DE2759700C2 - Radio receiver - Google Patents

Description

The present invention relates to a radio receiver according to the preamble of the patent claim.

With shortwave radio, the carrier frequencies are within the broad frequency band of 3 ... 30 MHz, and there are, for example, 4000 ... 5000 KW radio stations alone. The minimum unit on which the carrier frequencies Such transmitters are tuned in is of the order of kilohertz. A recipient who is such To record HF signals, it must be able to record the desired signal precisely and stably. Conventional HF broadcast receivers are not always satisfactory in this regard. Often one can Set the desired station only with difficulty and it can often happen that a well-set Receiver wanders beyond the set frequency.

In a method for improvement known from Japanese Patent Application No. 50-147811/1975 The tuning frequency of the local oscillator is digitally counted and shown on a display device. In such a method, the receive frequency should be accurate and can be counted and displayed in a stable manner. It is known to give precise details of the overlay receivers Receive frequency to count the oscillation frequency of the local oscillator directly and by addition or subtract the intermediate frequency - for example 455 kHz - to correct. The reception frequency is then output digitally immediately. This method is problematic because it occurs when receiving signals in the HF band. 3 ... 30 MHz at the bottom At the end of the range, only a relatively small frequency drift is to be expected, while at the upper end of the range It is difficult to keep the desired signal stable for a long period of time, even with a precise setting is. In addition, if a receiver has a digital display

ίο has, very high frequencies must be counted here will. Depending on the intermediate frequency, for example, with a frequency of 455 kHz, the counter must be up to 30.455 kHz can count. This makes a very fast integrated circuit such as one TTL circular receiver required, which is because of the heat generated and the radiated interference emitted is undesirable.

It is also known from DE-AS 15 41 591, a tunable oscillator whose oscillation frequency is sufficiently far below the upper range limit (e.g. 30 MHz) of the desired reception range, as well as a reference frequency oscillator, such as using a crystal oscillator that provides a stable reference frequency. The output signals these two oscillators are mixed and in a band filter to a desired higher mixing frequency filtered, the sum or difference frequency of the two generated oscillation frequencies represents

With this method, however, it is difficult to filter out only the desired admixing frequency, since all of them Interference frequencies, d. H. the higher harmonics of the two oscillation frequencies and their cross-modulation components, must be filtered out at the same time.

In addition, there is the disadvantage that this method has many bandpass filters and a very fast one for digital representation of the reception frequency with a digital counter and requires a presettable counter which is usually expensive.

From DE-AS 11 90 522 is a superimposition receiver known, in which the oscillations are generated by a counter which can be set in advance within predetermined time intervals an oscillator that is used to convert the receiving frequency into the intermediate frequency is provided. In order to be able to display the reception frequency, the counter is reset by Intermediate frequency adjusted. A disadvantage is also that a faster and therefore more expensive and expensive frequency counter must be used when the frequency supplied to the counter is high is.

From DE-AS 12 56 274 a superimposition receiver is known in the two oscillator frequencies to display the reception frequency with a double Overlay provided receiver are mixed and in which the mixed output frequency is counted.

DE-AS 19 12 857 discloses a circuit arrangement for measuring and displaying the tuning frequency a heterodyne receiver known. Thereby the received signal and the first output signal a variable frequency local oscillator mixed, wherein an intermediate frequency is generated. A frequency counter for digital display of the frequency

b5 sequence of the received signal is the second generated by an oscillator of the local oscillator Output signal with a variable frequency during a predetermined period of time via a gate

The display is derived from the counting result A disadvantage of such a circuit arrangement in which the received frequency is completely counted is that a faster and therefore more complex and expensive frequency counter is used must be when the frequency applied to the counter is high

The object of the present invention is therefore to provide an improved radio receiver with a specify simple circuit arrangement that can be precisely and stably tuned and in the case of interfering signals are eliminated.

This object is achieved by a radio receiver of the type mentioned, which is characterized by the Part of the claim specified features is characterized

A major advantage of the present invention is that the receiving frequency with a relatively slow frequency counter is displayed.

Advantageously, in the radio receiver according to the invention, which has a simple structure. failure when displaying the reception frequency.

In the following the invention is explained in more detail in connection with the figures. It shows

F i g. 1 is a block diagram of an embodiment of a radio receiver according to the invention,

F i g. 2 is a circuit diagram of an embodiment of a first local oscillator as used in the radio receiver according to FIG. 1 is used, and

F i g. 3 a circuit diagram of a frequency counter, partly in block form, as used in a radio receiver according to the invention.

