DE1537743C3 - Circuit arrangement for a paging receiver for evaluating a selective call signal consisting of a sequence of audio frequency pulses - Google Patents

Description

a resonant circuit arrangement with inductors and capacitances arranged in plug-in elements is known, in which an oscillating circuit is formed from each inductance together with one of the optionally connectable capacitances and in which the loss angle of the capacitances on the plug-in elements is determined by resistors also attached to the plug-in elements a measure dependent on the size of the capacitance is set in such a way that the quality of the resonant circuit is independent of the frequency determined by the connected plug-in element. The cathode resistor (Rl) provided there is chosen so that it does not impair this condition.

From IT-PS 6 73 251, which corresponds to the not previously published DT-AS 12 75 165, it is known to use automatically switchable L / C oscillating circuits as selection means by means of a relay chain, their coils for different connection of the capacitor with several taps like this are provided that the resonance resistance is kept approximately constant in all switching positions.

The invention is based on the object of providing a circuit arrangement of the type in question create the same (frequency-related) bandwidth of the at all pass frequencies Passage curve of the band pass, same input impedance and a constant ratio of Having input and output voltage of the bandpass filter.

This task is based on a circuit arrangement according to the preamble of claim, according to the invention by those specified in the characterizing part of the claim Measures resolved.

The invention will now be explained using an exemplary embodiment. The figure shows the circuit diagram a paging receiver having a circuit arrangement according to the invention, with those Parts that are not essential for understanding are designed as a block diagram, while the for Explanation of the invention necessary circuit parts are shown with all details.

A call signal emitted by a central transmitter in the form of a high-frequency signal modulated with a sequence of audio frequency pulses reaches the high-frequency part HF via the antenna, is mixed and amplified there and demodulated and amplified in the low-frequency part NF. From the output of the low frequency part, the audio frequency pulses reach the base of the transistor TRl. The signal has been limited to a constant value in the low-frequency section in a manner not shown so that switching operations cannot be erroneously triggered by a strong low-frequency signal with a frequency adjacent to the respective pass frequency of the band-pass filter - due to the limited selectivity of the bandpass filter. The audio frequency signal is amplified in the transistor TRl, which is connected in the collector circuit. The emitter resistor consists of a voltage divider which is formed by the resistors Rl and R. 8 The resistor R 8 has an extremely low resistance to the resonance resistance of the input resonant circuit of the bandpass filter, while Rl has about a thousand times the value of RS . The current in the resistor R 8 originating from the transistor TR1 (and thus also the voltage generated by this current) depends solely on the size of the input signal fed to the transistor TR1. The resistor R 8 thus represents a very low-resistance voltage source with an EMF that is only dependent on the size of the input signal, but not on its frequency. This voltage source is inserted into the input resonant circuit of the bandpass filter, which consists of two capacitively coupled circuits, an input resonant circuit and an output resonant circuit , consists. The pass frequency of this band pass can be changed in steps in the manner explained below. The inductances of the two circles are labeled Ll and Ll , the capacities with Cl and Cl and the coupling capacitance with C 3. When the receiver is idle, the current in the input resonant circuit runs from ground via the resistor RS, the capacitor Cl, most of the coil L1, the resistor R 11,

so the collector and emitter of the switching transistor TRU and the capacitor C5 back to ground. The current in the output resonant circuit runs from ground via the capacitors C4 and CI, most of the coil Ll, the resistor .R21, the collector and emitter of the switching transistor TR 21 and the capacitor C 5 back to ground. The capacitors C 4 and C 5 are very large compared to each of the other capacitors, so that their influence on the oscillation behavior of the circuits is negligible. The resistors RS, RIl and RH are very small, so that their contribution to the attenuation of the circles is also small. Their meaning will be discussed later. The coils Ll and L 2 each have ten taps that each have ten soldering points of a patch panel RFl and RFlenden.

