NL8802504A - Radio receiver with locked loop for automatic frequency control - has muting circuit blocking unwanted audio signals outside tuned region - Google Patents

Abstract

The receiver has a frequency locked loop including a VCO with a tuning input, a mixer with an antenna input, a filter, a frequency-to-voltage converter connected to the VCO, and a blocking circuit. The F/V converter is coupled to the VCO via a first amplifier/limiter. The F/V converter is connected to the first amplifier/limiter via alow-pass filter which has a bandwidth greater than the audible frequency range. The F/V converter contains a multiplier one output of which is connected via filter to a second amplifier/limiter. The multiplier is fed by the output of the first amplifier/limiter and a phase-shifted output from the control circuit. The blocking circuit is controlled by a control loop.

Description

4

W.

PHN 9558A 1 N.V. Philips' Incandescent light factories in Eindhoven.

Radio receiver.

The invention relates to a radio receiver provided with a frequency-keyed loop, successively comprising a voltage-controlled oscillator with an input for the tuning voltage, a mixing stage connected to an antenna input, a filter member, a frequency-voltage converter connected to the voltage-controlled oscillator and a punching circuit for blocking an audio signal outside of rejection.

Such a radio receiver is known from the article "IM IP Strip Using the CA 3189E" published in "Elektor", Vol. 5, 10 No. 6, p. 2-26, Canterbury (GB).

The frequency-voltage converter in the frequency-keyed loop of the known radio receiver supplies a frequency control signal to the voltage-controlled oscillator for the purpose of an automatic frequency control (APC). The frequency control signal is a measure of the frequency deviation between the current and the correct tuning frequency and is used in the known radio receiver together with the audio signal level to indicate the area of correct tuning, in which the blanking circuit must be switched off. to be.

However, the loop gain in the frequency-keyed loop affects said frequency control signal and thereby the effective operating range of the automatic frequency control and the latter sound of correct tuning, within which the blanking circuit must be turned off.

The object of the invention is to make the size of these areas independent of the size of the loop gain.

To this end, a radio receiver of the type mentioned in the preamble according to the invention is characterized in that the frequency-voltage converter is coupled to the voltage-controlled oscillator via a first amplifier limiter.

When the measure according to the invention is applied, the first amplifier limiter is limited by a certain amplitude of the output signal of the frequency-voltage converter, or at least the amplification decreases with a further increase in this output signal.

.8802504 4 m PHN 9558A 2

Although the gain of the first amplifier limiter and thus also the loop gain up to this amplitude can be very large, the influence thereof on the effective operating range of the automatic frequency control and the said frequency range of correct tuning is limited to the range in which the first amplifier limiter is out of limit, so that tuning and reproduction of weaker, frequency-adjacent transmission signals is possible.

A preferred embodiment of a receiver according to the invention is characterized in that the frequency-voltage converter is connected to the first amplifier limiter via a low-pass filter with a bandwidth of the size of at least the audible audio frequency range.

When this measure is applied, the frequency-voltage converter not only functions as a control voltage generating circuit for the automatic frequency control, but also as a frequency demodulator and a compression of the frequency sweep of the received signal takes place. The magnitude of this sweep compression is independent of the magnitude of the effective frequency range of the automatic frequency control and the magnitude of the frequency range of correct tuning within which the voltage circuit is turned off.

Moreover, by suitable selection of the effective operating range of the automatic frequency control relative to the correct tuning range, it is achieved that when at least on the edge of this correct tuning range the at least partly limiting effect of the first amplifier limiter is audible in a distortion of the reproduced sound signal, giving the user an indication that more optimal tuning is possible.

A further preferred embodiment of such a receiver is characterized in that the frequency-voltage converter comprises a multiplication disc trajectory, one of which has an output with the said low-pass fliter and also a second amplifier limiter via which the filter element is coupled to a first input. of the multiplier stage and on the other hand to a limiter, which is coupled via a frequency-dependent 90-phase shifter to a second input of the multiplier stage.

