DE2045821C3 - Radio receiver for optional superimposition reception of frequency or amplitude modulated vibrations - Google Patents

Description

It is known for the optional reception of frequency-modulated or amplitude-modulated vibrations (German Patent 8 41 295), both types of modulation after mixing, each with a special one if necessary convert the switchable oscillator frequency into the same intermediate frequency and amplify it in the same intermediate frequency channel. The intermediate frequency channel must be designed as a broadband amplifier with regard to the frequency modulation and is accordingly not selective for the amplitude-modulated oscillation. A sufficient tuning sharpness of the device is achieved with the intermediate frequency demodulation. In this known device are so separate input circuits for frequency-modulated and amplitude-modulated signals are provided can optionally be given by switching to a mixer stage, to which FM or AM oscillators can be further switched over by a corresponding switching process are connectable. High frequency amplifiers are not provided. As a result, the reception of amplitude-modulated signals is not always satisfactory. There In addition, two separate input circuits are required for amplitude-modulated and frequency-modulated signals, two high-frequency amplifiers would be added use. The resulting circuit is complicated

But it is already known ("radio mentor" 1952, p. 028, "Funkschau" volume 1951/52, 140), in radio

receive the same high-frequency amplifier for amplitude-modulated and frequency-modulated signals use that over a different frequency channels having signal transmission circuit is connected to the mixer. But here are at least s two or more mechanical switches required between high frequency amplifier and mixer, who have to switch frequency-modulated signals. This also makes this circuit complicated, expensive and maintenance-prone, as switches in FM transmission links because of the extension of the transmission link, the stray capacitances and the resulting feedback phenomena constitute a possible source of interference.

The invention is based on the object of building a radio device so that one and the same High frequency amplifier transistor and one and the same frequency converter transistor (mixer) for both amp. 'customer-modulated as well as frequency-modulated Signals can be used without d * ß in the Signal transmission path between the two for AM-FM switchover mechanical switches required who have to switch frequency-modulated signals. This task is achieved by the in claim 1 specified invention solved

With such a design of the radio receiver, a particularly simple structure is achieved the particular switch between the high-frequency amplifier and mixer are not required. counter are only there with such a structure of the signal transmission circuit for AM-FM switching required where only amplitude-modulated signals, i.e. signals of far lower frequency, are to be switched. In addition, the signal transmission circuit as well as the entire frequency mixing is with circuit technology simple measures achieved The complicated mechanical switches for AM-FM switching are saved. Advantageous developments of the invention are described in the subclaims.

An exemplary embodiment of the invention is illustrated with reference to FIGS. 1 and 2 explained. It shows

F i g. 1 is a circuit diagram of an embodiment of the AM-FM radio receiver according to the invention and

FIG. 2 is a circuit diagram of the individual electrical circuits in FIG. 1 illustrated embodiment.

F i g. 1 is a circuit diagram showing the electrical connections of an embodiment of an AM-FM radio receiver according to the invention, which has a high-frequency amplifier circuit A \ for AM and FM, a frequency mixing circuit A ₁ for AM and FM, a receiving oscillator circuit A3 for FM and a receiving oscillator circuit A for AM A coil L \ and a capacitor C ₂ form an FM tuning circuit in which one end of the coil is grounded via a capacitor C \

The connection point between the coil L \ and the capacitor Ci is connected via a resistor R \ to the output side of the local oscillator circuit A »for AM. A coil L ₂ , a capacitor Ca and the capacitor C \ form a suction circuit which is tuned to the FM intermediate frequency. There are also coupling capacitors Cs and G and intermediate frequency transformers Ti and T ₂ for AM and FM, respectively. Switches Si and & for switching to AM μ or FM work coupled, whereby the moving contact of the switch is switched to terminal 3 for AM reception and to terminal 1 for FM reception

The following describes the reception of FM broadcasts with reference to FIG. 1 explained

When an FM radio broadcast is received, the movable contacts Si and S ₂ are allocated to the terminal 1. As a result, a supply voltage via the switch S ₂ is applied to the FM local oscillation circuit A3 which this is brought in the operating state.

