JPH02290336A - Am tuner - Google Patents

Abstract

PURPOSE:To prevent any channel base from generating beat by applying 1/10 frequency division to a 1st local oscillator output with a prescribed frequency and forming an intermediate frequency signal with a specific frequency. CONSTITUTION:The oscillation output of a 1st local oscillation circuit 5 with a prescribed frequency having a PLL is subjected to the frequency division ratio of 1/10 at a frequency divider circuit 4, mixed with a reception output via an RF amplifier circuit 2 at a 1st frequency mixer circuit 3, from which an intermediate frequency signal whose frequency is near 10.7kHz and not coincident with the multiple of 9kHz and 10kHz. On the other hand, the frequency of the oscillating output of the circuit 5 is set to 10 times as much as the sum of the 1st intermediate frequency and the reception frequency. Based on the frequency setting value, in all the frequency bands of the AM broadcasting waves, the generation of beat with channel base frequencies 9kHz, 10kHz in Japan, Europe and USA is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an AM tuner, and more particularly to a double conversion type AM tuner using a PLL frequency synthesizer, which is used for receiving AM broadcasting and the like.

[Conventional technology]

Conventionally, in this kind of double-conversion type AM tuner, as an example of the block diagram is shown in FIG. is input to the first intermediate frequency amplifier circuit 6, mixed with the oscillation output signal of the first local oscillator (B) 11 formed by the voltage controlled oscillator, converted to the first intermediate frequency (f+pt), and sent to the first intermediate frequency amplifier circuit 6. The received signal amplified in the first intermediate frequency amplification circuit 6 is mixed with the oscillation output signal of the second local oscillation circuit 8 in the second frequency mixer 7, converted to the second intermediate frequency (f+pz), and then converted to the second intermediate frequency (f+pz). It is sent to the frequency amplification circuit 9. The received signal amplified in the second intermediate frequency amplification circuit 9 is transmitted to a demodulation circuit 10.
It is demodulated at and output as a predetermined audio signal. In this conventional example, the first local oscillator circuit (Ball is P
It is composed of a LL frequency synthesizer, and the first
The frequency of the signal obtained by dividing the oscillation output signal of the local oscillator circuit (B) 11 by a predetermined division number determined by the reception frequency using a programmable divider is compared with the frequency of a predetermined reference signal, and the frequency of the two is compared. The oscillation frequency of the voltage controlled oscillator forming the first local oscillator circuit (B) 11 is controlled so that the signal frequencies match. The channel space for AM broadcasting is 10KHz in the US.
, 9 KHz in Europe and Japan, so PLL synthesizers generally use 9 KH.
Two reference frequencies are provided: z and lQKHz.

When setting the reception frequency, by changing the frequency division number by the programmable divider one by one, the oscillation frequency of the first local oscillation circuit (B) 11 formed by the voltage controlled oscillator is changed for each frequency of the channel space. and set the receiving frequency.

As the first intermediate frequency (foFt), since there are 9κHz and 1OKHz in the channel space of AM broadcasting, the first intermediate frequency (foFt) is 1O. 71
MHz is set as the first intermediate frequency (f+pt). In addition, from the viewpoint of selectivity, the second intermediate frequency (flF2) is 450K, which is commonly used in the past.
Hz. Therefore, the oscillation frequency ('CSC2) of the second local oscillator circuit 8 is set to 10.26 KHz. Note that the second local oscillation circuit 8 is a fixed frequency oscillation circuit.

[Problem to be solved by the invention]

In the conventional AM tuner described above, the oscillation signals from the first and second local oscillator circuits are routed to the frequency mixing circuit via the power supply and ground wiring, and the frequency mixing circuit receives signals of various frequencies. Combined and output. The harmonic components of the sum signal or difference signal of the oscillation signals of the two local oscillator circuits are determined by the reception frequency (f's) as the first intermediate frequency (f+pt), the first local oscillation frequency (fosct), or the second image. Frequency (f+px
2ftp2), a beat frequency component is generated. That is, specifically, fosc1=f'N+
From the relational expression f+pt, a beat occurs in the following cases.

If the channel space is 9 KHI, fIm
=1512KHz - (fosct foscz)・
5=f+px 2f+pz f+w = 1602KHz − (fosct f
oscz) ・6=fOsc1 f+* = 1260KHz =- (fosct
foscz) ・7=fOSCl fiN=1080KHz −(fosct fosc
2)・7”flF1 f+* =621K}lz・・−(fosci f
oscz)・to”flPl f+* =531KHz-(foscl fosc2
)・10=l,pl 2Lpz If the channel space is 10KHz, f+s
= 1080KHz − (fosct
foscz) ・72flF1? 1s = 1260KHz - (fosc■
fosc2>・7=``. mcl fIN =640KHz-- (fosct f
oscz) ・9” f Ipt 2flp2 fH =740KI4z---(fosc1
fosczL 9”flPl f I N = 690κHz--(fosct
fosc2)10==l'Ipt 2f+pz In order to avoid disturbances caused by such beats, in conventional double-conversion type AM tuners, the first intermediate frequency (flFJ) and the second local oscillation frequency (f.
．． In some cases, c2) is set to a frequency different from the above-mentioned frequency. That is, the channel space is 9κ
For Hz, f+pt=lO. 70114Hz and fosc2 = lO. 25114t{z and the channel space is lOKHz, f I P
I = 10.690MHz and fomc2 = IO.
It is set to 240MHz.

