JP4137369B2 - Wireless transmitter and wireless device using the wireless transmitter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a radio transmitter (hereinafter simply referred to as a transmitter) and a radio apparatus using the transmitter, and particularly to a radio receiver (hereinafter simply referred to as a receiver) having a squelch circuit. The present invention relates to a transmitter and a wireless device that are effective for wireless communication between devices.
[0002]
[Prior art]
It is known that in a wireless device, for example, when a radio wave is not emitted from a transmitter or when a radio wave arriving at a receiver is too weak, a very large noise is output from the receiver. This phenomenon is particularly prominent in FM (frequency modulation) wireless devices. The squelch circuit is a means for suppressing this noise.
[0003]
As the squelch circuit, for example, a noise squelch circuit is known. This is because the noise component is extracted from the detection output in the receiver, and the presence or absence or strength of the incoming radio wave is detected from the magnitude of the noise component obtained by this extraction. Only when it has strength, for example, the detection output is output from the output terminal and the output of the so-called receiver is turned on. When there is no incoming radio wave from the transmitter or when it is too weak, the detection output is prevented from being output from the output terminal, and the so-called receiver output is turned off. This suppresses the noise from being output from the receiver.
[0004]
However, the noise squelch circuit has an element that constitutes a relatively large time constant such as a smoothing capacitor in a portion that extracts a noise component from the detection output or the like. Therefore, a time delay corresponding to the time constant occurs when the output of the receiver is turned on or off with respect to the presence or absence of the actual incoming radio wave or a change in strength. And this time delay induces the following problems.
[0005]
For example, wireless communication is being performed well between a transmitter and a receiver that constitute a certain wireless device, that is, radio waves emitted from the transmitter reach the receiver side with sufficient strength. Suppose you are. Here, for example, as shown in FIG. ₀ Suppose that the transmitter power switch is turned off. Then, at that time t ₀ Then, as shown in FIG. 5C, the transmission output (RF output) of the transmitter is turned off, and the emission of radio waves from the transmitter is stopped. In response to this, the receiver side has no incoming radio wave from the transmitter, and as shown in FIG. ₀ , The noise component of the detection output increases rapidly. When this noise component increases, the squelch circuit works and the output of the receiver is turned off.
[0006]
However, it takes time according to the time constant of the squelch circuit itself as described above until the squelch circuit is activated in response to the actual increase in the noise component. Therefore, as shown in FIG. 5E, the time t when the noise component is actually increased. ₀ From 'to Ts' until the squelch circuit is activated, the squelch circuit is in the output ON state. Therefore, during this period, Ts ′, a very large noise N ′ is output from the receiver. This period Ts ′ is about several [ms], and audibly, a loud sound “pot” is instantaneously output from the receiver.
[0007]
The transmitter has, for example, a press talk switch (hereinafter simply referred to as a talk switch), and the so-called press talk type in which the transmission output is turned on / off according to the ON / OFF operation of the talk switch. If the talk switch is turned off from the ON state, the same phenomenon as when the power switch is turned off from the ON state appears as shown in FIG. Therefore, in this case, each time the talk switch is turned OFF, the so-called “pop sound” is output, and the frequency of outputting the “pop sound” increases.
[0008]
[Problems to be solved by the invention]
In other words, the problem to be solved by the present invention is that when the power switch is turned off on the transmitter side, the above-mentioned “pop sound” is output on the receiver side, which is extremely uncomfortable for hearing. It is that. In particular, when the transmitter is of the above-mentioned press talk type, the above-mentioned problem becomes more prominent because not only the power switch but also the “pop sound” is output when the talk switch is turned off. .
[0009]
In addition to the noise squelch method, for example, the squelch circuit extracts a carrier wave (carrier) included in the received signal of the receiver, and according to the signal level of the carrier wave obtained by this extraction, There is a so-called carrier squelch type in which the output is ON / OFF controlled. This carrier squelch circuit also has a time constant that causes the time delay. However, the time constant of the carrier squelch circuit is generally smaller than the time constant of the noise squelch circuit. Therefore, in the noise squelch circuit having such a large time constant, the “popping noise” is more noticeable than in the carrier squelch circuit, and the above problem becomes obvious.
[0010]
Therefore, the present invention relates to a transmitter capable of preventing the above-mentioned “pop sound” from occurring on the receiver side when the power switch or the talk switch is turned off on the transmitter side, and a radio apparatus using the transmitter , To provide.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, it is assumed that the wireless device of the present invention includes a generally known compander. This compander consists of a compressor provided on the transmitter side and an expander provided on the receiver side, and avoids the influence of noise in the transmission path between these transceivers. Widely used as a means for achieving this.
