JPH0323016B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Application of the Invention] The present invention relates to a communication device in which it is necessary to select a radio wave mode (radio wave type) according to transmission and reception frequencies.

[Background technology]

In amateur radio equipment, etc., a frequency is set by a frequency setting means, and at the same time, a radio wave mode determined according to the frequency is selected by a mode changeover switch.

However, as shown in FIG. 1, since a wide variety of radio wave modes exist consecutively in a narrow band, operation is complicated and may cause erroneous operation.

[Purpose of the invention]

The present invention has been made in consideration of the above facts, and an object of the present invention is to obtain a communication device that is easy to operate and can prevent erroneous operations.

[Structure of the invention]

In the communication device according to the present invention, the mode determining means compares the transmission and reception frequencies set by the frequency setting means and the boundary frequency of the radio wave mode stored by the boundary frequency storage means, and determines which radio wave mode the mode belongs to. It is now possible to determine whether
When the radio wave mode is determined, the mode switching means switches the radio wave mode of the communication device accordingly.

[Embodiments of the invention]

FIG. 2 shows a partial block diagram of a communication device according to a first embodiment of the present invention.

In this first embodiment, the frequency setter 10 sets the transmission and reception frequencies, and the mode discriminator 12
It is designed to output a voltage signal corresponding to the set frequency of the heel. Further, the frequency setter 10 outputs PLL data corresponding to the set frequency to the PLL circuit 11. This PLL circuit 11 is
It constitutes a local oscillator (not shown) for transmitting or receiving radio waves at a set frequency. Note that the lock voltage that varies depending on the frequency may be supplied to the mode discriminator 12 as a voltage corresponding to the set frequency from the PLL circuit 11 instead of from the frequency setter 10, as shown by the dotted line.

On the other hand, the mode discriminator 12 is configured to receive voltages from boundary value generators 14 to 18 that output constant voltages corresponding to the boundary frequencies of radio wave modes.

The mode discriminator 12 compares the input voltage from the frequency setter 10 and the voltage values from the boundary value generators 14 to 18, and determines which radio wave mode (the mode shown in FIG. 1) the set frequency belongs to. . This determined mode signal is input to the mode switching circuit 22, and the analog switch 22A is switched depending on the mode.
can now be switched.

Here, the automatic side terminal 24A of the operation mode changeover switch 24 that changes between automatic and manual is connected to the control terminal 22C of the analog switch 22A, and the manual side terminal 24B is connected to the manual changeover switch 26.
It is connected to the common terminal 26C of. The common terminal 24C of this changeover switch is supplied with a radio wave mode common voltage from a power source (not shown). Further, the non-common terminals of the analog switch 22A and the manual changeover switch 26 are connected in accordance with each radio wave mode, and power is supplied to a circuit (not shown) corresponding to each radio wave mode.

Therefore, when the operation mode changeover switch 24 is set to the manual side, the mode common voltage is supplied to the circuit corresponding to the radio wave mode switched by the manual changeover switch 26.

When the operation mode switch 24 is set to the automatic side, the analog switch 22A is automatically switched according to the frequency set by the frequency setter 10, and the mode common voltage is supplied to the circuit corresponding to the radio wave mode.

In the first embodiment, the frequency setter 10 and the boundary value generators 14 to 18 may output digital data. Further, the frequency step from the frequency setter 10 may be automatically switched using the radio wave mode data determined by the mode discriminator 12.

Next, FIG. 3 shows a second embodiment of the present invention, in which a microcomputer 28 is used.

Signals from a frequency setting section 32, a step setting key 34, a radio wave mode setting key 36, and an operation mode setting key 38 are input to the input interface 30 of the microcomputer 28. The frequency setting section 32 includes a hand switch, a memory write switch for writing frequencies into each channel, a channel selection switch for selecting each channel, a VFO knob, and a circuit that generates pulses by rotating the VFO knob. ing. Further, the step setting key 34 is a key for setting the amount of change when the frequency is digitally changed by the pulse, and the amount of change is determined depending on whether it is on or off. Therefore, the microcomputer 28 can calculate the set frequency based on the input signals from the frequency setting section 32 and the step setting key 34.
The radio wave mode setting key 36 is used to set the radio wave mode (FM, USB, LSB, CW) during manual operation. Further, the operation mode setting key 38 is used for setting automatic operation mode and manual operation mode.

