JP2021197706A - wireless device - Google Patents

Abstract

To enable more reliable tuning in a wireless device that performs the tuning operation when transmission frequency fn is separated from the previously tuned transmission frequency fb by a predetermined ratio or more at the time of new transmission.SOLUTION: Transmission frequency fb is read in s1, transmission frequency fn currently set in s2 is detected, and when a PTT switch is pressed in s3, the flow proceeds to the determination of whether to perform tuning. In s3, when the transmission frequency fb is 11 MHz or more of a predetermined threshold frequency, the flow proceeds to s5 and a predetermined ratio is set to ±1%, and if not, the flow proceeds to s6 and the predetermined ratio is set to smaller ±0.5%. In s5 and s6, it is determined whether the currently set frequency fn is within the range of the predetermined ratio, and if not, tuning operation is performed in s7 and s8. Therefore, when the transmission frequency fn is low, the tuning operation can be performed more reliably.SELECTED DRAWING: Figure 3

Description

The present invention relates to a radio that is taken outdoors and used by connecting to an antenna wire erected at the place, and particularly to a tuning operation of an antenna tuner required in such a case.

In a radio device having a separate antenna, in the case of a stationary radio device, a dedicated antenna is often installed and used. Specifically, it is used by building a tall pole and connecting it to an antenna on which efficient elements are lined up.

On the other hand, in recent years, the capacity of the battery has been increased and the size of the stationary radio has been reduced, and the radio has been released as a radio that can be taken outdoors. Such a radio becomes a radio station by being connected to an antenna wire appropriately erected by the user in a place where the visibility seems to be good. In a simple case, the antenna wire is wound around a rod that can be expanded and contracted like a fishing rod, and is extended to be used as an antenna having a fraction of a wavelength. Therefore, different lengths may be prepared for each operating frequency band.

However, it is also difficult to reconnect the antenna wire every time the operating frequency band is changed. Therefore, an antenna wire having a certain length is erected, and the difference in impedance due to the difference in the operating frequency band is caused. By interposing an antenna tuner with the radio and tuning this antenna tuner, it is matched. The tuning operation outputs the adjustment carrier from the transmitter, outputs it to the antenna line via an attenuator, etc. as appropriate, and measures the reflected wave from the antenna with the SWR (standing wave ratio) measurement circuit to the transmission path. By adjusting the intervening antenna and capacitance, the measured VSWR (voltage standing wave ratio) is generally 1.5 or less, ideally suppressed to 3 or less. The impedance adjustment range is wide, for example, 16.7Ω to 150Ω, so it takes several seconds to several tens of seconds to adjust, and during that time, the indicator indicates that tuning is in progress, and transmission and reception are not possible. ..

Therefore, a typical prior art antenna tuner has been proposed by the applicant in Patent Document 1. In this conventional technique, in an antenna tuner composed of a tuning element of a capacitor and a coil, the circuit constant of the tuning element is automatically tuned so that VSWR is minimized in response to the switching of the operating frequency.

Further, Patent Document 2 also proposes a transmitter in which the automatic antenna coupler is adjusted in response to the switching of the operating frequency.

Jikken No. 63-16192 Special Publication No. 64-3438

The above-mentioned conventional technique automatically tunes the antenna tuner in conjunction with the switching of the operating frequency, and when the operating frequency is switched, that is, when the channel is selected to another station or switched to another band, Tuning operation will be performed. However, in the actual use of a radio, the operating frequency band remains the same, and it is often the case that the frequency is slightly shifted to search for another station, and each time, a time-consuming tuning operation is performed as described above. If you do, you will lose communication opportunities.

Therefore, in many radios, when transmission is started at a new transmission frequency fn, the transmission frequency fn is separated from the previously tuned transmission frequency fb by a predetermined ratio, for example, ± 1% or more. The tuning operation is automatically performed when the press / talk switch is pressed down, and the tuning operation is not performed unless the press / talk switch is separated.