[0012]
That is, of the transmitter and the receiver constituting the wireless device of the present invention, the transmitter is
A compressor that compresses the amplitude of the original signal to be transmitted based on a predetermined amplitude compression characteristic, such as a logarithmic characteristic or an exponential characteristic;
A transmitter for transmitting the signal compressed by the compressor by radio waves;
When a transmission stop command is given from the outside, only the radio wave is transmitted in a state that does not include the original signal for a predetermined period from the time when the transmission stop command is given, that is, a so-called silent state, and the predetermined period ends. A transmission control unit that controls the transmission unit so that the transmission of the radio wave is stopped at the time,
It comprises.
[0013]
In addition, as said original signal said here, there exists an audio | voice signal, for example. In addition to the audio signal, for example, a video signal, data obtained by digitizing various information, or the like can be used as the original signal. And that the transmission stop command is given from outside means, for example, that the power switch of this transmitter is changed from the ON state to the OFF state. Further, for example, when the transmitter is of a press talk type, changing the talk switch from the ON state to the OFF state corresponds to giving the transmission stop command.
[0014]
On the other hand, the receiver
A receiving unit that receives a radio wave transmitted from the transmitter and performs predetermined processing, such as detection processing, on the received signal;
A signal that is processed by the receiving unit is input, and an expander that restores the original signal by expanding the amplitude of the input signal based on an amplitude expansion characteristic opposite to the amplitude compression characteristic;
When the received electric field strength of the radio wave by the receiving unit is monitored and the received electric field strength obtained by monitoring is larger than a certain reference value, the original signal obtained by restoring by the expander is output from a predetermined output terminal. When the received electric field strength obtained by the monitoring is lower than the reference value when the output is in the first state, that is, the output is turned on, the original signal obtained by the restoration is prevented from being output from the output terminal. A squelch circuit that is in a second state, that is, an output OFF state,
It comprises.
For example, the expander detects the amplitude of the signal input thereto, and adjusts its own gain according to the amplitude of the input signal obtained by the detection, so that the expander is based on the predetermined amplitude expansion characteristic. Implement decompression processing. When the amplitude of the signal input to the expander changes, the expander changes the amplitude of its output signal in accordance with the change of the amplitude of the input signal. Cause delay.
The squelch circuit also has its own time constant to change from the output ON state to the output OFF state according to the change in the received electric field strength when the received electric field strength obtained by the monitoring changes. A corresponding second time delay is produced. However, the second time delay required for the squelch circuit to operate is shorter than the first time delay required for the expander to operate.
[0015]
Note that the certain reference value referred to here is, for example, a determination criterion for the presence or absence or strength of an incoming radio wave from the transmitter based on the received electric field strength obtained by the squelch circuit, The value which becomes. This reference value may be configured to be arbitrarily variable.
[0016]
In the present invention, for example, it is now assumed that both the power switches of the transmitter and the receiver are turned on. Then, on the transmitter side, the original signal compressed by the compressor is transmitted to the receiver side as a radio wave by the transmitter, and the radio wave including this original signal reaches the receiver side with sufficient strength. Suppose that In such a state, on the receiver side, the radio wave transmitted from the transmitter is received by the receiving unit, and the received signal is subjected to predetermined processing such as detection processing. Then, the original signal is restored by expanding the amplitude of the signal after this detection processing or the like by an expander. At this time, since the squelch circuit is in the output ON state, the restored original signal is output to the outside via the output terminal.
[0017]
Here, for example, it is assumed that a transmission stop command is given to the transmission control unit from the outside by turning off the power switch on the transmitter side. Then, the transmission control unit controls the transmission unit so as to transmit only the radio wave without including the original signal for a predetermined period from the time when the power switch is turned off. Then, the transmission control unit controls the transmission unit to stop the transmission of the radio wave when the predetermined period ends.
[0018]
On the other hand, on the receiver side, a so-called silent radio wave that does not include the original signal is received for the predetermined period from the time when the power switch is turned off on the transmitter side. As a result, the amplitude of the signal after processing by the receiving unit, that is, the amplitude of the input signal of the expander rapidly decreases, and the amplitude of the output signal of the expander also decreases accordingly. During this predetermined period, the incoming radio wave itself has a sufficient intensity (greater than the reference value), so that the squelch circuit maintains the output ON state. Therefore, even during this predetermined period, the output signal of the decompressor is output to the outside through the output terminal, but since this output signal does not include the original signal, the predetermined period is a so-called silent period. .