When this measure is applied, on the one hand, a quadratic amplification of AM noise from FM signals, such as occurs for instance with conventional EM quadrature demodulators, is avoided. Because the '8802504 * »4 PHN 9558A 3 average noise level outside of this receiver's equalization is equal to the average signal level with correct tuning, on the other hand noise peaks occur, which occur in the preamble of the known receiver at fluctuations of the noise level around the signal level. / avoided.

In addition, by properly selecting the limiting amplitude of this second amplifier limiter, small signals are linearly amplified, making the bandwidth of the loop for small noise signals smaller than for the larger, desired signals at which limitation occurs, so that high frequency noise disturbances are less audible.

The invention will be explained in more detail with reference to the figures shown in the drawing by way of example.

The invention will be explained in more detail with reference to the figures shown in the drawing by way of example.

15 Herein shows:

Figure 1 shows an FM receiver according to the invention;

Figure 1a shows an AM receiver according to the invention; Figures 2 to 5 show the idealized variation of the output voltage of the frequency-voltage converter, the first amplifier limiter, the first phase detector and the first limiter of the receiver coupled to the first phase detector according to the invention, respectively. of a normalized unmodulated tuning frequency at one particular level of the antenna signal.

Figure 6 shows the tuning behavior of the receiver according to the invention.

Figure 1 shows an FM receiver 1 according to the invention, which is connected on the one hand to an antenna device 100 and on the other hand to a loudspeaker 32 · The FM receiver 1 is provided with a frequency key loop 6 to 18 with a signal input 3j, which is coupled via an input amplifier 2 to the antenna device 35 100, and to a control circuit 19 to 27, which is coupled to the frequency-keyed loop 6 to 18 in the manner described below. and, on the other hand, to a control input 28 of a switch circuit 29.

.8802504 t 4 PHN 9558A 4

The mute circuit 29 includes first and second inputs 33 and 34, which first input 33 is coupled to a signal output 5 of the frequency-keyed loop 6 through 18 and which second input 34 is coupled to a noise source 30. The output of the Mute circuit 29 is coupled to the loudspeaker 32 via an audio signal processing part 31. In the idle state, the first input 33 is connected to the output of the mute circuit 29, when activated, the second input 3h is connected to the last mentioned output.

The frequency-keyed loops 6 to 18 successively comprise a mixer 6 connected to the signal input 3, a low-pass filter 7j, a frequency voltage converter 18, a so-called first amplifier limiter 15, an adder circuit 16 and a mixer connected to the mixer 6. 15 voltage-controlled oscillator 17 · The connection between the first amplifier limiter 15 and the adder circuit 16 is connected to the signal output 5 of the frequency-keyed loop 6 to 18. The adder circuit 16 also has a tuning voltage input 4 and counts the 20 supplied thereto tuning voltage at the output voltage of the first amplifier limiter 15. The frequency-voltage converter 18 comprises a second amplifier limiter 8 coupled to the low-pass filter 7, an output of which is coupled on the one hand to a first input 12 of 25, a so-called second phase detector 39, and on the other hand via a cascade connection of a second limiter 9 and an honor 1st 90 ° phase shifter 10 at a second input 13 of the second phase detector 39 · This second phase detector 39 comprises a cascade circuit of a mixing stage 11 connected to the inputs 12 and 13 and a low-pass filter 14 connected to the first amplification limiter 15 .

The control circuit 19 to 27 comprises a 180 ° phase shifter 19 wrelke via. a so-called third limiter 21 is coupled to a second input 24 of a so-called first phase detector 27. An ext input 23 of the phase detector 27 is coupled to an output of the second limiter 9 of the frequency voltage converter 18. An output of the first phase detector 27 is connected via a so-called 8802504 PHN 9558A 5 first limiter 26 to the control input 28 of the steam circuit 29

The 180 ° phase shifter 19 includes a second 90 ° phase shifter 20 which is connected between the first 90 ° phase 5 rotary shifter 10 of the frequency converter 18 and the third limiter 21. The two cascaded 90 ° phase shifters 10 and 20 function together as a 180 ° phase rotator. The first phase detector 27 contains a cascade circuit of a mixing stage 22 connected to the two inputs 23 and Zh and a low-pass filter 25 connected to the first limiter 26 *.

