JPH0389720A - Radio receiver - Google Patents

Abstract

PURPOSE:To reduce the cost and to prevent beat noises by sharing the most part of local oscillators consisting of phase locked loops(PLL). CONSTITUTION:A switching control signal is applied on changeover switches S1-S3 from a control circuit 18, and the change over switches S1-S3 are interactively and alternately changed over. Consequently, a programmable frequency divider 14, a phase difference detector 15 and a low pass filter 17 are set in common, and PLL of two systems including a first local oscillator 4 or a second local oscillator 11 are alternately formed. On the other hand, frequency division rate data N which are synchronized with the switching control signals outputted from the control circuit 18 to the switches S1-S3 and are outputted from the control circuit 18 to the programmable frequency divider 14 are alternately switched. Tuning is executed by local oscillation outputs based on frequency division rate data N1 and N2 in first and second tuners. Thus, the cost is reduced and the beat noise is prevented.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention has two front end systems and phase-locks the local signals at the front end.
The present invention relates to a radio receiver having a so-called double tuner configuration, which is provided by a loop (PLL).

[Conventional technology and its problems]

RDS (Radio Da
taSystem) broadcasting system is beginning to be fully equipped,
One service of this RDS broadcasting is a function called a same program following function (Network Follow).

This is because the RDS data includes frequency data (AF) of broadcasting stations that broadcast the same program, and while reading this AF data, the necessary AF list data is written to the memory installed in the receiver. . Using this data,
When the current receiving level is below the set level, AF
It checks the reception level of the frequency and switches to a broadcast frequency with better reception conditions.

Therefore, the channel selection operation that frequently occurs during mobile reception can be automatically performed, and the same program can be continuously received in good condition.

When trying to receive such a service, if there is only one FM receiving circuit, muting the station being monitored for a short time, searching for a station on the same network during that time,
If the reception condition of that station is good, the system switches to that station.

Also, it takes some time to determine whether the station is on the same network, so if the electric field level is stronger than the original receiving station at the same frequency, switch to that station and then check whether the station is on the same network. I'm checking. Therefore, in rare cases, a situation may occur in which the voice of a station on another network can be heard for a while, causing inconvenience such as confusion to the user.

In order to solve these problems, we changed the front end to 2.
A radio receiver equipped with a system has been proposed.

According to this, the first tuner can perform audio monitoring, and the second tuner can search for an optimal station. In other words, when the reception quality at the second tuner becomes higher than the reception quality at the first tuner, by instantaneously switching to a higher quality station,
It is possible to receive services from the same network without making the listener feel uncomfortable.

On the other hand, in Japan, roadside broadcasting is implemented on some motorways.

This mainly broadcasts traffic information using the AM frequency of 1620KHz or 1629KHz.

Even when receiving such roadside broadcasts, for example, if an FM broadcast is being received, it is necessary to switch the band to AM and then tune to the above-mentioned specific frequency.

Even when attempting to automatically receive such roadside broadcasting services, it is convenient to use a radio receiver equipped with two front ends.

In other words, if the first tuner is monitoring, for example, FM broadcasting, and the second tuner is enabled to receive the above-mentioned specific AM frequency, when the second tuner becomes ready to receive it, the second tuner will instantly receive the FM broadcast. By switching to the 2-channel reception frequency, you can automatically receive roadside broadcasting services.

The local signal oscillator in the front end uses a PLL whose oscillation frequency can be electronically controlled and has good frequency stability. Therefore, in a radio receiver equipped with two front ends, a PLL is used for each local signal oscillator.

As is well known, PLL basically consists of a reference signal oscillator using a crystal or the like, a phase difference detector to which the output of this reference oscillator is applied to one input terminal, and a DC component from the output of this detector. It consists of a bass filter that extracts is fed back to the end to form a phase-locked loop.

Therefore, when at least two such PLL circuits are provided as front-end local signal oscillators,
It is necessary to provide two of each of the reference signal oscillators, phase difference detectors, low-pass filters, voltage-controlled oscillators, etc. as described above, and a corresponding increase in cost is unavoidable.

Furthermore, there are problems in that beat noise occurs between each PLL, and this affects the demodulated audio signal as an interference signal.