However, when a relatively long antenna wire such as 10 m or 15 m is used, even if it is about ± 1%, VSWR (voltage standing wave ratio) can be suppressed to about 1.5, but such a sufficient length. In the case of an antenna in which the antenna wire cannot be used, the shortening rate is large, that is, the antenna is very short with respect to the wavelength, there is a problem that VSWR (voltage standing wave ratio) cannot be suppressed low. Therefore, even though the tuning operation is automatically performed as described above, it is necessary to perform the tuning operation again forcibly. In the case of reception, reception is possible even if the frequency is slightly deviated, but in the case of transmission, if there is a deviation in tuning, the transmission power is wasted and the reachable range is narrowed.

An object of the present invention is to perform tuning more reliably in a radio that causes an antenna tuner to perform tuning operation when a new transmission is started at a frequency separated from a previously tuned transmission frequency by a predetermined ratio or more. Is to provide a radio that can.

The radio of the present invention is a radio in which the control means causes the antenna tuner to perform a tuning operation when the transmission frequency is separated from the previously tuned transmission frequency by a predetermined ratio or more at the start of transmission. The control means is characterized in that the predetermined ratio is set to be small when the operating frequency band is relatively low and large when the operating frequency band is relatively high.

For example, when operating a radio station outdoors, a radio is connected to an antenna wire installed in a place where the radio station is moved as appropriate. The tension of the antenna wire is not uniform, and the appropriate antenna length changes greatly depending on the operating frequency band. In such a case, an antenna tuner that matches the impedance between the antenna and the radio is provided. The antenna tuner has a built-in, that is, an integrated one, and an external, that is, a separate one in the radio, and the tuning operation is controlled by the control means in the radio.

Normally, when the antenna wire is re-tensioned or the operating frequency band is switched, the impedance may be significantly deviated, and the tuning operation may be forcibly started by operating the tuning button or the like. many. However, for example, it may be better to perform tuning operation even when the frequency is slightly shifted in order to search for a new communication partner while keeping the operating frequency band as it is. On the other hand, the tuning operation takes several seconds to several tens of seconds, and transmission / reception cannot be performed during that period. Therefore, if the tuning operation is automatically (forced) performed every time the frequency is slightly shifted, the communication opportunity is impaired accordingly.

Therefore, in the present invention, when a new transmission is started at a frequency separated from the previously tuned transmission frequency by a predetermined ratio or more, the control means causes the antenna tuner to automatically (force) perform the tuning operation. As a result, in the radio with improved operability, the control means further changes (makes a difference) the predetermined ratio for determining whether or not to perform the tuning operation depending on the operating frequency band. Specifically, when the operating frequency band is relatively low, it is set small, and when it is high, it is set large.

Therefore, at low frequencies with relatively long wavelengths, even if the predetermined ratio is small, the tuning operation is surely performed, and during the subsequent operation, the user feels inconsistency and forcibly performs the tuning operation again. It is possible to reduce the number of cases that must be required and improve operability.

Further, in the radio device of the present invention, the transmission is started by pressing the press talk switch or operating the electric key key.

According to the above configuration, when a new transmission is started at a frequency separated from the previously tuned transmission frequency by a predetermined ratio or more, the antenna tuner is made to perform the tuning operation automatically (forced). At that time, the trigger of the tuning operation is realized by pressing the press talk switch or operating the electric key.

Therefore, the tuning operation is automatic (forced) when the user first presses the press talk switch or operates the key key after shifting the transmission frequency by the predetermined ratio or more. ), The operability of the tuning operation can be improved even if the dedicated tuning button is not provided.

Furthermore, the radio device of the present invention is characterized in that a threshold value is set in the operating frequency band, and the predetermined ratio is switched depending on whether or not the threshold value is equal to or higher than the threshold value.

According to the above configuration, the predetermined ratio, that is, the ratio of the difference between the newly started frequency and the previously tuned frequency for determining whether or not to perform the antenna tuning is the frequency band. However, a threshold is set in the operating frequency band, and the predetermined ratio is aggregated into two values depending on whether or not the threshold is equal to or higher than the threshold. This can simplify control.