[0019]
When the silent period ends, the incoming radio wave from the transmitter disappears. As a result, the receiving unit outputs the above-described very large noise. Then, when the noise is input to the expander, the amplitude of the input signal of the expander rapidly increases, and accordingly, the amplitude of the output signal of the expander also increases. In response to the absence of the incoming radio wave, the squelch circuit transitions from the output ON state to the output OFF state. Here, the squelch circuit does not immediately transition to the output OFF state when the incoming radio wave disappears, but enters the output OFF state after a second time delay from the time when the incoming radio wave disappears. Therefore, until the second time elapses, the output signal of the expander is output to the outside via the output terminal. However, the amplitude of the output signal of the expander does not increase suddenly when the incoming radio wave disappears, but gradually increases over a first time longer than the second time. Then, while the amplitude of the output signal of the expander is gradually increasing, in other words, while the amplitude of the output signal is still small, the squelch circuit is turned off. As a result, the level of noise output from the output terminal until the squelch circuit is in the output OFF state is suppressed to such an extent that it becomes inconspicuous for hearing. Therefore, a large noise such as the above-mentioned “pop sound” is not output.
[0020]
In addition, when the transmitter is of the press talk type, for example, when both the power switch and the talk switch of the transmitter are turned on, only the talk switch is turned off. The same effect as when the power switch is turned off is obtained. Therefore, in this case as well, it is possible to suppress the level of the noise output from the receiver before the squelch circuit is in the output OFF state, and to prevent the “pop sound” from being output.
[0021]
As described above, when the power switch or the talk switch is turned off on the transmitter side and a silent period is formed, the amplitude of the output signal of the expander on the receiver side decreases. Also at this time, the amplitude of the output signal of the expander does not rapidly decrease, but gradually decreases over time corresponding to the time constant of the expander itself. Here, for example, when the silent period is extremely short, there is no incoming radio wave from the transmitter before the amplitude of the output signal of the expander is sufficiently reduced. Then, the output signal of the expander in which the amplitude is not sufficiently reduced from when the incoming radio wave disappears until the output of the squelch circuit is turned off is output from the output terminal to the outside. The As a result, the level of noise output until the squelch circuit is in the output OFF state cannot be sufficiently suppressed.
[0022]
Therefore, in order to avoid such a problem, the silence period is substantially minimized during the silent period when the transmitter power switch or talk switch is turned OFF and the amplitude of the output signal of the expander is sufficiently reduced. It is desirable that the period is longer than the period until. However, if this silent period is made too long, for example, when these switches are turned on immediately after turning off the power switch or talk switch on the transmitter side, it takes time until the ON operation of this switch becomes effective. The wireless communication operation may be adversely affected. Therefore, it is important not to make the silent period longer than necessary.
[0023]
Further, the present invention extracts, as the squelch circuit, a certain noise component included in the received signal obtained by receiving the radio wave by the receiving unit, and based on the magnitude of the noise component obtained by the extraction. It is more effective when applied to a receiver that employs a noise squelch type circuit that determines whether or not the received electric field intensity obtained by monitoring is larger than the reference value.
[0024]
That is, as described above, a receiver that employs a noise squelch system as a squelch circuit is more prominent in the “pop sound” than a receiver that employs a carrier squelch system. Therefore, the present invention exerts particularly great power in a transmitter that uses a receiver that employs a noise squelch circuit that is prominent in such “popping noises”, and in a wireless device including such a receiver. .
[0025]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment in which the present invention is applied to, for example, a press-talk type wireless device will be described with reference to FIGS.
[0026]
FIG. 1A is a block diagram showing a schematic configuration of the transmitter according to the present embodiment. As shown in the figure, this transmitter has a compressor 3 to which a signal after an audio signal input from a microphone 1 is amplified by a low frequency amplifier 2 is input. The compressor 3 compresses the amplitude of the signal input thereto based on, for example, a ½ logarithmic characteristic, and inputs the compressed signal to the mixer 4. A tone signal generated by the tone signal generator 5 is also input to the mixer 4. Note that the tone signal is an AC signal in a non-audible frequency band having a frequency of about several tens of kHz, for example, and the frequency of the tone signal is arbitrarily set for each wireless device (system).
[0027]
The mixer 4 mixes the compressed audio signal and the tone signal inputted thereto, and inputs the signal obtained by the mixing to the modulation unit 7 via the audio switch 6. The modulation unit 7 includes a carrier wave oscillator (not shown), and performs, for example, FM modulation on the carrier wave signal oscillated by the carrier wave oscillator using the signal input from the mixer 4. The FM modulated signal is amplified by the high frequency power amplifier 8 and then emitted from the transmitting antenna 9 into the air as a radio wave.