The input amplifier 2 amplifies the antenna signal with carrier frequency f and offers it to the mixing stage 6. In the mixing stage 6, this antenna signal is multiplied by the signal of the voltage-controlled oscillator 17 with frequency f q, after which the desired mixing product with frequency f ^ - i * vco is selected by means of the low-pass filter 7. Undesired mixed products, for example as a result of neighboring transmitters, are suppressed by the low-pass filter 7. In a practical embodiment, the 3 <3B bandwidth of the low-pass filter 7 was 100 kHz.

The second amplifier limiter 8 linearly amplifies weak input signals (for example noise signals or signals not completely suppressed on the side edge of the low-pass filter 7) and acts as a limiter for strong input signals which pass the low-pass filter unimpeded. The output signal of the second amplifier limiter 8 is applied on the one hand to the first input 12 of the mixing stage 11 and on the other hand to the second limiter 9 where this output signal is limited in amplitude.

In the subsequent first 90 ° phase-shifter 10, a frequency-dependent phase shift takes place, wherein signals with frequency f ^ undergo a phase shift of 90 °. The frequency fj> being the characteristic frequency of the 90 ° phase shifter 10, was chosen in a practical embodiment equal to 60 kHz.

In the mixing stage 11, the output signal, and .8802504 4 PHN 9558A 6 of the 90 ° phase shifter 10 are multiplied by the output signals of the second amplifier limiter 8. The mixing products obtained thereby exhibit an amplitude which is proportional both with the phase difference between the signals applied to δ the two inputs 12 and 13 of the mixing stage 11, as with the amplitude thereof. The noise behavior of the frequency-voltage converter 18 is therefore more favorable than with conventional FM quadrature demodulators, where the two signals to be multiplied are limited. Such conventional FM quadrature demodulators also act quadratically for small noise signals, thereby interfering with the noise components located in the passband of the low-pass filter 7.

From the mixed products obtained at the output of the mixing stage 11, the audio-frequency mixed product is selected with the low-pass filter 1 h. The low-pass characteristic of this low-pass filter 14 determines the slope and tilt point of the loop gain characteristic, and thus the frequency range within which loop feedback can occur. In a practical embodiment, the bandwidth of this low-pass filter 14, also known as a loop filter, was 15 kHz.

In order to further explain the operation of the frequency-voltage converter 18, reference is made to Fig. 2, in which curve 100 shows the idealized variation of the output voltage of this frequency-voltage converter 18 as a function of the standardized tuning frequency. The frequency used for the difference frequency f ^ - "^ vco determines the level of an unmodulated antenna signal with transmitter frequency f ^.

Curve 100 is symmetrical with respect to the point, where f ^ - f ^ due to the conversion realized in the mixer 6 to a low base frequency band. Furthermore, at frequencies f, and -f. of the normal

j JL

35, the tuning frequency f - f obtained a phase shift between the signals at both inputs 12 and 13 of the second phase detector 33 of 90 °. V „. is equal to zero. If we call the frequency at which a signal .8802504 4 • ί ΡΗΝ 9558Α 7 with the level of said antenna signal in the low-pass filter 7 is almost completely suppressed f, then ë becomes at a standardized tuning frequency f - fvco * which is greater than f or smaller than -f ^, ^ DEM ° ° ^ in these Trequen-5 regions equal to zero.

At standardized tuning frequencies f - f, 'z vco, where partial suppression of the antenna signal occurs on the edge of the low-pass filter 7, the antenna signal attenuated in this way can be smaller than the signal generated by the mixing stage 6 in the pass band of the low-pass filter. 7 noise signal present. With such small signal amplitudes, the voltage V EM EM is independent of the frequency at which these occur due to the linear gain in the amplifier limiter 8. The average noise level after demodulation in the frequency voltage converter 18 therefore coincides with the average level of correct tuning in fΊ. This achieves that weak, occasionally noise-dense antenna signals do not give rise to annoying pulse-shaped disturbances, because voltage 20 jumps between the noise level and the signal level do not occur.

The output signal of the Treclueirfie voltage converter 18 is applied to the first amplifier limiter 15, in which a linear amplification of the output signal takes place up to a certain maximum signal level. This maximum signal level is reached in the respective figure under mciec at a standardized tuning frequency f - f of 0.5 f and 1.5 f. The signals above this maximum signal level are limited.