By setting the first intermediate frequency (t+px) and second local oscillation frequency (fo-cz) in this way, the reception frequency band where beats occur is reduced, but beat interference still occurs at the following frequencies. , this cannot be removed.

f IN = 639KHz・=・= (fosct
foscz) ・9f+pt 2f+pz f +pi -830KHz- - (foscx
foscz) 9foscl Therefore, the conventional double-conversion type AM tuner has the disadvantage that beats cannot be completely removed.

[Means to solve the problem]

The AM tuner of the present invention uses a PLL synthesizer to divide the frequency of the oscillation output signal of the first local oscillation circuit formed by a predetermined voltage controlled oscillator into one-tenth. a first frequency mixing circuit that mixes an output signal of the frequency dividing circuit and a received signal from a predetermined antenna; a first intermediate frequency signal output from the first frequency mixing circuit; The frequency of 10.
7M}! The frequency of the oscillation output signal of the first local oscillator circuit is set to a frequency that is near z and does not match a multiple of either 9 KHz or 10 KHz, and the frequency of the oscillation output signal of the first local oscillator circuit is set to 10 times the sum of the first intermediate frequency and the reception frequency. The frequency is set and configured.

〔Example〕

Next, the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of an embodiment of the present invention. As shown in FIG. 1, this embodiment includes an antenna 1, an RF amplifier circuit 2, a first frequency mixing circuit 3, a first frequency dividing circuit
a local oscillator circuit (A) 5, a first intermediate frequency amplification circuit 6,
9 constituted by a second frequency mixing circuit 7, a second local oscillation circuit 8, a second intermediate frequency amplification circuit 9, and a demodulation circuit 10. In FIG. The difference is that
The part exhibiting the first local oscillation effect is the first local oscillation circuit (
A) 5 and a frequency dividing circuit 4. The functions and effects other than the part exhibiting the first local oscillation function are the same as in the conventional example shown in FIG.
Detailed explanation will be omitted. In this embodiment, the frequency of the first intermediate frequency signal is lO. In the vicinity of 7MHz, and
The frequency is set to a frequency that is not a multiple of either 9K}Iz or 10 KHz, and this is the first feature of the present invention. Now, according to the above conditions, suppose the first local oscillation frequency is r I F+-10.695MH
If set to z, the second local oscillation frequency (foscz) will correspondingly be set to .z. It becomes 10.245hlHz.

Further, a frequency dividing circuit 4 with a frequency division ratio of 1/10 is provided between the first local oscillator circuit (A) 5 and the first frequency mixing circuit 3 of the present invention, and the first local oscillator circuit (A) A) The frequency of the output signal of 5 is set to a frequency that is a fraction of the phase of the first, intermediate frequency, and reception frequency, that is, 10 times. This is the second feature of the present invention.

In conventional AM tuners, the first intermediate frequency must be set to a multiple of 10 KHz when the channel space is 10 KHz, and must be set to a multiple of 9 IKz when the channel space is 9 KHz. I had to. Therefore, in order to avoid beats, the first. Are you trying to change the intermediate frequency? However, there were limits and it was impossible to respond adequately. However, in the present invention, the oscillation frequency of the voltage controlled oscillator forming the first local oscillator circuit (A) 5 is set to 10 times the local oscillator fg frequency (FOSC+) input to the first frequency mixing circuit 3. By setting this frequency to 1/1o by the frequency dividing circuit 4, the local oscillation frequency (
fosc■) is supplied to the first frequency mixing circuit 3.

By using such a circuit configuration, the oscillation frequency of the voltage controlled oscillator only needs to be changed by 10 times the channel space in response to the reception frequency of the AM tuner, and therefore the frequency given to the programmable divider described above can be changed by 10 times the channel space. The number of cycles can be varied by 10 times. This can be easily accomplished by changing the sip of the PLL synthesizer.

Note that the first intermediate frequency f+p+ set as described above
=IO. 695MHz, second local oscillation frequency rosc
In the case of 210.24514 Hz, unlike a conventional AM tuner, there is no station that corresponds to the receiving frequency where the beat occurs.

In addition, when an AM/FM two-band tuner is configured using the AM tuner and FM tuner of the present invention, an advantage is obtained that the first local oscillation circuit can also be used as the local oscillation circuit of the FM tuner. be. In this case, when the FM tuner is used for the Japanese band, it is preferable to set the frequency dividing ratio of the frequency dividing circuit to 1/6 from the broadcast frequency band.

〔Effect of the invention〕

As described above in detail, the present invention has a channel space of 9 KH in all frequency bands of AM broadcast waves.
z and 10 KHz, there is an effect that no beat occurs.

Circuit, 3...First frequency mixing circuit 3, 4...
... Frequency dividing circuit, 5... First local oscillator circuit (A
), 6...1 first intermediate frequency amplification circuit, 7...
. . . second frequency mixing circuit, 8 . . . second local oscillation circuit, 9 . . . second intermediate frequency amplification circuit, 10.
... Demodulation circuit, 11 ... First local oscillation circuit (B) Agent Patent attorney Original sound

[Brief explanation of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention, and FIG. 2 is a block diagram of an embodiment of the present invention.
FIG. 1 is a block diagram of an example of a conventional AM tuner.

Claims (1)

[Claims] a first local oscillation circuit formed by a predetermined voltage controlled oscillator using a PLL synthesizer; a frequency dividing circuit that divides the frequency of the oscillation output signal of the first local oscillation circuit to one-tenth; a first frequency mixing circuit that mixes the output signal of the circuit and the received signal from a predetermined antenna; And 9KHz
and 10 KHz, and setting the frequency of the oscillation output signal of the first local oscillator circuit to a frequency that is 10 times the sum of the first intermediate frequency and the receiving frequency. Featured AM
tuner.