[0028]
Further, the transmitter includes a control unit 10 having, for example, a CPU (Central Processing Unit) configuration. A power switch and a talk switch (not shown) are connected to the control unit 10, and the control unit 10 performs the ON / OFF operation of the voice switch 6 and the high frequency power according to the ON / OFF operation of these switches. The operation of the amplifier 8 is controlled. In particular, when the power switch is operated, the control unit 10 also controls a power supply circuit (not shown) for supplying driving power to each circuit constituting the transmitter.
[0029]
Specifically, for example, when both the power switch and the talk switch are in the ON state, the control unit 10 turns on the voice switch 6 to electrically connect the output side of the mixer 4 and the input side of the modulation unit 7. And the high-frequency power amplifier 8 is operated effectively. Therefore, in this state, a signal including the compressed audio signal and tone signal (strictly, modulated by these signals) is transmitted from the transmitting antenna 9 by radio waves.
[0030]
Next, it is assumed that at least one switch is turned off in a state where both the power switch and the talk switch are turned on. Then, when the switch is turned off, the control unit 10 turns off the voice switch and electrically disconnects the output side of the mixer 4 and the input side of the modulation unit 7. The control unit 10 stops the operation of the high-frequency power amplifier 8 only when a predetermined period To elapses after the power switch or the talk switch is turned off. That is, the transmitter emits only radio waves in a state that does not include the compressed audio signal and tone signal for a predetermined period To from the time when the power switch or the talk switch is turned off. When the predetermined period To elapses, the transmitter stops emitting the radio wave.
[0031]
The predetermined period To is a period longer than at least an attack time Ta and a release time Tr, which will be described later. For example, To = several hundreds [ms] (100 [ms] to 200 [ms]). Further, when the turned-off switch is a power switch, the control unit 10 stops the operation of the power circuit after the predetermined period To elapses and turns off the power of the entire transmitter (that is, The operation when the transmitter is turned off is a kind of software switch configuration).
[0032]
When only the power switch is turned on and the talk switch is turned off, the control unit 10 turns off the voice switch 6 and stops the operation of the high-frequency power amplifier 8. When the talk switch is turned on in this state, the control unit 10 immediately turns on the voice switch 6 and effectively operates the high-frequency power amplifier 8. Needless to say, the control unit 10 cannot operate when the power switch is originally turned off.
[0033]
The operation of the control unit 10, particularly the operation of the control unit 10 when one of the switches is turned off in a state where both the power switch and the talk switch are turned on, is represented by a flowchart, for example, as shown in FIG. become. A so-called control program for operating the control unit 10 in accordance with the procedure shown in the flowchart of FIG. 2 is stored in a storage unit having a semiconductor memory configuration (not shown).
[0034]
That is, in a state where both the power switch and the talk switch are turned on, when one of the switches is turned off, the control unit 10 enters the flow of FIG. And the control part 10 judges first whether the switch turned off is a power switch (step S2). Here, for example, if it is determined that the power switch is turned off (in the case of YES), the control unit 10 sets a power flag F indicating that, for example, F = 1 (step S4), and then the voice. The switch 6 is turned off (step S6). On the other hand, if it is determined in step S2 that the power switch is not turned off, that is, the talk switch is turned off (in the case of NO), the control unit 10 skips step S4 and proceeds to step S6. The voice switch 6 is turned off.
[0035]
After turning off the voice switch 6, the control unit 10 resets and starts a timer for counting the predetermined period To (step S8). Then, the control unit 10 repeats the counting operation of the timer until the predetermined period To elapses (step S10), and when the predetermined period To elapses (when YES in step S10), the high frequency The operation of the power amplifier 8 is stopped (step S12).
[0036]
After stopping the operation of the high-frequency power amplifier 8, the control unit 10 checks whether or not the power flag F is set (step S14). Here, when it is confirmed that the flag F is set (F = 1), that is, the switch that is turned off is a power switch (in the case of YES), the control unit 10 performs the operation of the power circuit. Processing for stopping is executed (step S16). Thereby, the power supply of the whole transmitter is actually turned off. On the other hand, when it is confirmed in step S14 that the flag F is not set, that is, the switch that has been turned off is a talk switch (in the case of NO), the control unit 10 exits this flow as it is.
[0037]
Note that the procedure shown in the flowchart of FIG. 2 is an example for realizing a series of operations of the control unit 10 until it gets tired. If the same operation as described above can be realized, the control is performed by other procedures. The unit 10 may be controlled. The control unit 10 is not limited to the CPU, and can be realized by a pure hardware configuration in which various electronic components are combined, for example.
