JPS5827444A - Diversity receiver - Google Patents

Abstract

PURPOSE:To perform the diversity reception with sure operation, by receiving at an auxiliary antenna when the reception level of a main antenna is decreased. CONSTITUTION:When a reception level of a main antenna 1 is higher than that of a reference voltage Es, a drive circuit 16 does not move a changeover switch 3 and keeps the main antenna 1 connected without being subject to an output from an antenna changeover pulse circuit 19 with the output, and a receiver 24 receives only with the main antenna 1. When a reception level of the main antenna 1 is the reference voltage Es or below, a comparator 15 gives information to the drive circuit 16 to control the changeover switch 3 and to changeover the antenna to an auxiliary antenna 2. While the antenna 2 is in operation, an antenna changeover pulse circuit 19, the drive circuit 16, and the changeover switch 3 are interlocked to take the level of the main antenna 1 in time division, and the reception level is stored in a sample hold circuit 14, and when the level is the reference voltage Es or over, the changeover is made to the main antenna 1 immediately.

Description

DETAILED DESCRIPTION OF THE INVENTION In the present invention, in the case of diversity reception, priority is given to the diversity antenna, and reception is normally performed using the main diversity antenna with a high priority. When the reception level of the antenna decreases, the auxiliary diversity antenna with a lower priority receives the signal, and during this time the reception level of the main diversity antenna is monitored in a time-sharing manner, and the reception level of the main diversity antenna is restored. Accordingly, the present invention relates to a diversity receiving device suitable for use in a vehicle so that the main diversity antenna immediately receives the signal.

An embodiment of a diversity receiving apparatus according to the present invention will be described below with reference to one drawing.

In FIG. 1, 1 and 2 are a main antenna and an auxiliary antenna for diversity reception, and 3 is a receiver 24 by switching between the main antenna 1 and the auxiliary antenna 2.
17 is a control terminal for the switching device, 4 is a tuner circuit of the receiver 24, 6 is an intermediate frequency amplification circuit, 6 is an FM detection circuit, and 7 is a control terminal for the switching device. An impulse noise limiting circuit 10 is a speaker for removing noise generated in the ignition system. Reference numeral 11 is a reception level detection terminal for outputting an output according to the reception level of the intermediate frequency amplification circuit 5, and 12 is a terminal connected to the terminal 11 for obtaining a reception level detection output according to the main antenna 1. , the reception level of the main antenna 1 is detected by switching from the auxiliary antenna 2 to the main antenna 1 in a time-sharing manner only when the level of the main antenna 1 decreases, using a clock pulse from the clock generation circuit 18 of the control circuit 22, which will be described later. The final sample switch 14 stores (memorizes) the reception level of the antenna 1 obtained by the sample switch 12.
Reference numeral 13 indicates a reference voltage source that generates a reference voltage Es set to the detection tolerance for pupil noise that appears in the speaker 10 when the reception level of the main antenna 1 decreases; 16 indicates the main antenna 1; A comparison circuit 16 compares the voltage level of the sample-and-hold circuit 14 storing the received level with the reference voltage Es of the reference voltage source 13;
When the reception level of the main antenna 1 is high, the changeover switch unit 3 is connected to the main antenna 1, and only when the reception level of the main antenna 1 is low, the switch is connected to the auxiliary antenna 2 and the main antenna 1 in a time-sharing manner. a drive circuit that applies a control signal to the control terminal 17 of the changeover switch section 3 to switch to the
Reference numeral 22 denotes a control circuit for adjusting the timing in order to operate the circuits of the above-mentioned parts normally. In this control circuit 22, upon receiving a clock pulse from a clock generation circuit 18, an antenna switching pulse circuit 19 applies an antenna switching pulse to a drive circuit 16.

The sample pulse circuit 2o is connected to the antenna switching circuit 19 and sends a signal to the sample switch 12 in order to sample and hold the reception level of the main antenna 1 during the antenna switching period. The sample hold circuit 1 is connected to the sample hold circuit 20 in synchronization with the start of the sample pulse.
4. Give Lise Sotono (Lus).

In steps 12 to 22 above, the controller 2 of the diversity receiving device
3 are made up.

Next, the operation of the diversity receiving apparatus configured as described above will be explained with reference to the signal waveform diagrams of FIGS. 1 and 2. In addition, the signals a-e attached in Fig. 1
corresponds to the waveforms in FIGS. 2(a) to (e). Now, assuming that the changeover switch section 3 is connected to the main antenna 1 and reception is performed by the main antenna 1, the antenna output is transmitted to the FM via the tuner circuit 4 and the intermediate frequency amplification circuit 6.
Detection circuit 6.

Impulse noise limiting circuit 7, stereo demodulation circuit 8.

The signal passes through the power amplifier circuit 9 and is output from the speaker 1o.

On the other hand, a signal a shown in FIG. 2 (,) corresponding to the reception level is output to the terminal 11. In addition, the control circuit 22 generates a clock pulse b as shown in FIG. operate in conjunction. That is, in response to the clock pulse b from the clock generation circuit 18, the antenna switching pulse circuit 19 generates an antenna switching pulse C of about 10 to 30 μSec as shown in FIG. 2(C) in synchronization with the rising edge of the clock pulse b. and gives an antenna switching pulse C to the drive circuit 1e. However, the drive circuit 16
The other input is obtained from the comparator circuit 15, and if the receiver 24 is receiving it from the main antenna 1, the comparator circuit 16 receives the other input.
The drive circuit 16 is prevented from operating based on this information. Therefore, no time-division antenna switching operation is performed.

On the other hand, the sample pulse circuit 20 connected to the antenna switching pulse circuit 19 is switched by the changeover switch section 3, and the tuner circuit 4. A sample pulse d as shown in FIG. 2(d) is generated in accordance with the time (5 to 20 μsec) until the reception level appears at the intermediate frequency amplification circuit 6 and the terminal 11.
is applied to the sample switch 12. At the same time, a reset pulse circuit 21 connected to the sample pulse circuit 20
Then, a reset pulse e as shown in FIG. 2(e) is given to the sample and hold circuit 14 to reset it in advance. By doing so, the reception level of the main antenna 1 is stored in the sample hold circuit 14 from the terminal 11 via the sample switch 12.

However, in this case, the changeover switch section 3 is connected to the main antenna 1 and the drive circuit 16 is not operating, so the changeover switch section 3 remains at the antenna 1 and the reception level of the main antenna 1 is set to the terminal 11. The signal is stored in the sample hold circuit 14 via the sample switch 12. Then, the output of the sample and hold circuit 14 is applied to one input of the comparator 15, and the reference voltage Es set to the audible noise detection tolerance level of the receiver 24 is added to the other input for comparison. When the level is high, the information is given to the drive circuit 16, and the main antenna 1 is turned off without moving the changeover switch section 3.
Receive at. The reception level of main antenna 1 is the reference voltage, [E
When the temperature is higher than s, this operation is repeated as it is, and the receiver 24 receives signals only with the main antenna 1 [see operation I in Figure 2]
. Therefore, time division of antenna switching is not performed.

However, if the reception level of the main antenna 1 has decreased compared to the reference voltage Es [the second operation old, that is, the terminal 1
1. The reception level of the main antenna 1 stored in the sample hold circuit 14 via the sample switch 12 is the reference voltage E.
When the value becomes lower than s, the comparator 16 gives information to the drive circuit 16, and the drive circuit 16 sends a signal to the control terminal 1 of the switch section 3 to switch the antenna from the main antenna 1 to the auxiliary antenna 2. send. Therefore, the receiver 24 starts receiving with the auxiliary antenna 2.

At this time, the present invention takes into account that when the reception level of the main antenna 1 is recovered, the main antenna is immediately returned to the antenna 1. That is, in reception by the auxiliary antenna 2, antenna switching) (antenna switching switch section 3 from the loop circuit 19)
is applied to the control terminal 17 of
It is switched to the main antenna 1 for 30 μsec. As a result, the control circuit 23 operates at the timing mentioned above and changes the reception level of the main antenna 1 to the terminal 11 only when switching to the main antenna 1. It is stored in the sample hold circuit 14 via the sample switch 12. Here, as in the previous statement, the comparison circuit 16 compares the reference voltage Es and the level corresponding to the reception level of the main antenna of the sample and hold circuit 14, and if the reception level of the main antenna 1 is not low, the auxiliary antenna 2 is used as is. When the receiver 24 receives the signal and the reception level of the main antenna 1 recovers, the main antenna 1 receives the signal from the receiver 24.
works to receive. That is, the reception level of the main antenna 1 is always stored in the sample and hold circuit 14, and only when the auxiliary antenna 2 is operating, the antenna switching pulse circuit 19, drive circuits 16, 0, and changeover switch section 3 are operated in conjunction with each other. The level of the main antenna 1 is taken in a time-sharing manner.

That is, the present invention normally receives signals using the main antenna, receives signals using the auxiliary antenna only when the receiving level of the main antenna decreases, and immediately receives signals using the main antenna when the receiving level of the main antenna recovers. It works most effectively when the main antenna is a monopole antenna installed outside the vehicle body, and the auxiliary antenna is a windshield antenna attached to the windshield or glass of the vehicle.

FIG. 3 shows a specific example of the configuration of the main parts of the present invention.

This is a part of the control section 23 shown in a dotted frame in FIG. 1. Reference numeral 25 in FIG. 1 is an input amplifier for receiving a signal from the terminal 11 in FIG. Analog switch 26 corresponds to sample switch 12 in FIG. Operational amplifiers 27 and 29. The diode 28, the transistor 30, and the capacitor C correspond to the sample and hold circuit 14 in FIG. The operational amplifier 31, diode 32, and inverter 33 correspond to the comparator circuit 16 in FIG. In the figure, Es corresponds to the reference voltage Es in FIG. NAND gate circuit 34,
Inverters 35, 36 and 37 are drive circuit 1 of FIG.
Corresponds to 6. Inverters 38 and 39 correspond to clock generation circuit 18 in FIG. Inverter 40. NA
ND gate circuit 41 corresponds to antenna switching pulse circuit 19 in FIG. Inverters 42 and 44. NAND
Gate circuit 43 corresponds to sample pulse circuit 20 in FIG. NAND gate circuit 46. Inverter 46 corresponds to reset pulse circuit 21 in FIG.

In this case, since the potential relationship between the receiving level of the receiver and the terminal 11 for detecting the receiving level is of opposite polarity, that is, the voltage at the terminal 11 decreases as the receiving level increases. Even the sample hold circuit and comparison circuit operate with reverse polarity. Furthermore, this circuit has a sample and hold circuit that performs peak hold, and operates in exactly the same way as the basic block diagram of FIG. Furthermore, it goes without saying that the portion corresponding to the control circuit 22 in FIG. 1 may be changed to J as long as the timing relationship in FIG. 2 is maintained. Also,
Reference voltage E8 is semi-fixed.

Further, in order to increase the stability against electric field fluctuations, it is also possible to apply it from the terminal 11 via an integrating circuit.

Another configuration example is shown in FIG. To explain this,
Operational amplifier 47 is an input amplifier similar to 25 in FIG. The analog switch 48 corresponds to the sample switch 12 in FIG. Operational amplifier 49 and capacitor C
corresponds to the sample and hold circuit in FIG. Operational amplifier 5o and diode 51 correspond to comparator circuit 16 in FIG. In the figure, Es corresponds to the reference voltage Es in FIG. NAND gate circuit 52. Inverters 63, 54 and 66 correspond to drive circuit 16 in FIG. Inverters 56 and 67 correspond to clock generation circuit 18 in FIG. The inverter 58° NAND gate circuit 59 corresponds to the antenna switching pulse circuit 19 in FIG. Inverters 6o and 62. NAND gate circuit 61 corresponds to sample pulse circuit 20 in FIG. In this case, input 3 is of opposite polarity as in FIG. Furthermore, by removing the peak hold shown in FIG. 3 and performing ordinary sample hold, the reset pulse circuit 21 shown in FIG. 1 can be eliminated, and a simpler diversity receiving apparatus can be realized. This is also operationally exactly the same as the case shown in Figure 1. Especially in the case of diversity reception for car-mounted FM radio, the main antenna is a monopole antenna attached to the outside of the car body, which has good sensitivity, and is attached to the glass. If the wind seal antenna is used as an auxiliary antenna, diversity reception can be performed with a simple configuration and reliable operation, and is effective for skip noise, picket fencing, and multipath.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of main parts of an embodiment of the present invention. Figure 2 (a), (b), (C), (d)
, (e) is a signal waveform diagram of each part in FIG. 1, and FIGS. 3 and 4 are specific circuit configuration diagrams of main parts that can be used in the present invention. 1...Main antenna, 2...Auxiliary antenna. 3... Changeover switch section, 11... Terminal for reception level 4 detection, 12... Sample switch. 13... Reference voltage source, 14... Sample hold circuit, 15... Comparison circuit, 16...
... Drive circuit, 18 ... Clock generation circuit, 19 ... Antenna switching pulse circuit, 20 ...
... Sample pulse circuit, 21 ... Reset pulse circuit, 22 ... Control circuit, 23 ...
...Control unit, 24...Receiver.

Claims (1)

[Claims] A main antenna and an auxiliary antenna for diversity reception, a changeover switch unit that selectively switches between the main antenna and the auxiliary antenna, a receiver to which an antenna output from the changeover switch is given, and the receiver. A drive circuit that sub-drives the changeover switch section in response to an output from a reception level detection terminal provided in the receiver, and a sample and hold circuit. a sample switch that inputs the output of the reception level detection terminal to the sample and hold circuit; a comparison circuit that compares the output level of the sample and hold circuit with a reference voltage; and a comparison circuit that provides the output to the drive circuit; It includes a control circuit that generates a sample pulse, a reset pulse, and an antenna switching pulse for operating the sample and hold circuit and the drive circuit,
When the reception level of the main antenna is high, the main antenna receives the signal preferentially, and when the reception level of the main antenna is low, the auxiliary antenna receives the signal, and when the control circuit recovers the reception level of the main antenna, the main antenna receives the signal. A diversity receiving device characterized in that it is configured to automatically switch to receive data using an antenna.