An FM high-frequency signal amplified by the high-frequency amplifier circuit Ai is given to the FM tuning circuit, which consists of the coil L1 and the variable capacitor C ₂ and which is tuned to a desired signal. The signal is passed through the coupling capacitor C ₃ to the frequency mixing circuit A ₂ , to which the output voltage of the AM receiving oscillator circuit is applied so that an FM intermediate frequency signal appears at the output of this circuit. This FM intermediate frequency signal! is taken from the FM intermediate frequency transformer Ti .

In this case, the AM _{local oscillator circuit A 4 is} inoperative because its output terminal is grounded through the switch Si. Furthermore , the FM tuning circuit formed by the coil Li and the variable capacitor Ci acts as a load on the high-frequency amplifier circuit A1.

If an AM radio transmission is now received, the movable contacts of the two switches Si and Si are switched to the terminals 3 and therefore the FM receiving oscillator circuit A3 is inoperative and the AM receiving oscillator circuit Aa is brought into operation

Since when receiving an AM radio transmission, the impedances of the coil Li belonging to the FM tuning circuit and the coil L ₂ belonging to the suction circuit become very low, an AM high-frequency signal amplified by the high-frequency amplifier circuit is transmitted through the coil together with the output voltage of the AM receiving oscillator circuit Aa Li, the capacitor Ca and the coil L _{2 are given} to the frequency mixing circuit A ₂ . As a result, an AM intermediate frequency signal appears at the output of the frequency mixing circuit A ₂ . This AM intermediate frequency signal is picked up by the AM intermediate frequency transformer Ti.

In this case, the capacitor C ₁ , the resistor R \ and an oscillator coil L * forming the AM receiver oscillator circuit Μ act as a parallel load of the high-frequency amplifier circuit. It is therefore advantageous in the suction circuit formed by the coil L ₂ and the capacitors Ci and Q to choose the capacitance of the capacitor Ci so that the value compared to the capacitance of the capacitor Q is quite low in order to reduce the attenuation of the output of the AM receiver oscillator circuit so that the load as the load of the high frequency amplifier circuit Ai does not become extremely low in impedance. Furthermore, it is desirable that the value of the capacitance of the capacitor G is chosen so that the impedance of the AM reception oscillator output and the AM high-frequency output does not become large, and the coil L ₂ is chosen so that its impedance is suitable for a signal of the AM Reception frequency is quite low.

F i £ 2 shows more details of the circuit of the AM-FM radio receiver. A whip antenna 1 for AM and FM is via a coil 2, which is at AM reception as a throttle for the FM frequency band

acts, connected to the neutral terminal b of an AM-FM switch 3.

The AM terminal a of the switch 3 is connected via a coupling capacitor 4 to one end of a ferrite rod antenna 5, while the FM terminal c via a capacitor 6, which is tuned to the FM frequency band together with the coil 2, to one end of a Parallel resonance circuit is connected, which consists of a coil 7 and a capacitor 8, the other ends of which are grounded.

The intermediate tap of a step-up coil 9, one end of which to the FM terminal c of an AM-FM switch 11 and the other end directly to the other end of the ferrite rod antenna 5 and a -B- power source is connected via a Capacitor 10 is connected to the output side of the capacitor 6.

The connection point between the ferrite rod antenna 5 and the coupling capacitor 4 is connected to the AM terminal a of the AM-FM switch 11, to which a variable capacitor 12 and a trimmer capacitor 13 are connected Form voting circle.

The figure also shows a high-frequency amplifying transistor 14 for AM and FM, the control electrode of which is connected to the middle terminal b of the AM-FM switch 11 and its source directly to the -B- energy source, while its discharge via a coil 15 and a capacitor 16 comparatively low capacitance is grounded

A neutralizing capacitor 18 is provided between one connected to the step-up coil 9 Coil 17 and the drain of the high frequency amplifying transistor 14 are connected. A variable capacitor 19 and a trimmer capacitor 20, which are at FM reception together with the coil 15 form a tuning circuit, are between the drain of the High frequency amplifier transistor 14 and connected to ground

In the case of a frequency mixing transistor 21 for AM and FM, the base is via a coupling capacitor 22 connected to the drain of the above-mentioned transistor, while the emitter is connected via a bias resistor 23 to the - B energy source and the collector via one of a series circuit of an intermediate frequency transformer 24 for AM is grounded with an intermediate frequency transformer 25 for FM existing circuit