The microcomputer 28 includes a central processing unit (CPU) 40 and a read-on memory (ROM) 4 connected to this via a bus.
2, a random access memory (RAM) 44, an input interface 30, and an output interface 46.

From the output interface 46, a PLL circuit 48, a mode voltage switching circuit 50, and indicators 52 and 5 are connected.
The signal is output to 4. this
The PLL circuit 48 is configured to output a signal of a predetermined frequency calculated by the microcomputer 28, and is used as a local oscillation circuit of a communication device. The mode voltage switching circuit 50 is configured to switch the connection in response to a radio wave mode signal from the microcomputer 28 so that the mode common voltage is supplied to a circuit corresponding to the radio wave mode. Signals are also input from the mode switching circuit 50 to the display 52, which displays each radio wave mode, automatic operation mode, and step switch on. Further, the display 54 is adapted to display the frequency calculated by the microcomputer 28 (current frequency).

Next, the software of the microcomputer 28 will be explained with reference to FIG.

FIG. 4 shows the configuration of the software, in which the operation mode switching means 56 reads whether the operation mode setting key 38 is turned on or off, and when it is turned off, displays the automatic operation mode on the display 52. Turn off.

Next, the radio wave mode control means 58 reads whether any of the radio wave mode setting keys 36 are on, and stores the mode in the RAM storage area 44a. Next, the mode voltage switching circuit 50 is operated in accordance with this mode, the radio wave mode is displayed on the display 52, and the mode common voltage is supplied to the circuit corresponding to the radio wave mode.

Next, the step information creation means 60 reads the on/off status from the step setting key 34 and turns on/off the step display on the display 52 in response to this. Next, the step information creation means 60 turns on and off the step setting keys and the RAM storage area 4.
From the combination with the radio wave mode stored in 4a,
Referring to a table previously stored in the ROM 42, a step value is determined and stored in the RAM storage area 44b.

Next, the frequency calculation control means 62 reads the frequency information from the frequency setting section 32 and stores it in the RAM storage area 4.
Temporarily store that information in 4d. Next, the frequency calculation control means 62 calculates the frequency from the frequency information stored in the RAM storage area 44d and the step value stored in the RAM storage area 44b, stores this frequency in the RAM storage area 44c, and displays the frequency display 54. Displays the heel frequency.

Next, the PLL data calculation means 64 calculates the PLL circuit 4 from the frequency stored in the RAM storage area 44c.
8 is calculated and output to the PLL circuit 48.

Next, the process returns to the beginning, and if the manual operation mode is selected, the above process is repeated.

Next, a case where the operation mode setting key 38 is turned on will be explained.

When the operation mode switching means 56 reads that the operation mode setting key 38 is on,
The automatic operation mode display is turned on on the display 52, and the radio wave mode determining means 66 reads the boundary frequency information f ₁ to f ₃ of each radio wave mode stored in advance in the ROM storage area 42a and the RAM storage area 44c.
It is determined to which radio wave mode (the mode shown in FIG. 1) the frequency belongs. This determined mode is input to the radio wave mode control means 58 and stored in the RAM storage area 44a.

Next, the mode voltage switching circuit 50 is operated in accordance with this mode, the radio wave mode is displayed on the display 52, and the mode common voltage is supplied to the circuit corresponding to the radio wave mode.

The subsequent step information processing and frequency calculation control processing are the same as those in the manual operation mode (the operation mode setting key is off), and are based on the frequency information from the frequency setting section 32 and the RAM storage area 44d.
The contents of the RAM storage area 44c are sequentially rewritten, and then the process returns to the beginning, and if the automatic operation mode is selected, the above process is repeated.

Next, the operation mode switching means 56, the radio wave mode determining means 66, and the processing routine in the automatic operation mode will be explained according to the flowchart shown in FIG.

In step 100, it is determined whether the operation mode setting key 38 is on or off. The operation mode is changed each time the operation mode setting key is pressed once. Therefore, if this is on, in step 102, it is determined that if the previous mode was automatic mode, it has been changed to manual mode,
Next, in step 104, the automatic display 52 is turned off, and the processing of this routine is ended.