Further, in the radio device of the present invention, the threshold value is 10 to 15 MHz.

According to the above configuration, the wavelength is 30 m at 10 MHz, the wavelength is 20 m at 15 MHz, and the 1/4 wavelength is 7.5 m and 5 m, respectively.

Therefore, with respect to the antenna wire having the length that is relatively easy to install, the predetermined ratio for determining whether or not to perform the tuning operation is appropriately set according to whether the wavelength is long or short. be able to.

Furthermore, in the radio of the present invention, the predetermined ratio to the transmission frequency tuned last time is ± 1% or more when the threshold value is 11 MHz or more, and ± 0.5% when the threshold value is less than 11 MHz. It is characterized by the above deviation.

According to the above configuration, when the predetermined ratio for determining whether or not to perform antenna tuning is aggregated from the operating frequency band to the two values, the wavelength is short and the influence of the deviation of the length of the antenna wire is affected. If it is difficult to obtain, set it to a large value at ± 1%, and if the wavelength is long and the effect of deviation is likely to occur, set it to a small value at ± 0.5%. can.

As described above, in the radio of the present invention, when the transmission frequency is separated from the previously tuned transmission frequency by a predetermined ratio or more at the start of transmission, the control means is tuned to the antenna tuner. In a radio that is designed to improve operability by automatically (forced) operation, the control means uses the predetermined ratio when the operating frequency band is relatively low. If it is small and high, set it large.

Therefore, at low frequencies with relatively long wavelengths, even if the predetermined ratio is small, the tuning operation is surely performed, and during the subsequent operation, the user feels inconsistency and forcibly performs the tuning operation again. It is possible to reduce the number of cases that must be done and improve the operability.

It is a block diagram of the transmitter in the radio which concerns on one Embodiment of this invention. It is a block diagram which shows one configuration example of the antenna tuner of the said transmitter. It is a flowchart for demonstrating the tuning operation of the antenna tuner. It is a block diagram of the transmitter in the radio which concerns on other embodiment of this invention.

(Embodiment 1)
FIG. 1 is a block diagram of a transmitter 1 in a radio device according to an embodiment of the present invention. The present invention is characterized in controlling the tuning operation of the antenna tuner for transmission, and if the impedance with the antenna is matched by the antenna tuner, the reception performance is improved, but the configuration for reception is arbitrary. Therefore, the description thereof will be omitted.

The audio signal collected by the microphone 21 is converted into a digital signal by the analog / digital converter 22, and is converted into a modulated signal by a predetermined modulation method in the modulation circuit 23 composed of a DSP, FPGA, or the like. The modulated signal is converted into an analog high-frequency signal by the digital / analog converter 24, and band-limited by a bandpass filter (hereinafter referred to as BPF) 25. The band-limited transmission signal in the BPF 25 is power-amplified by the amplifier 27 after the input level to the amplifier 27 is limited by the automatic level adjustment circuit (hereinafter referred to as ALC) 26 so that the waveform is not distorted. , Is transmitted from the antenna 29 via a low-pass filter (hereinafter referred to as LPF) 28. An antenna tuner 3 is interposed between the LPF 28 and the antenna 29.

Switching switches 41 and 42 are provided before and after the antenna tuner 3, and the control unit 5 as a control means switches and controls the switches 41 and 42 to pass through the built-in antenna tuner 3. It is switched whether to pass through the through line 43 provided in parallel. The through line 43 is used when connecting an antenna having good impedance matching, when impedance matching cannot be obtained even through the antenna tuner 3, or when avoiding the influence of heat generation of the antenna tuner 3 or the like. It is used when directly connecting 29 and a wireless circuit.