The connection point between the intermediate frequency transformer 24 for AM and the intermediate frequency transformer 25 for FM is connected to the AM terminal a of an AM-FM switch 26, whose neutral terminal b is grounded and its FM terminal c via a load resistor 27 with the connection point between the coil 15 and the capacitor 16 is connected. Furthermore, the emitter of an FM oscillator transistor 28 is connected via a resistor 29 to the FM terminal c of an AM-FM switch 30, the neutral terminal i of which is connected to the - B energy source, while the collector of this transistor is connected to the intermediate tap of a coil 33 which, together with a variable capacitor 31 and a trimmer capacitor 32, forms a resonance circuit. A feedback capacitor 34 is connected between the collector and the emitter. The emitter is also connected to the base of the frequency mixing transistor 21 via a capacitor 35 connected. The base and emitter of an AM oscillator transistor 36 are provided with a bias source, whose voltage is slightly higher than that of the - B energy source, or via a bias resistor 38 connected to the - B energy source, while the collector is grounded via the primary winding of an oscillator coil 39. The secondary winding of the oscillator coil 39 is connected via a coupling capacitor 42 a variable capacitor 40 and a trimmer capacitor 41 connected, with which together they the The intermediate tap of the secondary winding is directly connected to the FM terminal c des AM-FM switch 26 and via a feedback capacitor 43 to the emitter of transistor 36 connected.

One end of a coil 44 is across a capacitor 45 large capacitance is connected to a point between the coil 15 and the capacitor 16. The sink forms together with the capacitor 16 with smaller Capacity an intermediate frequency suction circuit tuned to the FM intermediate frequency. Between Connection point between coil 44 and capacitor 45 and the bias source is a Bias resistor 46 are also connected Base bias resistors 47 and 48 of the FM oscillator transistor 28 are provided. Bridging capacitors 49 and 50 are between the base of the FM oscillator transistor 28 and the ground or between the base of the AM oscillator transistor 36 and the ground switched between the -B energy source and the

Ground is a capacitor 51 and between the emitters

of FM oscillator transistor 28 and the ground is on

Capacitor 52 switched The above embodiment operates upon reception

an FM broadcast as follows:

When an FM transmission is received, all movable contacts of the AM-FM switches 3, 11, 26 and 30 are switched to the respective FM terminals c. As a result, the one from the ferrite rod is on tenne 5 and the variable capacitor 12 as well as the parallel to this capacitor 13 existing AM tuning circuit separated from the control electrode of the high-frequency amplifier transistor 14, during the Intermediate tap of the AM oscillator circuit forming Coil 39 is grounded so that the AM oscillator circuit is out of order and therefore no AM transmission can be received. One on the whip antenna 1 received FM high frequency signal is via the coil 2 and the capacitors 6 and 10 to the

so the step-up coil 9 is given and passed on to a circuit that represents the inductance of part of the coil 9 between its intermediate tap and the - B energy source and the capacitance of the capacitors 10 and 51 and resonates with the FM signal

ss The FM signal is amplified by the remaining part of the coil 9 and then switched on via the AM-FM switch 11 the control electrode of the high frequency amplifier transistor 14 given. That at the control electrode of the High frequency amplifier transistor 14 appearing

μ FM high frequency signal is in this transistor further amplified, and its output voltage is in the FM tuning circuit consisting of the coil 15, the variable capacitor 19 and the trimmer capacitor 20.

u tes FM signal tuned, and the tuned The FM signal is applied via the coupling capacitor 22 between the base and emitter of the frequency mixing transistor 21

On the other hand, it becomes the FM oscillator circuit associated oscillator transistor 28 by connecting its emitter via the AM-FM switch 30 with the - S energy source brought into operating condition, with an oscillator output signal 5 appears, the one by the coil 33, the variable capacitor 31 and the trimmer capacitor 32 has a certain frequency. This oscillator output signal is via the capacitor 35 to the base of the Frequency mixing transistor 21 passed. Therefore, a appears at the collector of the frequency mixing transistor 21 Signal one by the oscillator output signal and the FM signal supplied via the coupling capacitor 22 generated intermediate frequency. This signal is given to the intermediate frequency transformer 25 and removed from its output terminal 53.