In step 100, press the operation mode setting key 3.
If it is determined that 8 is off, step 1
In step 06, it is determined whether the automatic display 52 is on or off, and if it is off, the manual mode is being continued, and the routine ends. If the automatic display 52 is on, the automatic mode is continuing, and in step 108, it is determined whether or not the set frequency f has changed by checking the data in the RAM storage area 44d (this data will be rewritten by another routine). (The operation is performed as described above in the manual operation mode)
Discrimination is made by If the set frequency has not changed, there is no need to change the radio wave mode, and the process ends.

If it is determined in step 102 that the mode has been changed to automatic operation mode, then in step 110 the automatic display 52 is turned on. After turning on this, or if it is determined in step 108 that the set frequency f has changed, the set frequency f
and the boundary frequency data f ₁ of the ROM storage area 42a
~ Compare _f3 to determine the radio wave mode. f ₁ to f ₃ are the values shown in FIG.

That is, the values of f and f ₁ are compared in step 112, and if f<f ₁ , the process is performed in step 114.
Set the radio wave mode to CW. If f
When ≧f ₁ , in step 116 f
The value of _f2 is compared with the value of f2, and if f< _f2 , the radio wave mode is set to USB in step 118. If f≧f ₂ , step 12
0, the values of f and _f3 are compared, and if f< _f3 , the radio wave mode is set to FM in step 122.
Set to . If f≧f ₃ , the radio wave mode is set to LSB in step 124.

When the processing of steps 114, 118, 122 or 124 is completed, the radio wave mode information is stored in the RAM storage area 44a in step 126. Next, in step 128, this mode information is output to the mode voltage switching circuit 50, and in step 130, a frequency step value is set based on this mode and the on/off state of the step setting key 34, and is stored in the RAM storage area 44b. This completes the processing of the routine.

Next, FIG. 5 shows a third embodiment of the present invention, and corresponds to FIG. 4.

In this third embodiment, the PLL data calculation means 6
4, the actual frequency from the PLL circuit 48 is answered and outputted to the frequency display 54, and the radio wave mode discriminating means 66 uses this frequency data. Along with this, the frequency calculation control means 62
is not output to the display 54.

The other points are the same as in the second embodiment.

Note that when any radio wave mode setting key 36 is turned on, the automatic operation mode may be canceled and the mode may be changed to a manual operation mode.

In addition, in the second and third embodiments, the boundary frequency information
f ₁ to _{f 3} are stored in advance in the ROM storage area 42a, but this is not limited to the ROM. Data can also be input from a key switch or the like and stored in the RAM, or can be set using hardware such as a diode matrix and loaded onto the board. You can also input from

〔Effect of the invention〕

The communication device according to the present invention has a configuration that automatically switches the radio wave mode according to the frequency set by the frequency setting means or the actual frequency, so it is easy to operate and has the advantage that there is no possibility of erroneous operation. It has a good effect.

[Brief explanation of the drawing]

Figure 1 is a correspondence diagram between frequency and radio wave mode, Figure 2
3 is a partial block diagram showing a first embodiment of a communication device according to the present invention, FIG. 3 is a block diagram corresponding to FIG. 2 showing a second embodiment of the present invention, and FIG. A functional block diagram of the computer software, Figures 5 and 6 are flowcharts showing the operation mode switching means and processing in the automatic operation mode, and Figure 7 corresponds to Figure 4 showing the third embodiment of the present invention. FIG. 3 is a functional block diagram of the software. 10...Frequency setter, 12...Mode discriminator, 1
4 to 18...Boundary value generator, 22...Mode switching circuit, 32...Frequency setting section, 34...Step setting key, 50...Mode voltage switching circuit, 58...Radio wave mode control means, 60...Step information creation means, 62
...Frequency calculation control means, 66...Radio wave mode discrimination means.

Claims (1)

[Claims] 1. In a radio communication device in which the mode of transmission and reception radio waves is determined by the operating frequency, a frequency setting means for setting the operating frequency, and a boundary frequency storage means for storing the boundary frequency of the operating mode of the operating frequency. , mode determining means for comparing the set frequency set by the frequency setting means and the frequency stored in the boundary frequency storage means to determine to which radio wave mode the set frequency belongs; and an output of the mode determining means. A wireless communication device characterized by having a mode switching means for switching the operating radio wave mode of the communication device.