[Purpose of the invention]

Therefore, an object of the present invention is to reduce costs by sharing most of the local signal oscillator made up of PLLs, and also to eliminate the occurrence of beat noise between PLLs as in the past. The aim is to provide a radio receiver.

[Summary of the invention]

In order to achieve the above object, the radio receiver according to the present invention includes a first local signal oscillator for applying a first local signal to the input RF (i), and a first local signal oscillator for applying a first local signal to the input RF signal (i); A second local signal oscillator for applying a second local signal to the target, and a programmable device that selectively switches the oscillation output from the first or second local signal oscillator and inputs either of the oscillation outputs. A frequency divider, a phase difference detector which takes the output from this programmable frequency divider as one input and a reference signal as the other input and generates a DC output based on the phase difference between the two; Extract the low frequency component of the output, and
The second local signal oscillator is characterized in that it includes a low-pass filter that selectively supplies a DC component to the local signal oscillator or the second local signal oscillator.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a first embodiment of the invention.

That is, in the figure, 1 indicates an antenna, and after the RF multiplied signal from this antenna 1 is amplified by an RF amplifier 2 constituting a first tuner, it is applied to a mixer 3, where it is applied to a first local signal formed by a PLL. It is mixed with the local signal from the oscillator 4 to generate an intermediate frequency signal. This intermediate frequency signal is amplified by an intermediate frequency amplifier 5, demodulated by a detection circuit 6, and applied to a switching circuit 7.

On the other hand, the RF multiplied signal obtained from the receiving antenna 1 is applied to the RF amplifier 9 constituting the second tuner via the splitter 8, and is amplified by the RF amplifier 9 and applied to the RF multiplied signal mixer 10. .

Here, it is mixed with a local signal from the second local signal oscillator 11 consisting of the RF multiplied signal PLL, and an intermediate frequency signal is generated. This intermediate frequency signal is sent to an intermediate frequency amplifier 12.
After being amplified by, the signal is demodulated by the detection circuit 13 and applied to the switching circuit 7.

The oscillation output of the first local signal oscillator 4 and the oscillation output of the second local signal oscillator 11 are respectively connected to selected terminals of a selector switch S1, and the selected output is a predetermined one. It is applied to a programmable frequency divider 14 whose frequency is divided by a frequency division ratio N.

The output frequency-divided by the programmable frequency divider 14 is applied to one input terminal of the phase difference detector 15, and the output from the reference signal oscillator 16 using a crystal or the like is applied to the other input terminal. be compared.

The phase difference detector 15 generates a DC output based on the above-described phase difference between the two, and the output is applied to a low-pass filter 17 that extracts low-frequency components.

The output of this low-pass filter 17 is connected to the respective selected terminals of switches S2 and S3 that are linked to the changeover switch 31, and the selection terminal of switch S2 is connected to the first local signal oscillator 4, and the selection terminal of switch S
The three selection terminals are respectively connected to the second local signal oscillator 11 and selectively supply the tuning voltage.

The programmable frequency divider 14 is given frequency division ratio data N from a control circuit 18 consisting of a microprocessor. According to this frequency division ratio data N, the frequency division ratio of the PLL including the phase difference detector 15, the low-pass filter 17, and the first and second local signal oscillators 4 and 11 changes. As a result, the DC level applied to the first and second local signal oscillators 4 and 11 is varied, and the tuning frequencies at the front ends of the first and second tuners are determined.

An operation board 19 is connected to the control circuit 18, and frequency division ratio data N is determined based on channel selection data input from the operation board 19.

The control circuit 18 is further applied with station detection signals from the intermediate frequency amplifiers 5 and 12, and receives, for example, RDS data from the detectors 6 and 13.

From the control circuit 18, a selector switch 5l-5
A switching control signal is applied to the switch 3, and therefore the changeover switches 81 to S3 are alternately switched in conjunction with each other. As a result, the programmable frequency divider 14, phase difference detector 15, and low-pass filter 17 are common, and the first local signal oscillator 4 or the second local signal oscillator 1
Two systems of PLLs, including one PLL, are formed alternately.