The following describes the operation when receiving AM broadcasts.

When receiving AM transmissions, all movable contacts of the AM-FM switch 3, 11, 26 and 30 are connected to the respective AM terminals a. As a result, the whip antenna 1 via the coil 2 and the capacitor 4 with one end of the Ferrite rod antenna 5 is connected, and the step-up coil 9 is separated from the high frequency amplifier transistor 14. At the same time, the intermediate tap of the secondary winding becomes the one belonging to the AM receiver oscillator circuit Oscillator transformer 39 or the emitter of the FM oscillator transistor belonging to the FM receiver oscillator circuit 28 separated from the earth or the - ß-energy source, while the FM intermediate frequency transformer 25 is short-circuited by the AM-FM switch 26. Therefore, no FM transmission can be received.

An AM signal received at the whip antenna 1 or the ferrite rod antenna 5 is through the Ferrite rod antenna 5, the variable capacitor 12 and the trimmer capacitor 13 via the AM-FM switch 11 given to the control electrode of the high-frequency amplifier transistor 14. This AM signal is amplified by the high frequency amplifier transistor 14 and via the coil 15, the capacitor 45 with large capacity and the IF isolating coil 44 to the base of the frequency mixing transistor 21 given.

If, on the other hand, the intermediate tap of the oscillator coil forming the AM local oscillator circuit 39 is separated from the earth, the AM local oscillator circuit oscillates on a through the oscillator coil 39, the variable capacitor 40, the trimmer capacitor 41 and the coupling capacitor 42 are determined so Frequency and an output signal with this frequency appears at the intermediate tap of the coil 39. This The output signal is passed through resistor 27, capacitor 45 and coil 44 to the base of the Frequency mixing transistor 21 set Therefore, the frequency mixing transistor 21 operates in a predetermined Manner so that an AM intermediate frequency signal is generated at its emitter. This AM intermediate frequency signal is given to the AM intermediate frequency transformer 24 and from its output terminal 53 removed.

In addition, in the embodiment described above, the coil 15, the variable capacitor, acts 19 and the trimmer capacitor 20, which together form the FM tuning circuit, as a load for FM reception for an amplified high-frequency FM output, while resistor 27 is used as a load for AM reception for an amplified high frequency AM output