Each coil has three switching transistors TR 11 ... TR 13 or TR 21 ... TR 23, the collectors of which are connected to three soldering points of the relevant patch panel. The emitters of all switching transistors lead to the middle of a voltage divider, one branch of which consists of the parallel connection of the resistor R 9 with the capacitor C 5 and the other branch of which consists of the resistor R 10. The resistor R 10 is connected to the negative pole of the supply voltage source B - the positive pole of which is connected to ground - so that the emitters of all switching transistors are at a negative potential. The bases of the two switching transistors TRU and TR 21 are connected to output 1 of an evaluator A via resistors (not designated), the bases of transistors TR 12 and TR 22 to output 2 and the bases of transistors TR 13 and TR 23 to output 3 of the evaluator. Since the emitters of all switching transistors are at a negative potential, those switching transistors whose base is connected to ground potential become conductive, while those switching transistors whose base is connected to negative supply potential are blocked. Provided that it is ensured that one of the three switching transistors that are assigned to a coil and the associated patch panel is conductive and the other two are blocked, one tap of the coils is connected to ground, i.e. connected to the remaining parts of the resonant circuit, while the other two taps are separated from it. In which

Call receivers shown in the figure are, for example, the taps 2 via the resistor R 11 or R 21, the collector-emitter path of the switching transistor TA 11 or TR 21 and the capacitor C 5 to ground and thus via the resistor. R8 and the capacitor C4 are connected to the resonant circuit capacitors Cl and C 2, respectively. As already mentioned, the capacitances C 4 and CS are irrelevant with regard to frequency influencing, since they are very large. ■

If one of the three switching transistors is put into the conductive state and the other two into the blocked state, the associated resonant circuit is closed, its frequency on the one hand by the constant capacitance Cl or Cl and on the other hand by the selected part connected to the conductive switching transistor the coil Ll or Ll is determined. With the help of the jumper panels RFl and RFl it is possible to connect the switching transistors to any taps, so that the bandpass filter can be tuned to any three of ten possible frequencies by means of purely electronic switching means by making the appropriate routing in each of the two jumper panels.

For the stage following the bandpass filter to work properly, the signals passing through the bandpass filter must be supplied to this stage with a voltage which is exclusively proportional to the signal voltage applied to the bandpass filter and is independent of the frequency. Under this prerequisite, this voltage is then constant if the signal reception strength is sufficient due to the effect of the limiting circuits. This requirement is met in the present bandpass filter in that it is ensured that the circles have the same quality factor Q for all adjustments and in that the coupling takes place with a capacitive voltage divider. Assuming a constant quality factor, the result for a resonant circuit with a "voltage source" in the course of this circuit, the internal resistance of which is small compared to the loss resistance (resonance resistance) of the circuit, results in the resonance voltage being ß-times the emf of this source. Since - as described earlier - the resistor 7? 8 is extremely low-resistance compared to the resonant circuit resistors, this requirement is met here. Since it can be assumed that the relationships mentioned are generally known, they are not derived here.

According to other relationships that can be derived from the oscillation equations, to achieve the required independence of the circular quality of the tuning frequency, with one Resonant circuit in which the capacitance is constant and the inductance depends on the tuning frequency depends, the loss resistance will be proportional to the square root of the inductance. In a coil with Taps, the root of the inductance is proportional to the number of turns. Provided all turns would have the same length, the same wire is used and the external load is neglected would be for a resonant circuit with a constant capacity and a such a coil the quality factor is always the same. In practice, this condition cannot be met. A way out is possible, however, by inserting a resistor in each circle whose value for the part of the coil with the mean turn length selected by the tap and through which the current flows - and if necessary the influence of the external load - is adapted. To this Way can be achieved that the ratio of the ohmic resistance of a circuit and the number of turns despite different coil diameters - and possibly changing influence of the

ίο external stress - remains practically the same for all votes. These individual resistances ( denoted by Jill, RU, /? 13 or Jl21, R12, R 23 in the figure), the value of which is permanently assigned to a specific tap, are located in the jumper field between those taps that are connected to the switching transistors and inserted into the collectors of these transistors.

From the bandpass filter described, the output signal is taken from the capacitive voltage divider consisting of the two capacitors C 2 and C 4, which divider forms the capacitive branch of the output resonant circuit. As mentioned earlier, the capacitance C 4 is much larger than the capacitance C 2, so that essentially C2 is the frequency-determining factor for the resonant circuit. So that the same coils and capacitors can be used in both circuits, it is possible to build up the capacitance C 2 from two capacitors connected in parallel, one of which corresponds to the capacitor C1 and the other compensates for the capacitance-reducing influence of C 4 in the resonant circuit. The capacitive voltage division in the output circuit results in a frequency-independent voltage division. Since, according to the earlier statements, the resonance voltage at the resonant circuits depends only on the EMF occurring in the resistor R 8, but not on the frequency, the ratio between EMF and output voltage is therefore approximately constant at the respective pass frequency of the bandpass, so that the. The output voltage depends only on the input voltage supplied to the transistor TR 1.