[0038]
On the other hand, the configuration of the receiver is shown in FIG. As shown in the figure, the receiver receives the radio wave transmitted from the transmitter by the receiving antenna 20, and the received signal is subjected to predetermined processing such as amplification processing and filtering processing by the high frequency processing unit 21. Thereafter, FM detection is performed by the detection unit 22. The so-called detection output obtained by detection by the detection unit 22 is input to the expander 24 via a low-pass filter (LPF) 23 having a pass band mainly in the audible frequency band. The expander 23 expands the amplitude of the detection output after filtering input thereto based on a 1/2 logarithmic characteristic opposite to the amplitude compression characteristic by the compressor 3 to restore the original audio signal. . The restored audio signal is output to the outside from the output terminal 26 via the squelch switch 25, and is input to, for example, a speaker (not shown).
[0039]
The expander 24 detects the amplitude of the signal (that is, the detection output) input thereto, and adjusts its own gain according to the amplitude obtained by the detection, whereby the 1/2 logarithm. Realize stretching. However, the expander 24 has an element that constitutes a relatively large time constant such as a smoothing capacitor, for example, in a portion that detects the amplitude of the input signal. Therefore, when the amplitude of the signal input to the expander 24 changes abruptly, the expander 24 changes the gain of the signal according to the change of the amplitude of the input signal, with a time delay corresponding to the time constant. Arise. This time delay is about several tens [ms] (about 20 [ms] to 30 [ms]) at the maximum. Note that the operation of the expander 24 in the direction of amplifying its own gain is generally referred to as an attack, and the time taken for this attack is referred to as the attack time Ta described above. Further, the operation of the expander 24 in the direction of decreasing its own gain is generally referred to as release, and the time taken for this release is referred to as the release time Tr described above.
[0040]
The decompressor 24 forms a pair of companders together with the compressor 3 on the transmitter side. This compander is widely used as a means for avoiding the influence of noise in the transmission path between the transceiver. Since this compander is a well-known technique, further detailed explanation is omitted here. In the present embodiment, the 1/2 logarithmic characteristic is used as the companding characteristic of the compander, but other characteristics such as a logarithmic characteristic of other ratios and an exponential characteristic may be used. Good.
[0041]
The receiver has two filters 27 and 28 in addition to the low pass filter 23. The detection output of the detection unit 22 is also input to these filters 27 and 28. One of these 27 is a band pass filter for extracting the tone signal, and has, for example, a crystal filter configuration in order to obtain good selectivity. The tone signal extracted by the filter 27 is rectified and smoothed by the rectifying unit 29 and then input to the control unit 30 having a CPU configuration, for example.
[0042]
The other filter 28 has a very large noise component output from the detector 22 when there is no incoming radio wave from the transmitter (strictly speaking, an incoming radio wave that can be received by the receiver) or when it is too weak, And a high-pass filter configuration. The noise component extracted by the high-pass filter 28 is also rectified and smoothed by a rectifying unit 31 different from the rectifying unit 29 and then input to the control unit 30. The high-pass filter 28 has a pass band in a frequency band other than the pass bands of the low-pass filter 23 and the band-pass filter 27 in order to reliably extract the noise component. is doing. Instead of the high pass filter 28, a band pass filter having a pass band in substantially the same frequency band may be used.
[0043]
The control unit 30 controls the ON / OFF operation of the squelch switch 25 based on the signals input from the rectifying units 29 and 31. Specifically, the control unit 30 compares the level of the signal input from the rectification unit 29 with a predetermined tone reference level. When the level of the signal input from the rectifying unit 29 is higher than the tone reference level, in other words, when the detection signal includes a tone signal, the control unit 30 receives the signal from the transmitter that is the communication partner. Recognized as a radio wave being sent (strictly speaking, a radio wave sent from a transmitter as a communication partner can be received with sufficient strength). On the contrary, when the level of the signal input from the rectifying unit 29 is equal to or lower than the tone reference level, in other words, when the tone signal is not included in the detection output, the control unit 30 is the communication partner. Recognizes that radio waves are not sent from a certain transmitter (or radio waves are too weak). The tone reference level referred to here is based on the level of the signal input from the rectifying unit 29, and is used to determine whether or not radio waves are being transmitted with sufficient strength from the transmitter that is the communication partner. This is the level that is used as a criterion. This tone reference level may be arbitrarily variable.
[0044]
Further, the control unit 30 compares the level of the signal input from the rectification unit 31 with a predetermined noise reference level. When the level of the signal input from the rectifier 31 is smaller than the noise reference level, in other words, when the very large noise is not output from the detector 22, the control unit 30 is the communication partner. It is recognized that an incoming radio wave from a certain transmitter has sufficient intensity (strictly, it can receive any incoming radio wave that can be received by this receiver with sufficient intensity). On the contrary, when the level of the signal input from the rectifier 31 is equal to or higher than the noise reference level, in other words, when the very large noise is output from the detector 22, the controller 30 , It recognizes that there is no incoming radio wave from the transmitter or it is too weak. The above-mentioned noise reference level refers to a level that serves as a determination reference for determining the presence or absence or strength of the incoming radio wave based on the level of the signal input from the rectifying unit 31. This noise reference level may also be arbitrarily variable as with the tone reference level.