As can be seen from the explanation of the above embodiment, the high frequency amplifier circuit and the frequency mixing circuit when receiving signals from the AM as well as the d.s. FM frequency band can be used. You can also switch from AM to FM or vice versa precisely and precisely without any complex mechanical switch in front of the frequency mixing circuit be performed. As a result, the whole structure of the radio receiver can be simplified considerably. Furthermore, the responsiveness in AM reception can be improved even without a special high-frequency amplifier circuit can be improved significantly, and therefore remarkable advantages in characteristics can be found. Thus, a AM-FM radio receivers of high selectivity are created in that a field effect transistor is used as the high frequency amplifier transistor 14, with a high value resulting from the Combination of the input impedance of the field effect transistor and the step-up impedance of its input circuit results, can be achieved by such a construction in which a by reinforcing the FM high frequency signal obtained by the step-up coil 9 and the AM high frequency signals be switched by the switch 11, so that one of the two to the control electrode of the above Transistor is given. In addition, an AM-FM broadcast receiver becomes high as a whole Responsiveness created by the fact that the output of the high frequency amplifier transistor 14 supplies a high signal voltage because the coil inductance between the intermediate tap of the Coil 9 and the —S energy source and the capacitance of the coupling capacitor 10 comprehensive circuit with the received high-frequency signals oscillates in resonance and these signals through the step-up coil 9 be reinforced, further that a tuning circuit is available, which consists of the with the intermediate tap Up coil 9 connected coupling capacitor 10 and the coil between the intermediate tap of the mentioned coil 9 and the - ß-energy source and that on the middle frequency of the received Frequency band is tuned, and that one appears between the end terminals of the step-up coil 9 Voltage between the control electrode and the source of the high frequency amplifier transistor 14 is applied.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Transistorized radio receiver for optional reception of frequency- or amplitude-modulated vibrations with a common HF amplifier that can be switched from AM to FM reception and a common IF mixer for the AM and FM signals, with separate AM and FM channels in the signal transmission path between the HF amplifier and the mixer stage and AM and FM receiving oscillators which can be optionally switched on via AM-FM switches, characterized in that the signal transmission circuit consists of an FM tuning circuit connected to the output of the high-frequency amplifier (Ar, 14), which is formed from a first coil (Lr, 15) connected to the output of the high-frequency amplifier and connected to ground via a first capacitance (Cr, 16) and a variable second capacitance (C ₂ ; 19) connected in parallel to this, further comprising a the input of the mixer (A ₂ ; 21) connected to the FM intermediate frequency suction circuit, the one connected to the input of the mixer second coil (L ₂ ; 44) and the first capacitance (Cr, 16) connected in series with both coils is formed, and finally consists of a coupling capacitor (Cy, 22) connected between the output of the high-frequency amplifier and the input of the mixer, and connected between the output of the high-frequency amplifier and the input of the mixer, and for High-frequency signals for FM reception via the coupling capacitor (C ₃ ; 22) and for AM reception via the two coils (L _u L ₂ ; 15, 44) is permeable, and that the FM load representing the FM load on bsi FM reception -Abstimmkreis occurring FM signals together with signals from the FM receiving oscillator (A ₃ ; 28), with AM reception the one at the AM load, through the first capacitance (C \; 16) and one of these with the AM receiving oscillator (A4; 36) connecting resistor (R \, 27) is formed, occurring AM signals are applied to the input of the mixer (A ₂ ; 21) together with the signals from the AM receiving oscillator. 2. Radio receiver according to claim 1, characterized in that the output of the high-frequency amplifier (Ar, 14) via the coil belonging to the FM tuning circuit (Lr, 15) and the resistor (Rr, 27) with a to the AM receiving oscillator (A ^ ; 36) belonging oscillator coil (L · ,; 39) is connected, and that the connection point between the oscillator coil and the resistor and the connection point between an AM intermediate frequency transformer (Tr, 24) and an FM intermediate frequency transformer (T ₂ ; 25), which are connected in series to the output of the mixer (A ₂ ; 21), each connected to the terminals of an AM-FM switch (Sr, 26), the neutral terminal (2; b) of which is grounded, and the one for FM reception the connection point of the resistor with the oscillator coil, in the case of AM reception the connection point of the two intermediate frequency transformers to earth. 3. Broadcast radio receiver according to claim 1 or 2, characterized in that the high frequency converter μ stronger is a field effect transistor, the control electrode of which is connected to a terminal of an AM-FM switch (11), which can optionally be connected to it FM terminal (C) or its AM terminal (a) can be connected, of which the first is connected to one end of a step-up coil (9) and the second to an AM tuning circuit (5, 12, 13), one between an intermediate tap of the up coil (9) and the antenna (1) switched capacitor (6) together with the up coil has a resonance frequency which is close to the frequency of the FM received signal 4. Broadcast radio receiver according to claim 3, characterized by an antenna circuit connected to the antenna (1) to which the high-frequency amplifier (14) is connected, by a Antenna circuit forming coil (2) connected to the antenna, which has a high impedance for a received signal of the FM frequency band and a low impedance for a received signal of an AM frequency band, and connected by one to the output of the coil AM-FM switch (3), the FM terminal of which is connected to the capacitor (6), which together with the coil (2) a band-pass filter which passes a received signal of the FM frequency band forms, and its AM terminal directly with the AM terminal of the AM-FM switch at the input of the high frequency amplifier is connected 5. Radio receiver according to one of claims 1 to 4, characterized in that the capacitor (Cr, Lö) of the intermediate frequency suction circuit is a capacitor of small capacitance and that the connection point between the capacitor of small capacitance and the first coil (L ₁ ; 15) on the one hand or the resistor (R \; 27) representing the AM load, on the other hand, via a capacitor (Ca; 45) of large capacitance to the second coil (L ₂ ; 44) and via this to the input of the mixer (A ₂ ; 21) connected is