JP2681799B2 - Multi-channel selective calling device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-channel selective calling device for efficiently and individually calling subscribers moving in a wide area.

(Prior Art) Conventionally, in order to use a multi-channel selective calling device in a wide area, it is performed by switching to a radio channel in a service receiving area and standby reception is performed. However, the time slots of signals vary depending on the group. is there. Also,
Even on the same radio channel, there were times when the call was wasted without a call because time slots differ depending on the region.

(Problems to be Solved by the Invention) However, if the time slot for transmitting the calling signal differs depending on the group, the radio wave of an area not registered by itself as a service area is received, and therefore a time slot without calling is received. There was a problem that it wasted a waiting period and missed an important call.

The present invention solves such a problem, and provides a new multi-channel selective calling device capable of automatically waiting for a radio channel for calling its own device when the reception input is lowered. It is intended.

(Means for Solving the Problems) In order to achieve the above object, the present invention divides one frame forming one transmission unit into a plurality of groups, and the upper bits are formed of group IDs different from each other. , Call ID whose low-order bits consist of the subscriber ID
A multi-channel switching radio receiver for receiving a radio signal including a signal, a call display circuit for notifying an incoming call, and a signal receiving section for operating the call display circuit when the call ID of the own device is detected from the radio signal. In a multi-channel selective calling device including: a plurality of receiving channel numbers corresponding to a plurality of frequency bands receivable by the wireless receiver, a time slot number assigned to each receiving channel, and high-order bits. RO that stores the call ID of the own machine, which consists of the ID and the lower bits are composed of the subscriber ID of the own machine
M memory and a frequency synthesizer for switching the setting of the reception frequency of this wireless receiver, and further, the signal receiving unit, when the receiving channel is switched and the frame synchronization is obtained, the upper bit of the calling ID of the wireless signal Corresponds to the receiving channel number with frame synchronization by the group number judgment circuit that takes in and judges whether it is the group ID number of the own machine and the judgment signal that is judged to be the group ID number of the own machine The CPU that takes in the time slot of the number to be set from the ROM memory and sets it as the time slot during reception, and the subscriber ID of the own device can be detected from the radio signal from the frame-synchronized receiving channel. And a call waiting circuit that waits for.

(Operation) With the above-described functional configuration, the present invention operates as follows.

(1) Since multiple radio channel numbers and time slots are assigned to each group, when signals cannot be received on the used channels and time slots, the channels stored in the ROM are sequentially switched. It can receive and acquire a new channel.

(2) Even if you switch channels and receive signals,
When the groups of given time slots are different, it can stop receiving and switch to the correct channel.

(Embodiment) FIGS. 1 to 3 show the structure of an embodiment of the present invention. FIG. 2 shows an example of grouping of calling numbers (IDs). The call number uses 1 to 60,000 of 2 ¹⁶ = 65,536. Now, 60,000 units are displayed and identified as a combination number of 15 excluding 0000 of the group number (group ID) 2 ⁴ = 16 and 4,000 excluding all 0 of the subscriber ID 2 ¹² = 4096. .

FIG. 1 is a functional block diagram of a multi-channel selective calling device. 1 is a radio unit, 2 is a CPU for controlling the operation of this device, 3 is a signal receiving unit, 4 is a channel number to be used and a calling ID ( ROM that stores group ID and lower ID,
5 is a ring tone reset switch (RS-SW), 6 is a channel switch (CH-SW), 7 is a multi-stage power switch,
8 is a channel number display, 9 is a ringing tone and ringing display, 10 is a frequency synthesizer, 11 is a power supply battery, 21
Is a crystal oscillator for the clock signal of the CPU 2, 31 is a crystal oscillator for the clock signal of the signal receiving unit 3, 32 is a signal decoder unit, 33 is a driver of the LCD 8, and 91 is a call display unit 9 Buzzer, 92 is an LED that flashes when calling
(Red) and 93 are in-range display LEDs (green). In the power switch, is switch OFF, is switch ON-1,
Is the switch ON-2.

Now, ROM4 allocates five channels of channels 1, 4, 7, 10, 13 and the time
Slots 1,13,10,7,4 have their own channel and time
There are devices assigned as slots.

The call ID of this device is any of 0000-3999. As described above, the group ID for 0000 to 3999 is 1 (0001), and the lower number is any one of 0000 to 3999.
One number, for example 2345.

Next, the operation of the above embodiment will be described based on the flow of FIG.