On the other hand, frequency division ratio data N output from the control circuit 18 to the programmable frequency divider 14 is also alternately switched in synchronization with the switching control signals output from the control circuit 18 to the switches 81 to S3. The first tuner performs tuning using local signal oscillation output based on frequency division ratio data N1, and the second tuner performs tuning using local signal oscillation output based on frequency division ratio data N2. Become.

Therefore, for example, by monitoring the audio with the first tuner and selecting the optimal station with the second tuner, it is possible to activate the same program tracking function, which is one of the services of RDS broadcasting.

FIG. 2 shows a part of a second embodiment of the invention.

In FIG. 2, parts designated by the same reference numerals as those in FIG. 1 indicate the same circuits, and therefore their explanations will be omitted.

In the example shown in FIG. 2, a signal from this low-pass filter is supplied to the output end of a low-pass filter 17 that selectively supplies a DC component to the first local signal oscillator 4 or the second local signal oscillator 11. An analog/digital converter 20 for digitally converting the DC output is connected.

The digital data from the analog-to-digital converter 20 is then temporarily written into storage means (not shown) provided within the control circuit 18.

The digital data from this storage means is converted into analog by a digital-to-analog converter 21, and the analog value is supplied alternatively to the first local signal oscillator 4 or the second local signal oscillator 11.

That is, the state in which the first local signal oscillator 4 is forced to be included in the PLL loop (changeover switches 81 to
While S3 is in the illustrated state B), the low-pass filter 17
The DC value from is digitally converted by the analog-to-digital converter 20 and temporarily written into the storage means. Next, a state in which the second local signal oscillator 11 is included in the PLL loop (changeover switch St
~S3 is in a state in the opposite direction to that shown in the figure), the stored data is converted to the original analog value by the digital-to-analog converter 21, and is supplied to the first local signal oscillator 4. The local signal oscillator 4 can continue to stably oscillate local signals.

Note that the second local signal oscillator 11 can continue to stably oscillate the local signal by the same effect as described above.

〔effect〕

As is clear from the above explanation, according to the present invention, despite having two front ends, the PLL
Since most of the local signal oscillators can be shared, it is possible to reduce costs, and at the same time, it is possible to eliminate the conventional problem of beat noise occurring between PLLs. .

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the second embodiment of the invention, and FIG. 2 is a block diagram showing the second embodiment of the invention. 1... Antenna, 2, 9... RF amplifier, 3, 10
... Mixer, 4, 11 ... Local signal oscillator, 5
゜12... Intermediate frequency amplifier, 6, 13... Detection circuit, 7... Switching circuit, 8... Brancher, 14...
Programmable frequency divider, 15... Phase difference detector, 16
...Reference signal oscillator, 17...Low pass filter,
18... Control circuit, 19... Operation board, 20...
・Analog-digital converter, 1... Digital-analog converter, 1-33... Selector switch.

Claims (2)

[Claims] (1) A first local signal oscillator for applying a first local signal to the input RF signal, a second local signal oscillator for applying the second local signal to the input RF signal, and A programmable frequency divider that selectively switches the oscillation output from the first or second local signal oscillator and receives either of the oscillation outputs as an input; a phase difference detector that receives a signal as the other input and generates a DC output based on the phase difference between the two, and extracts a low frequency component of the output from this phase difference detector, and A radio receiver comprising: a low-pass filter that selectively supplies a DC component to a local signal oscillator. (2) a first local signal oscillator for applying a first local signal to the input RF signal; a second local signal oscillator for applying the second local signal to the input RF signal; A programmable frequency divider that selectively switches the oscillation output from the first or second local signal oscillator and receives either of the oscillation outputs as an input; a phase difference detector that receives a signal as the other input and generates a DC output based on the phase difference between the two, and extracts a low frequency component of the output from this phase difference detector, and A low-pass filter that selectively supplies a DC component to a local signal oscillator, an analog-to-digital converter that digitally converts the DC output provided by this low-pass filter, and a digital data from this analog-to-digital converter is written. a digital-to-analog converter that converts the digital data from the storage means into analog and supplies the analog value to the first local signal oscillator or the second local signal oscillator; A radio receiver characterized by comprising: