DE3744471A1 - AM/FM band selector - Google Patents

Abstract

The invention relates to an amplitude modulation/frequency modulation or, respectively, AM/FM band selector by means of which AM/FM bands or ranges can be selected by means of an electronic switch of the control capacitor type of resonance, particularly an electronic quiet-tuning-type AM/FM band selector which is capable of suppressing pulse-like interference signals (clicking noises) during the switching-off of the power supply or when selecting (switching-over) the AM/FM band.

Description

The invention relates to an amplitude modulation / frequency modulation or AM / FM band selector, with which AM / FM band the or areas by means of an electronic switch of the control capacitor resonance type are selectable, in particular an electronic breastfeeding AM / FM band selector, the pulse-like interference signals (crackling noises) when Ab switching the power supply or when dialing (switching) of the AM / FM band can suppress.

. In a recent such a circuit of Figure 3 are 34 and 36 connected to outputs of L and R, the outputs of an AM receiver 31 and an FM receiver 32 via the analog switch 33; the power supply for the AM receiver 31 or the FM receiver 32 is selected by means of switches SW 1 and SW 2 , which are connected to a flip-flop circuit 37 made of NAND elements G 1 and G 2 . While a capacitor C 1 is charged during the initial application of the mains voltage by a voltage or power supply B ⁺, the output signals from inverters I 1 and I 2 change to "high" or "low" until the charging voltage reaches the operating voltage VTH of inverter I 1 reached; the NAND gate G 1 is fed with a low input signal and the NAND gate G 2 with a high input signal, the output signals of the NAND gates G 1 and G 2 adopting the states "high" and "low", respectively that a Transi stor Q 5 turns on and a transistor Q 6 and a transistor Q 3 for blocking and turns on a transistor Q 4 and thus delivers energy from the power supply B ⁺ to the FM receiver 32 ; consequently, the FM receiver 32 is selected or switched on when the power supply is switched on. At the same time brings the high output signal of the inverter I 1, the output signal of the NAND gate G 2 via a diode D 5 in the "high" state to turn on a transistor Q 2 and to light up a light emitting diode LD 2 , which indicates the operational readiness of the FM Displays receiver 32 ; on the other hand, the output signal of the NAND gate G 1 assumes the "low" state, and the transistor Q 3 blocks, so that the transistor Q 4 switches through and the power supply B ⁺ to the FM receiver 32 is switched on. In addition, transistors Q 9 and Q 10 turn on, and they eliminate pulse voltages and consequently pulse-like interference signals (crackling noises) when the power supply B ⁺ is switched on.

After the charging of the capacitor C 1 after switching on (initial operation), the input signal to the NAND gate G 2 from the inverters I 1 and I 2 goes high, and the input signal of the NAND gate G 2 also goes high, so that the Output signals of these NAND gates G 1 and G 2 are retained. The output signal of the inverter I 1 becomes low and is applied to the base electrodes of the transistors Q 7 and Q 10 via the diode D 5 in order to block these transistors, so that the output signal of the FM switch to be applied via the analog switches 35 and 36 Receiver ( 32 ) for the charging time of the capacitor C 1 is delayed. When the switch SW 1 is switched to switch the FM / AM bands or ranges, the output state of the flip-flop circuit 37 also changes , and the transistor Q 7 switches on at the moment of the change of state, so that the output signal of the inverter I 1 becomes low and the transistors Q 9 , Q 10 which are switched through, the driver voltage at the control terminal of the analog switch falling and thus pulse-like interference signals during band switching are eliminated. If the charging voltage of the capacitor C 1 is reversed when the power supply is switched off to a size below the operating voltage VTH , a low signal is applied to the output of the NAND gates G 1 and G 2 to switch off the analog switch for the removal of impulsive interference signals.

However, the previous circuit has the following shortcomings: (1) Two band switches SW 1 and SW 2 are required for switching between AM and FM bands, which require a correspondingly large installation space. (2) When actuated, the switches SW 1 and SW 2 bring the output signals of the NAND gates G 1 and G 2 to the low state in order to simultaneously switch between AM and FM bands (or to select these bands), while (3) the non-selected (switched on) electrostatic voltage supply continues to consume energy and continues to turn the output terminal of the positive edge detector to an inverter (turns to), so that (4) energy is still supplied from the power supply B ⁺ to the inverter and is unnecessary is consumed. (5) In addition, the AM and FM band indicator disadvantageously requires a separate driver circuit for its operation.

With the aim of avoiding the deficiencies in the state of the Technology, the invention aims to create an AM / FM Band selector that allows you to select or switch AM / FM Tapes is possible with a single switch and Interference signals (noises) when switching the on and off Suppress power supply and band switching who the and also electricity or energy by limiting the Power consumption is saved to a minimum.

This object is characterized by the claim Features resolved.  

