JPH056379B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a tone oscillation circuit with improved rise characteristics.

Tone squelch radios, especially transceivers, squelch based on the presence or absence of a tone signal.
Even if the pre-talk switch is pressed to enter the transmitting state, if the rise of the tone signal is delayed, the beginning of the audio signal may not be reproduced on the receiving side. FIG. 1 is a schematic diagram of the transmitting side of this type of radio equipment, where 10 is a tone oscillation circuit, 21 is an amplifier that amplifies its output (tone signal), and 22 is an amplify audio signal from a microphone 23. An amplifier 24 is a modulation circuit that modulates the carrier with a tone signal and an audio signal, 25 to 27 are multipliers that multiply the output frequency of the modulation circuit 24, 28 is a power amplifier, and 29 is an antenna for both transmission and reception.

The tone oscillation circuit 10 includes a state variable band pass filter (BPF) 11, a switch SW ₁ , and an amplifier 1.
2, forming an oscillation loop that closes switch SW ₁ at transmission time (T). The problem with this oscillator circuit 10 is that since the BPF 11 is of the state variable type, the rise time is slow, and after turning on switch SW ₁ ,
The point is that steady oscillation does not occur until 100 msec has passed. However, the speaker may start speaking immediately after pressing the pre-talk switch (not shown), and if it is too early, switch SW ₁ will turn on in conjunction with the pre-talk switch and the beginning of the voice will start 100 msec later. may be input to the microphone 23. In such a case, the receiving side does not release the squelch unless a tone signal is detected, so the beginning of the audio immediately after the start of transmission is cut off, making it difficult to hear.

The present invention aims to improve the rise characteristics of a tone oscillation circuit in order to solve the above-mentioned problem of tone squelch.

The present invention configures an oscillation loop by inputting the output of a state variable bandpass filter to an amplifier via a first switch during transmission, and feeding back the output of the amplifier to the input of the filter. In a tone oscillation circuit that continuously generates a tone signal of a predetermined frequency during a transmission period from The second switch linked with the first switch is activated only at the start of transmission, and the trigger pulse generated by the pulse generating circuit is applied to the input stage of the filter. This will be explained in detail with reference to the illustrated embodiment.

FIG. 2 is a schematic block diagram of a tone oscillation circuit 10 showing an embodiment of the present invention, in which 13 is an added pulse generator and SW ₂ is a similarly added switch. This switch SW ₂ operates in conjunction with the switch SW ₁ and is used to start the pulse generator 13.
The pulse generator 13 is single-shot, as will be described later, and generates a trigger pulse T-out of a predetermined time width only once at the start of transmission. This trigger pulse T-out is
It is forcibly added to the input of the BPF 11 to hasten the rise of the tone signal BPF out.

FIG. 3 is a typical circuit diagram of the state variable type BPF 11, where A ₁ to A ₃ are differential amplifiers, and VR is a variable resistor for frequency determination. The reference voltages of differential amplifiers A ₁ to _{A 3} are all V _DD /2, and the input in of first stage amplifier A ₁ is
is the output of amplifier 12. This first stage amplifier A ₁
The output has the characteristics of a high-pass filter and becomes the input to the next stage differential amplifier _A2 . The output of the final stage differential amplifier _A3 has the characteristics of a low-pass filter, but when it is fed back to the differential amplifier _A1 through the resistor _R1 that determines the BPF width, the output BPF of the amplifier _A2
out becomes a band-limited waveform. At this time the resistance
The oscillation frequency of the tone signal is determined by the value of VR.

FIG. 4 is a circuit diagram including the amplifier 12, where A ₄ is a differential amplifier that is the center of the amplifier 12. This circuit configuration corresponds to the tone oscillation circuit 10 in FIG.