To clarify the operation of the limiter 15, reference is made to figure 3. In this figure 3, curves 110 to 116 show the idealized variation of the output voltage Vy ^ of the amplifier limiter 15 as a function of do as standardized tuning. frequency used differential frequency f - f. at z vco a certain level of an unmodulated antenna signal with transmitter frequency f.

The amplifier limiter 15 is in boundary c 8802504 PHN 9558A 8 in the areas of the normalized tuning frequency f ^ - f q indicated by curves 111 to 113. In these areas, the holding areas to be referred to hereinafter, the loop is indeed keyed, but Vy, and therefore the oscillator frequency f, remains constant. In the areas indicated by

VCO

curves 110 and 114 to 116 are linearly amplified. However, positive feedback in the frequency keyed loop 6 through 18 occurs in the areas indicated by curves 115 and 116.

The oscillator frequency will vary in these frequency ranges.

Negative feedback takes place in the areas indicated by curves 114 and 110. Stable tuning takes place in these areas, ie a locking of the frequency-keyed loop.

An undesired side tuning takes place on the curve 114, which is suppressed according to the invention in the manner described below. Curve 110 indicates the area of correct tuning or the tracking area of the voltage controlled oscillator 17

A control voltage for the mute circuit is obtained by means of the control circuit 19 to 27, shown in Figure 1, comprising the 180 ° phase-rotation network 19, the so-called third limiter 21, the phase-25 detector 27 and the so-called first limiter 26.

To clarify the operation of this control circuit 19 to 27, reference is made to Figures k and 5, in which the output voltage of the phase detector 27 and the control voltage at the output of the limiter 26, respectively, are used as a function of the standardized tuning frequency. differential frequency fz - f is idealized at one specific level of an unmodulated antenna signal with transmitter frequency f * 35 The course of the curve shown in curve 120 in Figure 1c is obtained because the inputs applied to the inputs 23 and 2k of the mixing stage 22 signals are both bounded and show a phase difference realized in the 180 ° phase-rotation ne-8802504 PHN 9558A 9 sales. The characteristic frequency of the second 90 ° -f * axis turner 20 is chosen equal to that of the first 90 ° -fas® turner 10 (f ^ = 60 kHz), so that at a standardized tuning frequency f ^ - fvco of 5 0j 0, 5 f ^ f ^ * 1.5 -0.5 -f ^ and -1.5 f ^ a phase rotation of O, respectively; 90 ° 5 180 °; 270 °; -90 °; -180 ° and -2700 are obtained. On the one hand, the bandwidth of the low-pass filter 25 should not be chosen too large, in order to avoid that the mute circuit, when tuning in the vicinity of 0.5 f ^ and 1 * 5 f · ^, is continuously switched into an audio frequency. and switched off and, on the other hand, should not be chosen too small to avoid that the tuning switches off too slowly, so that stations are skipped. A practical value for this bandwidth is 1 Hz.

The idealized variation of curve shown in Fig. 5 with curve 130 is obtained by an infinite gain of in the so-called first limiter 26. The output voltage of the limiter 26, in other words the control voltage for the stopping circuit 29, varies in a jump between 2 discrete values. . Switches take place at values -1.5 f ^; -0.5 f ^; 0.5 f2 and 1 * 5 f2 of the normalized tuning frequency f - fz vco 25 By activating the tuning circuit 29 at a positive value of Vj ^ j / pg and in the rest position at a negative value of is at a normal value even with tuning frequency f - f less than -1.5 f, * between -0.5 fp and 0.5 f2 © ft greater than 1.5 f2, the signal output 5 of the frequency-keyed loop is decoupled of the signal processing part 31 and ife the noise source 30 coupled to this signal processing part 31 · With the loudspeaker 32, the user therefore has an acoustic indication for the operation of the FM receiver, out of coordination, while a possible side tuning is shown in FIG. 3 with the region indicated in curve 114 is suppressed. The noise source can be the amplified amplified thermal noise of a resistor, I8802504 PHN 9558A 10