The following is a preferred embodiment of the Er Finding compared to the prior art based on the drawing tion explained in more detail. It shows

Fig. 1 is a diagram of an AM / FM band selector according to the invention,

Fig. 2 (A) to 2 (H) are graphical waveform diagrams at respective portions of the circuit of Fig. 1 and

Fig. 3 is a circuit diagram of a conventional AM / FM band selector.

Fig. 3 has been already explained.

At the inFig. 1 shown AM / FM band selector according to the invention, in which the outputs of an AM receiver1  and an FM receiver2nd via analog switchG 1 andG 2nd  at exitsL andR are connected, the current of a power supplyB⁺ via one from a zener diode ZD 1 and a transistorQ 1 existing electrostatic part3rd to transistorsQ 2nd andQ 3rd one from the latter like this like zener diodesZD 2nd,ZD 3rd existing switch part8th to led, the outputs of which via indicators (display elements) 4, 5 in the form of light emitting diodesLD 1 respectively.LD 2nd to electricity supplier supply terminals of AM and FM receivers1 respectively.2nd connected are. The base electrodes of transistorsQ 2nd andQ 3rd  in part (or section or circle)8th are about zener diodesZD 2nd,ZD 3rd with the respective outputsQ respectively.   a flip-flop circuit7 connected whose outputsQ,  each with the control terminals of analog switchesG 3rd,G 4th  andG 1,G 2nd as well as capacitorsC. 3rd andC. 4th with the Base electrodes of transistorsQ 4th respectively.Q 5 in one out TransistorsQ 4th,Q 5, DiodesD 1,D 2nd and capacitorsC. 3rd, C. 4th existing detector (part)6 for the pulse edge posi tive polarity are connected. The output of the detector  part6 is through a capacitor connected to ground5 and an inverterI. 1 to the base electrodes from with the emit the grounded transistors (ground transistors) Q 6,Q 7 connected whose collectors to the outputs Q respectively.  of the flip-flop circuit7 are connected, its clock input to the movable contact partc of the switchSW 1  is connected, the fixed contact parta  is again grounded while the fixed contact b with the input of the flip-flop circuit7 connected is.

In the following, the Ar beitsweise the circuit described is explained with reference to FIGS . 2 (A) to 2 (H).

When power is supplied from the power supplyB⁺ to one given timet 1 according toFig. 2 (A) to 2 (H) becomes current about a resistanceR 1 to the blanking terminal of the flip-flop circle7 and about a resistanceR 2nd to the entrance of the Flip-flop circuit7 fed and (also) to the setting input (preset input) applied while the capacitorC. 1  starts charging slowly (Fig. 2 (C)). According toFig. 2 (A) also becomes energy through a resistorR 10th in the condenser gateC. 5 loaded and to the input of the inverterI. 1 on placed. The flip-flop circuit7 therefore holds accordingFig. 2 (C) a low potential at the set clamp (preset) during currentlyt 1-t 3rd upright when the charging voltage is below the operating voltageVTH lies, so that regardless of Clock signalCK at the entranceT the exitQ of the flip-flop circle ses7 remains at a high potential state during the exit  remains in the low potential state (see Fig. 2 (F) and 2 (G)) so that when applying (applying) the power supplyBGewählt the FM band selected or switched on is tested. Only during the timet 1-t 4thwhen the charging span charge volt on the capacitorC. 5 under the operating tensionVTH of the inverterI. 1 lies, the exit occurs signal according toFig. 2 (B) with a high potential. The Delay time of the flip-flop circuit7 is however in Ver equal to the time constants of resistor and capacitor  too short to weigh (Fig. 2 (C)). The high potential signal is via the diodeD 3rd and resistorsR 11  andR 12 on transistorsQ 6 respectively.Q 7 laid out so this switch through and low potential to the control input jamG 1-G 4th of analog switchesG 1- G 4 deliver to open these switches and turn on the power supply careB⁺ Eliminate output interference signals. In addition, the high potential output signalQ of Flip-flop circle7 to the detector (part)6 for pulse edge positive polarity (pulse positive polarity edge detector) laid out to this for the timet 1-t 2ndduring which the voltage above the operating voltageVTH of the transistors (Fig. 2 (F)) lies on. Hence the low Potential at the collector, d. H. at the output of the transistor Q 5 for a timet 1-t 2nd during which the condensate satorC. 5 after charging on turning on the power supply discharges to then at the timet 2nd how accordingly according to the time constant ofR 10th andC. 7 on load in order to explain pulse-like interference signals Way to eliminate or suppress. The time constant resistanceR 2nd and capacitorC. 1 are shorter on poses as that of resistanceR 10th and capacitorC. 5. The High potential signal from the outputQ of the flip-flop circuit7  (Fig. 2 (E)) is used to lock the transistorQ 2nd to the Zener diodeZD 2nd and about the resistanceR 13 to the tax jamG 3rd,G 4th the analog switchG 3rd respectively.G 4th laid out to to close the latter; the accordingFig. 2 (G) a low Potential output  of the flip-flop circuit7  switches the transistorQ 3rd of the switch part8th through to the constant voltage from the constant current supply part3rd  directly to the output collector of the transistorQ 3rd to transmitted for the purpose of power supply from the power supply B⁺ to the FM indicator5 and to the FM receiver2ndto this for the transmission of the normal FM output signal to the ExitsL andR head for.  