FIG. 5 shows a specific circuit example corresponding to the embodiment shown in FIG. 2, and the BPF 11 and amplifier 12 are the same as in FIG. 4. The added pulse generator 13 includes switches SWA and SWB that connect the input I and output O terminals when the C terminal becomes H (high) level, and an integrating circuit INT consisting of a resistor R ₀ and a capacitor C ₀ . The switch SWA attempts to pass the power supply voltage V _DD (8V) applied to the input terminal in1 during the transmission period. The switch SWB grounds the output of the switch SWA after a certain time t from the start of transmission so that it is not output. The integrating circuit INT determines this time t, and charges the capacitor C ₀ through the resistor R ₀ with the voltage B applied to the input terminal in2.
The added switch SW ₂ applies the voltage of the power supply B to the C terminal of the switch SWA and the integrating circuit INT during transmission (T). Therefore, when the switch SW ₂ is set to the T side, the pulse generator 13 outputs a trigger pulse T for a certain period of time t.
Only one -out is generated and this is added to the input stage of the BPF 11.

FIG. 6 is a time chart showing the signal waveforms of each part and the operating states of the switches. tone signal
BPF is normally set in the range of 67 to 250.3 Hz, and its waveform is, for example, a sine wave with an amplitude of 1 V _pp centered at V _DD /2. On the other hand, the trigger pulse T-out
is a single rectangular wave with an amplitude of 8V and a pulse width t=20 to 40 msec. Under these conditions, the rise time τ from when the switches SW ₁ and SW ₂ are turned on until the tone signal BPF out reaches a steady level is shortened to 10 msec according to actual measurements. This has little to do with the frequency of the tone signal. Incidentally, with the configuration shown in Figure 4 (conventional example), the rise time is 500 msec at 67 Hz.
It was 300msec at 151.4Hz and 140msec at 250.3Hz.

The trigger pulse T-out must rise rapidly in synchronization with the switch _SW2 . However, when the falling edge coincides with the rising edge of the output of the amplifier 12, the two cancel each other out and the oscillation loop must start from 0 again, so the width t of the trigger pulse is different from the period of the tone signal BPF out to be obtained. do it like this. However, since the amplitude of the trigger pulse is as high as V _DD =8V, if the width t is too long, the waveform of BPF out will be distorted, so at the above frequency, 20 to 40 ms is a rough guide. Of course, on the contrary, it may be shorter than the period of the tone signal.

As described above, according to the present invention, a single trigger pulse having a rectangular waveform whose pulse width is different from the period of the tone signal is injected into the input of the state variable BPF of the tone generator at the start of transmission. Therefore, the period of the trigger pulse is not affected by other circuits such as filters, and the rise characteristics of the tone signal are reliably improved.This makes it possible to cut the beginning of the audio signal with a squelch even in the absence of a tone signal on the receiving side. This has the advantage of eliminating the inconvenience of doing so.
In addition, the period of the trigger pulse can be determined simply by adjusting the pulse width of the rectangular waveform pulse in the pulse generation circuit, so the operation is simple.

[Brief explanation of the drawing]

Fig. 1 is a schematic block diagram showing the transmitting side of a conventional tone squelch type radio device, Fig. 2 is a schematic block diagram showing an embodiment of the present invention, and Fig. 3 is a state variable type radio device.
4 is a circuit diagram showing an example of the conventional tone oscillator of FIG. 1, FIG. 5 is a circuit diagram of a specific example corresponding to the embodiment shown in FIG. 2, and FIG. The figure is a time chart showing the operation. In the figure, 10 is a tone oscillator, 11 is a state variable band pass filter, 12 is an amplifier, 13 is a pulse generator, SW ₁ is a first switch, and W ₂ is a second switch.

Claims (1)

[Claims] 1. When transmitting the output of the state variable type bandpass filter, input it to the amplifier via the first switch,
Further, in a tone oscillation circuit that forms an oscillation loop by feeding back the output of the amplifier to the input of the filter, and continuously generates a tone signal of a predetermined frequency from the filter during a transmission period, the pulse width is equal to the tone signal. A pulse generation circuit that outputs a single pulse in the form of a rectangular wave different from the period of A tone oscillation circuit characterized in that the tone oscillation circuit is configured to apply a triggered pulse to an input stage of the filter.