An operation unit 6 and a display unit 7 are connected to the control unit 5. The display unit 7 displays the transmission / reception frequency and the signal level, and also displays that the tuning operation, which will be described later, is in progress. In addition to the various operation buttons (including the touch panel) 61 mounted on the main body, the operation unit 6 includes a press talk switch 62 integrated with the microphone 21, an electric key 63 that can be separately connected as an option, and the like. included. In response to the operation of the operation button 61, the control unit 5 performs various control operations and display operations. When the press talk switch 62 is pressed, the control unit 5 modulates and transmits the audio signal collected by the microphone 21, and when the press release is released, the control unit 5 is in the reception state. In the communication in the CW mode, when the break-in function is ON, the control unit 5 starts transmission by operating the electric key 63, and turns the modulation signal ON / OFF in the modulation circuit 23 according to the operation. ..

FIG. 2 is a block diagram showing an example of the electrical configuration of the antenna tuner 3. In this antenna tuner 3, the inductors L1, L2, L3, L4 interposed in series with the signal line 30 between the input terminal 31 and the output terminal 32 are selectively arranged by switches S1, S2, S3, S4 in parallel. The capacitors C1, C2, C3, and C4, which are short-circuited and connected in parallel to the input side of the inductor L1, are selectively ground-faulted by the series switches S11, S12, S13, and S14, so that the tuning operation (tuning operation ( Impedance matching) is performed.

For the tuning operation, the signal line 30 is provided with a SWR measurement circuit 33, and an attenuator 34 is provided on the upstream side thereof. Bypass switches 35 and 36 are provided before and after the attenuator 34, and when tuning operation is performed by the control unit 5, the bypass switches 35 and 36 are connected to the attenuator 34 side and are predetermined from the transmission circuit. The carrier component of the above is attenuated to, for example, 1/10, and is input from the SWR measurement circuit 33 to the rows of inductors L1, L2, L3, L4 and the rows of capacitors C1, C2, C3, C4. The control unit 5 connects the bypass switches 35 and 36 to the through line 37 side during normal transmission. In FIG. 2, the configuration shown by the broken line will be described in the second embodiment.

In the tuning operation, as described above, the control unit 5 switches the bypass switches 35 and 36 to the attenuator 34 side, generates a carrier component at the transmission frequency in the modulation circuit 23, and detects it in the carrier detection circuit 38. Then, while monitoring VSWR by the SWR measurement circuit 33, switches S1 to S4; S11 to S14 are appropriately switched, and automatic tuning is performed so that the VSWR is minimized. Meanwhile, the display unit 7 indicates that the tuning operation is in progress. When the tuning operation is completed, the control unit 5 switches the bypass switches 35 and 36 to the through line 37 side to enable transmission.

This tuning operation can also be forcibly performed by operating a tuning button (not shown). However, in some portable radios, the area of the operation panel is small. In that case, the dedicated tuning button is not provided, and in response to the operation of the operation button 61, the control unit 5 displays the menu screen on the display unit 7. After expanding and displaying the setting screen, the tuning operation will be selected from the mode selection. Particularly suitable for such a case, in order to improve the operability of the tuning operation, the control unit 5 of the present embodiment performs the tuning operation as appropriate by performing the operation as shown in FIG.

FIG. 3 is a flowchart for explaining the tuning operation. In step s1, the transmission frequency fb tuned last time is read from the memory or the like. In step s2, the currently set frequency fn is detected. In step s3, it is determined whether or not the press talk switch 62 is pressed, and the process returns to step s2 until the press talk switch 62 is pressed, that is, until the transmission is started, and the currently set frequency fn is updated. In the case of communication in the CW mode, in step s3, instead of pressing the press talk switch 62, a short press of the key 63 is detected.

When the press talk switch 62 is pressed or the electric key 63 is operated in step s3, the previous transmission frequency fb read in step s1 in step s4 is a predetermined threshold frequency. It is determined whether or not the frequency is 11 MHz or higher, and if so, the process proceeds to step s5, and the predetermined ratio that becomes the determination threshold value for whether or not to perform the tuning operation, that is, the difference between the frequencies fn and fb is ± of the frequency fb. If it is not set to 1%, the process proceeds to step s6, and the determination threshold is set to a smaller ± 0.5%.