[0045]
The control unit 30 has a level of the signal input from the rectification unit 29 higher than the tone reference level, that is, a radio wave is transmitted from a transmitter as a communication partner, and is input from the rectification unit 31. The squelch switch 25 is turned on and the output of the so-called receiver is turned on only when the level of the signal to be transmitted is smaller than the noise reference level, that is, when the incoming radio wave from the transmitter has sufficient strength. . In other cases, that is, at least when the level of the signal input from the rectifier 29 is equal to or lower than the tone reference level, or when the level of the signal input from the rectifier 31 is equal to or higher than the noise reference level, The control unit 30 determines that no radio wave is emitted from the transmitter that is the communication partner, or that the radio wave is too weak. Then, the squelch switch 25 is turned off, and so-called receiver output is turned off.
[0046]
That is, the receiver according to the present embodiment includes a tone squelch type squelch circuit that turns ON / OFF the output of the receiver depending on whether or not a tone signal is included in the detection output, and noise included in the detection output. A noise squelch type squelch circuit that turns ON / OFF the output of the receiver according to the level of the component is used in combination. This makes it possible to realize wireless communication reliably and satisfactorily only with the transmitter that is the communication partner.
[0047]
According to the tone squelch circuit, it is possible to determine whether or not the radio wave transmitted from the transmitter as the communication partner can be received with sufficient strength based on the presence or absence of the tone signal. In view of this point, it is considered that the tone squelch circuit is sufficient without using both the noise squelch circuit and the tone squelch circuit as described above.
[0048]
However, since the band-pass filter 27 constituting the tone squelch circuit has a crystal filter configuration with poor responsiveness, the responsiveness of the tone squelch circuit itself is also poor. For example, when the presence or absence of a tone signal changes, it may take up to about 1 [s] until the tone squelch circuit operates in response to this change. Therefore, only the tone squelch circuit having such poor response cannot instantaneously suppress the noise output from the receiver when there is no incoming radio wave or when it is too weak. Therefore, in this embodiment, the original function of the squelch circuit, which turns off the output of the receiver when there is no incoming radio wave or is too weak, is realized by a noise squelch circuit, and the tone squelch circuit is mainly used for communication. This is used as a means for generally specifying the transmitter as the counterpart.
[0049]
However, the noise squelch circuit also has a slight effect on turning on or off the output of the receiver according to the presence or absence of the incoming radio wave or a change in strength due to the influence of the time constant of the rectifying unit 31 constituting the squelch circuit. This causes a time delay. For example, when the presence or absence or strength of incoming radio waves changes suddenly, the maximum number of [ms] (about 2 [ms] to 3 [ms]) is required before the noise squelch circuit operates according to this change. It takes time Ts.
[0050]
In the wireless apparatus configured as described above, for example, it is assumed that the power switches of the transmitter and the receiver are both turned on and the talk switch of the transmitter is also turned on. Then, it is assumed that the audio signal compressed on the transmitter side is transmitted to the receiver side by radio waves, and the radio wave including this audio signal reaches the receiver side with sufficient strength. In such a state, the receiver side receives the radio wave transmitted from the transmitter, detects the received signal, and expands the original audio signal. At this time, since the receiver (squelch switch 25) is in an output ON state, the restored audio signal is output to the outside via the output terminal 26.
[0051]
Here, for example, as shown in FIG. 3A or FIG. ₀ Suppose that the transmitter power switch or talk switch is turned off. Then, the transmitter, as described above, points in time t when these switches are turned off. ₀ From time to time, only radio waves are emitted in a state that does not include the audio signal and tone signal for a predetermined period To. Then, as shown in FIG. 5C, the time t when the predetermined period To has elapsed. ₁ Then, the emission of the radio wave is stopped.
[0052]
On the other hand, at the receiver side, the time t ₀ Thus, a so-called silent radio wave that does not include a voice signal and a tone signal is received for a predetermined period To. During the predetermined period To, the received radio wave itself has a sufficient strength, so that the very large noise described above is not output from the detector 22 as shown in FIG. In addition, the time t ₀ Thus, as the incoming radio wave from the transmitter does not contain an audio signal, the gain of the expander 24 gradually decreases, that is, the expander 24 starts to be released, as shown in FIG. The release time Tr (= several tens [ms]) of the expander 24 is considerably shorter (Tr << To) than the predetermined period To (= several hundreds [ms]). Completed during a predetermined period To.