At a standardized tuning frequency f ^ - i'vco between -1.5 f ^ and “^> 5 f ^ and between 0.5 f ^ and 1» 5 Ij, the signal output 5 of the frequency-keyed loop is connected to the signal processing part 31 and audio frequency signals are reproduced 5 with the loudspeaker 32. As mentioned before, the frequency range between -0.5%] and -1.5 ^ the loop is positively fed back, so that this area is passed over in a jump manner and only in the correct tuning range between 0.5 f ^ and 1.5 f ^ a stable tuning is possible with an idle circuit in idle mode 29 ·

Fig. 6 shows the tuning behavior of the FM receiver according to the invention. For simplification, the frequency ivco of the voltage-controlled oscillator 17 is shown as a function of an unmodulated antenna signal with a continuously varying transmitter frequency f and a constant amplitude.

Lines p, q, r and s indicate the points at which the normalized tuning frequency f - fz vco 20 have the respective values -1.5 f1, -0.5 f ^, 0.5 f ^ and 1.5 f ^ assumes. The reverse circuit 29 is in the rest position at a standardized tuning frequency f - f between z lines along the lines p and q and between the lines r and s, beyond which the interrupt circuit 29 is activated.

25 In the area where f - f is smaller * than z vco - 1.5 f. with increasing f, first trajectory G is traversed.

The frequency-keyed loop is unlocked here and the voltage-controlled oscillator 17 is released. Thereafter, when f ^ - f ss -1.5 fj ^ range E is reached, the frequency-keyed loop is locked and the frequency Ivco of the voltage-controlled oscillator 17 is drawn along with the transmitter frequency f. The trajectory E indicates the range of the stable side tuning, which is shown by the curve 111 in FIG.

With a further increase of f, range z J is traversed. In this region, the limiter 15 is in limitation and the frequency f ^ remains at a constant value despite an increasing f. The path J corres- 8802504 PHN 9558A 11 pounds with the holding area indicated by the curve 112 in Figure 3. Since during the traversing of the ranges G, E and J the mute circuit is activated, a tuning through this frequency range takes place silently, at least only with representation of the noise from the noise source 30 serving as an acoustic indication for the tuning process.

After the range J follows with an increasing range A where positive feedback occurs in the frequency-keyed loop. The frequency ί * νοο 10 therefore decreases suddenly until the frequency keyed loop locks into place. With this sudden decrease in fvco, the partial route is passed between lines p and q. Since the switchover 29 is switched off with a certain inertia due to the small bandwidth of the low-pass filter 25, the switchover remains activated during this frequency jump by the said sub-range between p and q, so that the frequency jump is not audible.

The said locking of the frequency-20 keyed loop takes place in the correct tuning area or tracking area F. This area is indicated by curve 110 in Figure 3. The oscillator frequency f follows the transmitter frequency f over a free trough area. In this way z the demodulation function is combined with an automatic frequency control function.

The edge of the tracking region is formed by the line s, where the limiter 15 is bounded and the oscillator frequency i'VCQ remains constant with increasing transmitter frequency f. The muting circuit 29 is activated here. Route K is followed. This range K corresponds to the area shown with curve 113 in Figure 3.

As the transmitter frequency f increases further, the limiter 15 comes out of limitation and a positive feedback occurs in the frequency-keyed loop. (See curve 116 of Figure 3). The oscillator frequency ί * νοο therefore decreases suddenly until the loop is completely unlocked and the oscillator completely freezes. Route D becomes here- <. 8802504 «t PHN 9558A 12 when going through *

With a further increasing transmitter frequency f, the frequency-keyed loop remains unlocked and * z traverses section H. When tuning over the ranges δ K, D and H, the mute circuit is activated and only the noise from the noise source 30 used as acoustic tuning indication is audible. In a practical embodiment, the tracking area F was found to be approximately 350 kHz.

Starting from the frequency range now reached, at a decreasing transmitter frequency f after the range H, the section M is traversed where the unlocking of the frequency-keyed loop continues to exist. With further decreasing transmitter frequency f, normalized tuning frequency f - f decreases until the value f is reached and z vco g 15 positive feedback occurs in the loop (curve 116 of figure 3). At that moment the oscillation frequency fQSC suddenly, until the frequency-keyed loop locks. This frequency jump, represented by curve B, is inaudible due to the activated dumb circuit 29 in this frequency range.