In steps s5 and s6, it is determined whether or not the current set frequency fn in step s2 is within the range of ± 1% and ± 0.5% of the previous transmission frequency fb, respectively, and is not included. In this case, in step s7, the switches 35 and 36 are switched to the attenuator 34 side, and the tuning operation is started. In the tuning operation, the switches S1 to S4; S11 to S14 are switched, and in step s8, it is determined whether the VSWR may be minimized and the tuning operation may be terminated. If the tuning operation is to be continued, the process returns to step s7. .. When it is determined in step s8 that the tuning operation is completed, the process proceeds to step s9, and the current set frequency fn is set to the previously tuned transmission frequency fb and stored in a memory or the like.

In step s10, the actual voice call is enabled, that is, the switches 35 and 36 are switched to the through line 37 side to end the process. In steps s5 and s6, when the current set frequency fn is within the range of ± 1% and ± 0.5% of the previous transmission frequency fb, the tuning operation of steps s7 and s8 and the transmission frequency of step s9 are performed. The update operation of fb is not performed, and the transmission operation of step s10 is performed directly.

In the transmitter 1 of the present embodiment, as described above, when a new transmission is started at a frequency fn separated from the previously tuned transmission frequency fb by a predetermined ratio or more, the control unit 5 controls the antenna tuner 3 In a radio with improved operability, the predetermined ratio, which is the determination threshold for whether or not to perform the tuning operation, is changed depending on the operating frequency band (forcibly). Make a difference). Specifically, in the above example, the predetermined ratio is fb ± 1%, which is a relatively large value when the operating frequency band (fb) is 11 MHz or higher, which is a relatively high frequency. When the frequency is less than 11 MHz, which is a relatively low frequency, the range is set to a range of fb ± 0.5%, which is a relatively small value.

Here, the tuning operation of FIG. 3 takes several seconds to several tens of seconds, during which transmission and reception cannot be performed. Therefore, if the tuning operation is automatically (forced) performed every time the frequency is slightly shifted, the communication opportunity is impaired accordingly. On the other hand, as described above, the predetermined ratio, which is the determination threshold for whether or not to perform the tuning operation, is switched, and at a high frequency with a relatively short wavelength, the predetermined ratio is set to fb ± 1%. By not performing the tuning operation within that range, the number of times the tuning operation is performed can be reduced and the communication opportunity can be expanded. On the other hand, at low frequencies with relatively long wavelengths, if an antenna very short with respect to the wavelength is used, tuning may not be covered within the range of fb ± 1%. Therefore, the predetermined ratio, which is the determination threshold value, is set to a smaller fb ± 0.5%, and after the tuning operation is performed, the user must feel inconsistency and forcibly perform the tuning operation again. It is possible to reduce the number of cases and improve operability.

Further, in the radio of the present embodiment, when transmission is started at a frequency separated from the previously tuned transmission frequency fb by a predetermined ratio or more, the control unit 5 automatically tunes the antenna tuner 3 ( Since it is assumed that the press talk switch 62 is first pressed or the electric key key 63 is short-pressed, a dedicated tuning button is provided to trigger the tuning operation. Even if it is not done, the operability of the tuning operation can be improved.

Furthermore, the predetermined ratio, which is the determination threshold for whether or not to perform antenna tuning, may be appropriately determined according to the frequency band. However, in the radio of the present embodiment, the operating frequency band is described above. As an example, a threshold value of 11 MHz is set, and the predetermined ratio is switched between, for example, fb ± 1% and fb ± 0.5% depending on whether or not the threshold value is equal to or higher than this threshold value. Therefore, by aggregating the determination threshold values into these two values, the control by the control unit 5 can be simplified. The 11 MHz is assumed to divide the operating frequency band into 1.8 to 10 MHz and 14 to 50 MHz.