[0053]
Furthermore, the time t ₀ Therefore, the tone squelch circuit described above tries to operate so as to turn off the output of the receiver. However, as described above, until the tone squelch circuit operates, the time t ₀ Takes about 1 [s]. Therefore, the output of the receiver is not turned off by the operation of the tone squelch circuit at least until the predetermined period To elapses. During the predetermined period To, the incoming radio wave itself has sufficient strength as described above, so that the above-described noise squelch circuit does not turn off the output of the receiver. Accordingly, during the predetermined period To, the receiver maintains the output ON state, so that the output signal of the expander 24 is output to the outside via the output terminal 26. However, since the output signal does not include an audio signal, the predetermined period To is a so-called silent period.
[0054]
When the silent engine To ends, the time t ₁ Thus, the incoming radio wave from the transmitter disappears. As a result, the detection unit 22, as shown in FIG. ₁ In this case, a very large noise is output. When this noise is input to the expander 24, the gain of the expander 24 begins to increase gradually, that is, the expander 24 begins to attack, as shown in FIG. In addition, in response to the absence of the incoming radio wave from the transmitter, the noise squelch circuit may ₁ The output of the receiver is turned off with a delay of time Ts corresponding to its own time constant.
[0055]
Here, the time Ts (= several [ms]) required for the noise squelch circuit to turn off the output of the receiver is considerably shorter than the attack time Ta (= several tens [ms]) of the decompressor 24 (Ts). «Ta). Therefore, the noise squelch circuit turns off the output of the receiver while the expander 24 is attacking, that is, while the gain of the expander 24 is not so large, as shown in FIG. As a result, the time until the noise squelch circuit turns off the output of the receiver (time t ₁ Until the time Ts elapses), the level of the noise N output from the output terminal 26 is suppressed.
[0056]
As described above, according to the present embodiment, when the power switch or the talk switch is turned off on the transmitter side, the level of noise that is output until the squelch circuit operates in the receiver, for example, is audible. It can be suppressed to an inconspicuous level. Therefore, a large noise such as the above-mentioned “pop sound” is not output, and comfortable wireless communication can be realized.
[0057]
In addition, the present embodiment basically has a configuration in which the silent period To is provided in a wireless device including a compander. Therefore, for example, even if an existing wireless device is equipped with a compander, the transmitter only adjusts the timing from when the power switch or talk switch is turned off until the transmission output is turned off. Thus, the present embodiment can be realized. In particular, when the transmitter includes a CPU such as the control unit 10 in the present embodiment, the present embodiment can be realized only by changing a program for controlling the CPU.
[0058]
The control unit 10 on the transmitter side is not limited to the CPU, and may be a pure hardware configuration including, for example, various electronic components.
[0059]
In the present embodiment, the receiver output is turned ON / OFF by turning ON / OFF the squelch switch 25 on the receiver side. However, the present invention is not limited to this. For example, instead of the squelch switch 25, a circuit such as an amplifier may be provided, and the output of the receiver may be turned ON / OFF by turning this circuit operation ON / OFF (operation / non-operation).
[0060]
Further, although the tone squelch circuit and the noise squelch circuit are used in combination as the squelch circuit for controlling the ON / OFF operation of the squelch switch 25, the present invention is not limited to this. For example, only the noise squelch circuit may be provided without providing the tone squelch circuit.
[0061]
Further, the above-described carrier squelch circuit may be used instead of the noise squelch circuit. However, as described above, the noise squelch circuit is more conspicuous in terms of audibility than the carrier squelch circuit when the present embodiment is not applied. Therefore, in the receiver including the noise squelch circuit in which such “sounds” are easily noticeable, the present embodiment exerts great power.
[0062]
Further, in the present embodiment, the radio apparatus adopting the FM modulation scheme has been described, but the present invention can also be applied to a radio apparatus employing other modulation schemes. Further, although the transmission target of the wireless apparatus is an audio signal, other video signals or various digital data may be the transmission target.
[0063]
In this embodiment, the press-talk type wireless device is described, but the present invention is not limited to this. However, according to the press-talk type radio apparatus, when the present embodiment is not applied, the “pop sound” is output every time the talk switch is turned off. Accordingly, the present embodiment functions extremely effectively in a press-talk type radio apparatus that frequently outputs such “sounds”. In particular, the effectiveness of the present embodiment becomes even more remarkable when the wireless device performs a press talk type alternating call.