If the entranceCK of the flip-flop circuit7by the counterSW 1 for band switching at a given time Pointt 5 is grounded for the selection of the AM band, to the entranceT is switched, it becomes the same Same effect as applying the clock pulse to the inputCK  produced, the output signal of the flip-flop flips circle7 on the exitQ (comes to have toggle for outputQ)to maintain the low potential and on the exit in order to maintain the high potential (cf. Fig. 2 (E) and 2 (G)). The signal of high potential on exitQ brings the transistorQ 3rd in the switch circuit part8th to lock to switch off the FM receiver from the power supply (source) while at the same time the transistorQ 4th in the named detector6 at the base for a specific timet 5-t 6 at which over the company chip nungVTH of the transistor turns on (see.Fig. 2 (H)). As a result, the output signal gets of the transistorQ 4th a low potential, so short early in the capacitorC. 5 Unload stored cargo will (cf.Fig. 2 (A)) and the capacitorC. 5 from timet 6 can recharge on. In the meantime is the input signal of the inverterI. 1 during the Period of timet 5-t 7 under the operating voltageVTH, so that the output signal conforms to the shapeFig. 2 (B) assumes and pulse-like interference signals when switching channels mentioned way are eliminated; the signal low Potential from the outputQ switches the transistorQ 2nd in the Switch part8th through to energy or electricity from the electricity careB⁺ to the collector, d. H. Output terminal, to be used for power supply to the AM display4th and to the AM receiver1so that the indicator4th lights up and the receiver1 is operated. Furthermore, through the high potential signal from the outputQ of the flip-flop circuit7 Chip of a high potential via the resistanceR 14 to the control terminals of the analog switchesG 1 andG 2nd delivered, whereby the latter ge for receiving normal AM signals be closed.  

When the switch SW 1 is closed and opened at a given time t 8 for the selection of the FM band, the operation is carried out in the same way as described for AM selection or setting. When the power supply is switched on at a given time t 1 , the output signal of the flip-flop circuit 7 becomes the low potential signal according to FIGS. 2 (E) and 2 (G), so that the control terminals g 1 - g 4 of the analog switches G 1 - G 4 are switched off ( turn off) and consequently the switches are opened and pulse-like interference signals are eliminated or suppressed by switching off the power supply B ⁺.

As described above, the Select or set the FM or AM band using a single switch. This also includes the electricity consumption by omitting electricity-consuming construction share lowered. In addition, pulse-like interference signals Band switching as well as when switching the power on and off supply eliminated or suppressed.

Claims (1)

AM / FM band selector, in which the outputs are connected to an AM and an FM receiver via analog switches, characterized in that energy or current from a power supply (B ⁺) via a constant current supply part ( 3 ) from a Zener diode ( ZD 1 ) and a transistor (Q 1 ) to transistors (Q 2 , Q 3 ) of a switch part ( 8 ) from the transistors (Q 2 , Q 3 ) and Zener diodes (ZD 2 , ZD 3 ) is supplied, the output of the switch part ( 8 ) via an indicator (display elements ( 4, 5 ) in the form of light-emitting diodes (LD 1 , LD 2 ) is connected to power supply terminals of the AM receiver ( 1 ) and the FM receiver ( 2 ), the base electrodes of the transistors ( Q 2 , Q 3 ) in the switch part ( 8 ) are connected via the Zener diodes (ZD 2 or ZD 3 ) to the outputs (Q or ) of a flip-flop circuit ( 7 ), which in turn are each connected to control terminals of analog switches (G 2 , G 4 or G 1 , G 2 ) and also via capacitors (C 3 , C 4 ) with the base electrodes of Transistore n (Q 4 , Q 5 ) of a detector ( 6 ) for the pulse edge of positive polarity of transistors (Q 4 , Q 5 ), diodes (D 1 , D 2 ) and capacitors (C 3 , C 4 ) are connected, the Output of the detector ( 6 ) via a grounded capacitor (C 5 ) and an inverter (I 1 ) to the base electrodes of transistors (Q 6 , Q 7 ) with grounded emitters (emitter ground transistors) are connected, the collectors of transistors (Q 6 , Q 9 ) with the outputs (Q,) of the flip-flop circuit ( 7 ) are connected to the whose clock input is connected to the movable contact part (c) of a switch (SW 1 ), the fixed contacts (a and b) are in turn connected to ground or the input (T) of the flip-flop circuit ( 7 ).