Further, since the receiver 12 as a transmitter / receiver is mounted on the meter unit 10 having a good radio wave reception environment, the transmitter / receiver performance can be improved.

Further, the control unit 11 includes the meter unit 10
Since it is also used as the control unit, it is possible to reduce the size and cost by sharing the components.

It is needless to say that the present invention is not limited to a four-wheel vehicle, but can be applied to a keyless entry system for two wheels, snowmobiles, ships, etc.

In the embodiment of the present invention, the keyless entry system has been described as an example of the transmitting / receiving device. However, the present invention is mounted on a vehicle and determines the presence / absence of a transmission signal from the transmitting unit. It is needless to say that the present invention is also applicable to an entry system for products (for example, a tire pressure monitoring system, a smart entry system).

[0049]

INDUSTRIAL APPLICABILITY The present invention relates to a transmitting / receiving device such as a keyless entry system and a tire pressure monitoring device, which can more effectively reduce the average current consumption of a battery, which is the original purpose, and can reduce the RSSI signal. It is possible to obtain a transmitting / receiving device whose characteristics can be easily corrected.

[Brief description of drawings]

FIG. 1 is a block diagram illustrating a configuration of a keyless entry system according to an embodiment of the present invention.

FIG. 2 is a time series diagram for explaining a reception state in the intermittent reception system of the above embodiment.

FIG. 3 is a diagram for explaining a specified value of an RSSI signal in a normal electric field area according to the above embodiment.

FIG. 4 is a diagram illustrating a specified value of an RSSI signal in a strong electric field area according to the above embodiment.

FIG. 5 is a time series diagram for explaining a reception state in the intermittent reception system according to another embodiment of the present invention.

[Explanation of symbols]

10 meter unit 11 Control unit 12 Receiver 13 antennas 14 Memory 15 Drive 16 First instruments 17 Second instruments 18 power supply 19 ON / OFF switching section 20 Transmitter 30 drive unit 40 battery D signal

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04Q 9/00 341 H04Q 9/00 341B

Claims (10)

[Claims] 1. A transmission unit for transmitting a binarized pulse signal containing at least a start bit and a unique identification code by a user's operation, and a function for outputting the electric field strength of a received radio wave as an RSSI signal, A receiving unit that receives a signal from a transmitting unit, the identification code received by the receiving unit, and a registration code stored in a storage unit are compared, and when the identification code and the registration code match. A transmitter / receiver having a controller that outputs an output signal for performing a desired operation intended by the user, wherein the controller determines whether or not the signal from the transmitter is a normal signal. A transmitter / receiver characterized by using a judgment based on the electric field strength of a received radio wave and automatically obtaining a specified value used for this judgment under an operating environment. 2. The control unit is activated at predetermined time intervals to bring the receiving unit into a power supply state capable of receiving a signal from the transmitting unit, and in this power supply state, whether the RSSI signal is a specified value or more. If the RSSI signal is greater than or equal to the specified value, the power supply state is extended so that the identification code can be received, and the reception processing of the identification code is performed. When it is less than the specified value, the power is cut off and the RSSI
The transmitter / receiver according to claim 1, wherein a prescribed value used for determining the RSSI signal at the next startup is determined based on the signal. 3. The controller controls the RSS at the next startup.
The stipulated value is not updated when it is determined that the RSSI signal is due to reception of a normal transmission signal in determining the stipulated value used for determining the I signal. Transceiver device. 4. The RS is used as a condition for determining that the RSSI signal is a normal transmission signal.
The transmitter / receiver according to claim 3, wherein the SI signal is equal to or more than a specified value, and the identification code has a regular code system. 5. A transmission unit for transmitting a binarized pulse signal containing at least a start bit and a unique identification code by a user's operation, and a function for outputting the electric field strength of a received radio wave as an RSSI signal, A receiving unit that receives a signal from a transmitting unit, the identification code received by the receiving unit, and a registration code stored in a storage unit are compared, and when the identification code and the registration code match. A transmitter / receiver having a controller that outputs an output signal for performing a desired operation intended by the user, wherein the controller determines whether or not the signal from the transmitter is a normal signal. In addition, the judgment based on the electric field strength of the received radio wave and the start bit judgment by software are used together, and the specified value used for the judgment based on the electric field strength of the received radio wave is automatically obtained under the operating environment. Transmitter and receiver. 6. The control unit is activated at predetermined time intervals to bring the receiving unit into a power supply state capable of receiving a signal from the transmitting unit, and in this power supply state, whether the RSSI signal is a specified value or more. If the RSSI signal is greater than or equal to the specified value, the power supply state is extended so that the start bit can be received, and the start bit determination by the software is performed. When it is determined that the identification code is a valid bit, the power supply state is further extended so that the identification code can be received, and the reception processing of the identification code is performed, and the RSSI signal is less than the specified value, or the start bit. When it is determined that is not a normal bit, the power is cut off, and the R at the next startup is based on the RSSI signal.
The transmitter / receiver according to claim 5, wherein a prescribed value used for the determination of the SSI signal is determined. 7. The control unit determines that the RSSI signal is due to reception of a proper transmission signal when determining a prescribed value used for determination of the RSSI signal at the next startup based on the RSSI signal. The transmitter / receiver according to claim 6, wherein the specified value is not updated in such a case. 8. The control unit sets the RS as a condition for determining that the RSSI signal is a normal transmission signal.
8. The transmitter / receiver according to claim 7, wherein the SI signal is equal to or larger than a specified value and the start bit is a regular bit. 9. The transmitter / receiver according to claim 1, wherein the receiver is mounted on a meter unit that displays various types of coasting information. 10. The transmission / reception device according to claim 1, wherein the control unit is also used as a control unit of a meter unit that displays various types of information.