[0064]
In the present embodiment, the transmitter-side voice switch 6, the modulation unit 7, the high-frequency power amplifier 8, and the transmission antenna 9 correspond to the transmission unit described in the claims, and the control unit 10 This corresponds to the transmission control unit described in the claims. In a state where both the power switch and the talk switch are turned on, at least one of them is turned off. This is because the transmission stop command (strictly speaking, this command is given). Corresponding to
[0065]
On the other hand, a part including the receiving antenna 20, the high frequency processing unit 21, the detection unit 22, and the low pass filter 23 on the receiver side corresponds to the receiving unit described in the claims. The attack time Ta and the release time Tr of the expander 24 correspond to the first time lag described in the claims, and the time t ₁ The time Ts until the squelch switch 25 is in the output OFF state corresponds to the second time lag described in the claims.
[0066]
【The invention's effect】
As described above, according to the present invention, when the power switch or talk switch is turned off on the transmitter side, noise due to the absence of incoming radio waves is output from the output terminal at the receiver. It can be suppressed to such an extent that it is not noticeable. Therefore, there is an effect that a comfortable wireless communication can be realized without outputting a large noise such as the above-mentioned “pop sound”.
[0067]
In addition, the present invention basically provides a wireless device equipped with a compander only by providing the above-described silence period. Specifically, after the power switch or the talk switch is turned off on the transmitter side. This can be realized simply by adjusting the timing until the transmission output is turned off. Therefore, the present invention can be realized by a simple remodeling work that only changes the timing as long as an existing transmitter is provided with a compressor. In particular, when the transmitter has a CPU and the CPU adjusts the timing by software, the present invention can be realized only by changing a program for controlling the CPU. effective.
[Brief description of the drawings]
1A and 1B are diagrams showing a schematic configuration of the present embodiment, in which FIG. 1A is a block diagram of a transmitter and FIG. 1B is a block diagram of a receiver;
FIG. 2 is a flowchart showing the operation of the CPU on the transmitter side in the embodiment.
FIG. 3 is a diagram showing an embodiment of the present invention, and is a chart showing the operation timing of each element constituting the transmitter and the receiver.
FIG. 4 is a chart showing operation timing in a conventional wireless device.
[Explanation of symbols]
3 Compressor
6 Voice switch
7 Modulator
8 High frequency power amplifier
9 Transmitting antenna
10 Control unit
20 Receiving antenna
21 High-frequency processing section
22 detector
24 Stretcher
25 Squelch switch
30 Control unit

Claims (3)

A compressor that compresses the amplitude of the original signal to be transmitted based on a predetermined amplitude compression characteristic;
A transmitter for transmitting the signal after compression by the compressor by radio waves;
When the transmission stop command is given from the outside, the radio wave is transmitted without including the original signal for a predetermined period from the time when the transmission stop command is given, and the radio wave is transmitted when the predetermined period ends. A transmission control unit for controlling the transmission unit to stop,
Comprising
The predetermined period is an expander having an amplitude expansion characteristic substantially opposite to the amplitude compression characteristic provided in a wireless receiver as a communication partner, wherein the squelch circuit provided in the wireless receiver receives the radio wave. Longer than the release time of the stretcher having an attack time longer than the time required to transition from the output-on state to the output-off state, depending on the electric field strength,
Wireless transmitter. In a wireless device including a wireless transmitter and a wireless receiver capable of wireless communication with the wireless transmitter,
The wireless transmitter is
A compressor that compresses the amplitude of the original signal to be transmitted based on a predetermined amplitude compression characteristic;
A transmitter for transmitting the signal after compression by the compressor by radio waves;
When a transmission stop command is given from the outside, the radio wave is transmitted without including the original signal for a predetermined period from the time when the transmission stop command is given, and the radio wave is transmitted when the predetermined period ends. A transmission control unit for controlling the transmission unit to stop,
Comprising
The above wireless receiver
A receiving unit that receives the radio wave transmitted from the wireless transmitter and performs predetermined processing on the received signal;
A decompressor that restores the original signal by inputting a signal after processing by the receiver and expanding the amplitude of the input signal based on an amplitude expansion characteristic that is substantially opposite to the amplitude compression characteristic;
When the received electric field strength of the radio wave by the receiving unit is monitored and the received electric field strength is greater than a reference value, the original signal obtained by restoring by the expander is output from a predetermined output terminal. A squelch circuit that is in an output off state that prevents the original signal from being output from the output terminal when the received electric field strength is equal to or less than the reference value;
Comprising
Further, the expander has an attack time longer than a time required for the squelch circuit to transition from the output-on state to the output-off state according to the received electric field strength,
The predetermined period is longer than the release time of the expander,
Wireless device. The squelch circuit extracts a certain noise component included in the received signal by the receiving unit, and determines whether or not the received electric field strength is larger than the reference value based on the magnitude of the noise component. This is a noise squelch circuit.
The wireless device according to claim 2.

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