The frequency-keyed loop is locked in the correct tuning or tracking area F, where demodulation and automatic frequency control can take place. The dimming circuit 29 is here in the rest position. The edge of the tracking area F wox-dt at a decreasing transmitter frequency f reaches at the line r.

z

The normalized tuning frequency f ^ - f ^ here is 0.5 f ^ · The limiter 15 comes into limitation and trajectory L, corresponding to the area represented by the curve 111 in Figure 3, is traversed. The stomp circuit 29 is now activated.

"As the transmitter frequency f decreases further, a positive feedback occurs in the frequency-keyed loop at the line q, as a result of which the oscillator frequency o ogc suddenly increases, until the loop is unlocked and the voltage-controlled oscillator 17 is fully idle. During this, section C is completed. As with the range A, this frequency jump across the range C passes the .8802504 * • a PHN 9558A 13 region between lines p and q. Due to the small bandwidth of the low-pass filter 25, the mute circuit 29 is switched off with a certain delay, so that it remains activated during the passage of the latter region between p and q. The frequency jump is thereby suppressed. With a further decrease in the standardized tuning frequency fz - fvco, the. frequency-keyed loop is unlocked and the voltage-controlled oscillator 17 is completely free.

It should be noted that it is also possible to dimension the amplifier limiter 15 and / or the control circuit 19 to 27 such that a limitation of VCO rains occurs before the stub circuit 29 is activated. Due to the audible sound distortion associated with this limitation, the user has an indication when tuning to an edge of the correct tuning area.

Figure 1a shows an AM receiver 11 according to the invention, waax-in the circuits, which perform the same function as the circuits of the FM receiver 1 of Fig. 1, are correspondingly numbered. The AM receiver 1 * differs from the FM receiver 1 in that the demodulator function does not take place in the frequency-voltage converter 18 but in an amplitude detector connected to the low-pass filter 7 via an AGC amplifier 8 '. 51 »An output of the amplitude detector 51 is coupled on the one hand via an AGC filter 50 to a control input of the AGC amplifier 8 'and on the other hand to the input 33 of the muting circuit 29 · The time constant of the AGC filter 50 is approx.

0.1 second.

The frequency-voltage converter 18 only functions as a control generating circuit for an automatic frequency control, which has been realized by replacing the audio-frequency low-pass filter 1h of the FM receiver 1 with an automatic frequency control filter 14 'with a time constant of about 1 second .

The idealized variation of the output voltage of the frequency spawning converter first amplifier limiter 15 * the first phase detector 27 and the .8802504 * 4 PHN 9558A 14 first limiter 26 of this AM receiver 11 according to the invention as a function of the standardized, unmodulated tuning frequency at one particular level of the antenna signal as well as the tuning behavior for unmodulated signals 5 does of course not deviate from that of the FM receiver 1 and is shown in Figures 2 to 6.

10 15 20 25 30 35! .8802504

Claims (3)

1. A radio receiver provided with a frequency-keyed loop, successively comprising a voltage-controlled oscillator 5 with an input for the output shaft voltage, a mixing stage connected to an antenna input, a filter element, a frequency-voltage converter connected to the voltage-controlled oscillator and a blanking circuit for blocking an audio signal out of tuning, characterized in that the frequency-voltage converter is coupled to the voltage-controlled oscillator via a first amplifier limiter 10. Radio receiver according to claim 1, characterized in that the frequency-voltage converter is connected to the first amplifier limiter via a low-pass filter with a bandwidth of at least the audible audio-frequency range. 15 3. Radio receiver as claimed in claim 2, characterized in that the frequency-voltage converter comprises a multiplication signal, one of which is connected, output to said low-pass filter and a second amplifier limiter via which the filter member is coupled to a first input of the multiplier stage and on the other hand to a limiter, 20 is coupled to a second input of the multiplier stage via a frequency-dependent 90 ° phase shifter. 25 30 35 .8802504