Further, in the above example, the threshold frequency for switching the determination threshold is 11 MHz, but it is preferably 10 to 15 MHz. This is because the wavelength is 30 m at 10 MHz, the wavelength is 20 m at 15 MHz, and the 1/4 wavelength is 7.5 m and 5 m, respectively. This is because the determination threshold value for whether or not to perform the tuning operation can be appropriately switched according to whether the transmission wavelength of the above is long or short.

Then, in dividing the determination threshold for whether or not to perform antenna tuning into the above two from the operating frequency band, the threshold frequency is set to 11 MHz, and the wavelength is shorter than that, and the influence of the deviation in the length of the antenna wire is unlikely to occur. In the case, it is set to be large at ± 1%, and when the wavelength is long and the influence of deviation is likely to occur, it is set to be small at ± 0.5%, so that it is possible to determine whether or not the tuning operation is performed more appropriately.

In the present embodiment, the threshold frequency for switching the determination threshold value is one of the above 11 MHz, but two or more, that is, the operating frequency band may be divided into three or more. Further, although the determination threshold values are set to ± 1% and ± 0.5%, other values may be used. For example, the higher frequency is greater than ± 1%, for example ± 1.5%, and the lower frequency is less than ± 0.5%, for example ± 0.3%.

(Embodiment 2)
FIG. 4 is a block diagram of the transmitter 1a in the radio according to another embodiment of the present invention. The transmitter 1a is similar to the transmitter 1 described above, and the corresponding parts are designated by the same reference numerals, and the description thereof will be omitted. The transmitter 1 described above is different in that the antenna tuner 3 is built in the radio, that is, integrated, whereas in the transmitter 1a, the antenna tuner is externally configured, that is, is composed of a separate body.

Therefore, in the transmitter 1a, the antenna tuner is connected to the connector for connecting the antenna via the coaxial cable, or the antenna is connected. Further, in FIG. 2, the configuration of the broken line is added to the antenna tuner adapted to the transmitter 1a. That is, the through line 39 and the bypass switches 35 and 38 corresponding to the through line 43 and the switches 41 and 42 in the transmitter 1 of FIG. 1 are provided. The bypass switch 35 has three individual contacts, the bypass switch 38 is interposed in the final stage of the signal line 30. The switching of the bypass switches 35 and 38 and the tuning operation described above may be performed by the control unit 5 on the transmitter 1a side, but a control unit is also provided on the antenna tuner side and they cooperate with each other. You may do it.

With such a configuration, the influence of loss and heat generation due to the antenna tuner can be reduced, and it is particularly suitable when the transmission power is increased.

1,1a Transmitter 21 Microphone 22 Analog / Digital Converter 23 Modulation Circuit 24 Digital / Analog Converter 25 BPF
26 ALC
27 amplifier 28 LPF
29 Antenna 3 Antenna tuner 33 SWR measurement circuit 34 Attenuator 35, 36, 38 Bypass switch 38 Carrier detection circuit 39, 43 Through line 41, 42 Changeover switch 5, 5a Control unit 6 Operation unit 61 Operation button 62 Press talk switch 63 Electric key 7 Display

Claims (5)

In a radio device in which the control means causes the antenna tuner to perform tuning operation when the transmission frequency is separated from the previously tuned transmission frequency by a predetermined ratio or more at the start of transmission.
The control means is a radio device, wherein the predetermined ratio is set small when the operating frequency band is relatively low and large when the operating frequency band is high. The radio according to claim 1, wherein the transmission is started by pressing the press talk switch or operating the electric key key. The radio according to claim 1 or 2, wherein a threshold value is set in the operating frequency band, and the predetermined ratio is switched depending on whether or not the threshold value is equal to or higher than the threshold value. The radio according to claim 3, wherein the threshold value is 10 to 15 MHz. The predetermined ratio with respect to the transmission frequency tuned last time is characterized by a deviation of ± 1% or more when the threshold value is 11 MHz or more and ± 0.5% or more when the threshold value is less than 11 MHz. The radio according to claim 3 or 4.

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