F i g. 1 shows a HF receiver with double superposition, in which the reception frequency is displayed digitally. In Fig. 1, is applied picked up by an antenna 1 signal to an H F-amplifier 2, which has a selection circuit for the reception signals of the receiving frequency / ₀ The selected reception signal of the reception frequency is k at the input terminal 4 of a first frequency mixer 3. This first Frequency mixer 3 has a further input to which the first output signal of a local oscillator 5 is applied. The received signal of the received frequency / Ό and the first output signal of the frequency f \ of the local oscillator 5 are mixed in the first frequency mixer 3 to form a signal of a first intermediate frequency / j, which is the sum or the difference frequency of the two input frequencies (f ₂ = / Ό ± f \).

The first intermediate frequency amplifier 6 following the first frequency mixer 3 amplifies the first IF signal and delivers its output signal to a second frequency mixer 7, which mixes the first IF signal and the output signal of the frequency f _{r2 of} a further local oscillator 8. The output signal of the further local oscillator 8 has a second intermediate frequency / 3 = / 2 ± / »2 and is applied to a second intermediate frequency amplifier 9. The second intermediate frequency amplifier 9 is connected to an AM demodulator 10, which in turn is connected to an LF amplifier 11 to which a loudspeaker 12 is finally connected. Furthermore, a frequency counter 13 with a frequency counter 14 and a digital display device 15 is connected to the first tunable oscillator contained in the first superposition oscillator 5. The frequency counter 13 counts the oscillation frequency of the second output signal of the local oscillator 5 and represents the reception frequency digitally. Since the in FIG. 1, with the exception of the local oscillator and the frequency counter 13, can be constructed from known circuits as are familiar to those skilled in the art, these blocks are not described further.
FIG. 2 shows an embodiment of the local oscillator 5 of FIG. 1. In Fig. 2, an oscillation frequency fy 1 of the tunable oscillator 16 is low and its tuning range Jf " 1 is small, so that a stable output frequency can easily be achieved (for example /", = 5 ... 9 MHz; Afvx = 4 MHz). As he-

The reference frequency oscillator 18 becomes a fixed frequency oscillator of high stability such as a quartz oscillator used, its oscillation frequency / ri is above the upper limit of the reception range (for example / r, = 60 MHz).

The output signals of the frequencies f _v 1 and //? 1 of these two oscillators go to a first premixer 19 and are mixed by this. At the output of the first premixer 19 there is a first bandpass filter 20 which only allows the component (ίκ \ + f _v \) of the mixer output signal, for example 56.

A second reference frequency oscillator 22 and a third reference frequency oscillator 23 are stable fixed frequency oscillators with oscillation frequencies / «2 and fg 3 (for example fm = 40 MHz, f _R3 = 48 MHz). With a band switch 24, one of the output signals of the second or third reference frequency oscillator 22 or 23 is selected and sent to the second premixer 21. When the first band switch 24 selects the second reference frequency oscillator, the second premixer 21 supplies a frequency component Z ₁ , which is the difference between the output signal of the frequency (fü \ + fv \) of the first band filter 20 and the oscillation frequency fft 2 of the second reference frequency oscillator 22nd

(ie f \ = / «) - / λ2 + fv \) acts. A second band filter 25 only allows this frequency component / ■, = / "", - f _K 2 + / Ii (for example / i = 25 which is the output connection of the local oscillator 5 and which leads to the first frequency mixer 3. If the center frequency of the first IF amplifier 6 is 2 MHz in the case of the above frequency example (in brackets), shortwave signals of 27 .. Record 31 MHz satisfactorily.

In the case of amateur band receivers, a so-called premixing process is conventionally used, in which a tunable oscillator and a reference oscillator are used, their sum or difference frequency serves as an admixing signal. Since the reception bands of such receivers are relatively narrow the desired admixing signal can easily be separated from undesired interfering components. Are However, the reception areas of HF radio receivers are wider, as a result of the premixing process numerous spurious components at the output of the local oscillator, so that such a premixing process For example, for short-wave radio receivers only un-

b5 less difficult to apply.