Channel CH from ROM4 in step 1 after starting
The number is read and set in CPU2, and in step 2, the standby reception state is entered. In step 3, it is checked whether the frames are synchronized. When the frames are not synchronized, counting of time is started, and when the time is less than a second, the process returns to step 2 and the standby reception state is continued. When a seconds have passed in step 4, YES is set and the channel CH is advanced by 1 in step 5. In step 6, it is checked whether all the switching channels have been switched. If all the switching channels have not been switched, the process returns to step 2 and the above operation is repeated. All channels (5 for 5CH)
When the (time) is switched, it returns to the first channel. In this case, it is determined that the user is in a blind area and the dead area is left. After waiting for C minutes in step 8, all the time counters and the number of times counter are cleared, and the process returns to step 1 to read the channel number from the ROM 4.

Next, if the frame is synchronized in step 3, the time slot specified in ROM4 is received, and in step 10A, m bits are fetched from the beginning of the call ID, and then step 1
0B Tests whether it matches the group signal of its own.

If it does not match the signal of the own device group in step 10B, it is repeatedly checked for b seconds in step 11, and if it does not match the signal of the own device group, the process returns to step 10A. When b seconds have passed, YES is selected and the channel is advanced by one in step 5. If all channels have not been searched, the standby reception state of step 2 is restored.

Next, if it matches the signal of the own group in step 10B, the time slot is set to the receiving time slot in step 12, and the receiving channel number is displayed on the CH display 8 in step 13. At the same time, all counters are cleared in step 14, and the own ID is set in the standby reception state in step 15. If there is no signal of your machine ID, keep waiting for your machine to call. Own ID in step 15
When there is a call of, the answer is YES, the green LED is lit to display the incoming call of the own machine, and the buzzer sounds. If the reset switch is turned on, the buzzer will stop beeping. Alternatively, when the predetermined time elapses and the time is out in step 17, the operation of step 16 is stopped. When the predetermined time has passed, the call is stopped in step 18,
Returning to step 15, the automatic ID standby is started.

Next, the determination of the group ID of the own device in step 10B is performed by comparing the m bits at the head of 16 bits of the calling ID, in this case, the group is 15, and 15 excluding 0000 of 2 ⁴ = 16 is compared. Become. Call IDs 1 to 3999 are 0001, 4000 to 7999
IDs of 0010 and IDs of 56000 to 59999 are represented by 1111. This is easier than capturing and matching the 12 bits representing 1-3999.

(Effects of the Invention) The present invention has the following effects, as is apparent from the above-described embodiments.

(1) The number structure can be simplified by configuring the calling ID from the upper group ID and the lower 4,000 ID.

(2) Since the call ID is composed of the group ID x 4000, the group can be determined by collating the first m bits of all 16 bits, for example, 4 bits (16), which consumes less battery than before. Can be reduced.

(3) Since multiple radio channel numbers and time slots are assigned to each group, when signals cannot be received on the used channels and time slots, the channels stored in the ROM are sequentially switched. hand,
It is possible to acquire a new channel assigned to itself.

[Brief description of the drawings]

FIG. 1 is a functional block diagram of a multi-channel selective calling device according to the present invention, and FIG. 2 is a radio channel, group and time
FIG. 3 is a diagram showing the relationship of slots, and FIG. 3 is an operation flow diagram of the present invention. 3 ... Signal receiver, 4 ... ROM, 8 ... CH number display, 3
2 …… Data decoder.

Claims (1)

(57) [Claims] 1. A frame that forms one transmission unit is divided into a plurality of groups, the upper bits of which are group IDs different from each other, and the lower bits of which are subscribers.
A multi-channel switching radio receiver that receives a radio signal containing a call ID composed of an ID, a call display circuit that notifies an incoming call, and a call display when the call ID of the own device is detected from the radio signal. In a multi-channel selective calling device having a signal receiving section for operating a circuit, a plurality of receiving channel numbers corresponding to a plurality of frequency bands receivable by the wireless receiver and a time assigned to each receiving channel. A ROM memory that stores the calling ID of the own device, in which the slot number, the upper bits are the group ID, and the lower bits are the subscriber ID of the own device, and the frequency that switches the setting of the reception frequency of this wireless receiver And a synthesizer, and when the signal receiving unit switches the receiving channel to achieve frame synchronization, captures the upper bits of the call ID of the wireless signal. With the group number determination circuit that determines whether it is the group ID number of its own device, and the determination signal that is determined to be the group ID number of the own device, the number corresponding to the receiving channel number for which frame synchronization is obtained A CPU that fetches a time slot from the ROM memory and sets it as a time slot during reception, and a subscriber of the own device from a radio signal from a reception channel in which the frame is synchronized.
A multi-channel selective calling device comprising a call waiting circuit that waits for an ID to be detected.