Since in the present case the oscillation frequency of the local oscillator 5 is initially set to above the Fre-

sequence is mixed up by means of a first reference oscillator and then mixed down again with the second reference oscillator, as was explained above, it becomes possible to eliminate the above-mentioned interference components. In addition, since the oscillation frequency f, ι of the oscillator can be made low, very stable reception of HF radio signals is possible. Furthermore, by counting the oscillation frequency Λ ι, the reception frequency /. i »represent comparatively simply digitally. If the oscillation frequency f * \ is high, however, a faster and therefore more expensive frequency counter must be used.

With HF radio receivers, the entire reception range of 3 ... 30 MHz is usually divided into suitable bands, in the example mentioned above, the band from 27 ... 31 MHz can be received. For the reception frequencies below 27 MHz, many other reference oscillators and band filters, such as those for the oscillator 23 and the band filter 26, are required. However, by making the tuning range Ai _x \ of the tunable oscillator 16 of the local oscillator 5 twice as wide as the center frequency of the first IF amplifier 6, the number of reference oscillators and band filters required can be halved. In the example mentioned, the center frequency of the first IF amplifier 6 is equal to 2 MHz, so that the tuning range Af _v \ = MHz. In the output terminal 29 of the local oscillator 5 is a signal of the frequency 25 ... 29 MHz, with which not only the receiving band 27 ... 31 MHz, but also that of 23 ... 27 MHz can be reached, since the center frequencies these two bands are at a distance of twice the intermediate frequency.

F i g. 3 shows an embodiment of a frequency counter 14 as used for the radio receiver according to the present invention. The output terminal 17 of the tunable oscillator 16 of the local oscillator 5 of FIG. 1 is connected to the input 30 of an isolation amplifier 31 (FIG. 3). The output signal of the oscillator 16 with the oscillation frequency /, 1 is amplified by the isolating amplifier 31 and applied to a gate circuit 34 in the circuit 32. If this is necessary, a driver 33 can be switched on between the isolation amplifier 31 and the gate circuit 34. The switching time of the gate circuit 34 is determined by the switching time general 35 connected to the gate circuit 34. The frequency of the signal switched through by the gate circuit 34 is counted by a frequency counter 36 connected to the gate circuit 34 for the lower digits. This frequency counter 36 is not relocatable and counts the lower digits of the oscillation frequency fy 1 of the oscillator 16. In contrast, the frequency counter 38 for the upper digits, to which a presetting stage 37 is connected, can be set in advance. The advance stage 37 determines the value to which the counter is advanced. The frequency counter 38 is connected to the frequency counter 36 and counts the upper digits of the oscillation frequency f _v \ of the oscillator 16. The digital information at the outputs of the two frequency counters goes to a driver circuit 39 and from there to a display 40, which consists, for example, of light emitting diodes Da the in F i g. 3 can be built with circuits that are familiar to the person skilled in the art, a detailed description of the same is dispensed with here

According to the present invention, the receiving frequency / 0 is displayed digitally by using the tunable oscillator 16 with a tunable circuit which provides an oscillation frequency Λ 1 which corresponds to the receiving frequency f ₀ in the lower digits, the difference in the upper digits is corrected by the offset 37. It is therefore possible to use a slower and therefore cheaper counter 36 that cannot be moved, so that HF radio receivers digitally display the reception frequency with little effort.

For this purpose 3 sheets of drawings

Claims (1)

Claim: Radio receiver with a device for digitally displaying the reception frequency / o of a received signal, with a local oscillator which delivers a first output signal of the frequency f \ and contains an oscillator for generating a second output signal with a variable frequency / Vi, with a frequency mixer for mixing the received signal and the first output signal to form an intermediate frequency Fz = / Ό ± / | and with a frequency counter which is connected via a gate circuit to the second output signal of the local oscillator, characterized in that the frequency counter (14) has a frequency counter (36) for the lower digits and a frequency counter (38) for the upper digits, that the frequency counter (36) for the lower digits through the gate circuit (34) during a predetermined period the oscillation frequency / Vi of the oscillator for generating a variable frequency which _{corresponds to the receiving frequency Z 0} in the lower digits, that the counter (38) for the upper digits is connected to the counter (36) for the lower digits and can be preset by a presetting stage (37) so that the presetting stage (37) generates digital code information which is the difference between the reception frequency / ö and the Oscillation frequency / Vi corresponds to that the digital code information in the form of an integer value to the counter (38) for the Upper Siell is applied, and that the counter (38) for the upper digits counts the upper digits of the oscillation frequency / V ι and adds the value preset by the presetting stage (37) to the counted value.