The output signal of the band pass goes to the pulse shaper IF, where the respective audio frequency pulse is converted into a direct current pulse of a defined height and edge steepness. These direct current pulses are fed to an evaluator A , which has four outputs 1 ... 4. One of the outputs 1 ... 3 always carries ground potential, while the other two have the (negative) supply potential. The output 4 initially carries a potential which blocks the oscillator stage O .. When the receiver is idle, the ground potential is at output 1, so that - as previously assumed - the two switching transistors TJlIl and TRIl are unblocked, while the other switching transistors are blocked and thus the bandpass filter is tuned to frequency "2" (tap 2). When a (first) pulse has passed from the pulse shaper IF to the evaluator A , the evaluator applies the ground potential to the output 2. The transistors TR 12 and TR 22 become conductive and the bandpass is tuned to frequency "6". If a pulse with this frequency is received, the (second) pulse thus fed to the evaluator causes the ground potential to be applied. the output 3, which results in the tuning of the bandpass to the frequency "7"

has. A third tone impulse of the appropriate frequency causes the application of an unlocking potential to output 4 of evaluator A, whereby the oscillator O is put into operation and a warning signal sounds from the loudspeaker,

The evaluator, which is made up of well-known logic switching elements and therefore is not described in more detail, is set up so that after a certain time after the last Receipt of an impulse returns to the rest position, regardless of whether the switching processes have progressed or not until the oscillator is triggered. It thus follows that the oscillator only issues an alert when three specific frequencies correspond to the Call receivers are assigned individually, within a certain time and in a certain order be received. To be even more secure

In order to avoid false calls, it is possible to add a counting level to the warning sign only to be triggered when a certain tone pulse sequence has been received several times.

In the example, in order not to complicate the drawing too much, the number of in each tone pulse train contained frequencies with three and one bandpass, tunable to ten different frequencies, accepted. Of course you are not in any

ίο way tied to these values. Both numbers can can still be increased significantly and then result in an extraordinarily large number of individual Call options.

The present circuit arrangement allows

every call receiver, without replacement, more frequency-determining Share on any call signal within the scope of the paging system in question to adjust. The only really individual parts are resistors.

1 sheet of drawings

609 639/361

Claims (1)

1 ■ ..,. .2 lies than this with regard to the given fre- Claim: frequency spacing is permissible. Unless the switchover takes place by means of mechanical contacts, come to Circuit arrangement for a paging receiver, the scattering of the inductances also Streuzum Evaluation of one of a sequence of tones of capacities. frequency pulses existing selective call It has now been shown that when using signals that contain one of two oscillating circuits (one of pot cores or of - a special kind of gear oscillating circuit, output oscillating circuit) formed by pot cores representing - cross cores for the bandpass filter, which in the idle state the coils and transistors for switching to the first frequency of the Receiver assignments is possible, in the latter case it is tuned for the split audio frequency sequence and with ratios between the inductances the part _: ^ Reception of this frequency as the first frequency coils and the inductance of the whole in question, a call signal on the second frequency of the coil Extraordinarily tight tolerances to achieve the audio frequency sequence allocated to the receiver are switched over and the stray capacitances mentioned are switched to very small ones, and so on, at which the further values are brought. teren each of the two resonant circuits from a case of the circuit arrangement mentioned above With a constant capacitance and an inductance, each oscillating circuit accordingly has a coil with tapping with taps, a constant capacitance and a constant capacitance, as well as for the mentioned frequency reversal 20 such as switching transistors The emitter-collector circuit of which is arranged a number of capacitance corresponding to the number of capacitance that corresponds to the number of capacitance that is connected to the receiver between a coil tap and the divided audio frequencies. The switching transistors vervon having switching transistors, the emitters of which each bind one of the taps to the collector path between the constant named capacitance, while the other tap capacitance and one tap of the coil are separated from it. As a result, any are arranged - by means of a switching transistor because a resonant circuit can be connected through a constant so the respective coil tap with capacitance and * a selected part of the associated capacitance, so that the coil is formed. Similar measures are also provided for a resonant circuit, each by a constant capacitance and the inductance of a part 30 15 16 737, which is also formed for the Freeiner coil - and by quenzumschalt one of the number the number of lector paths of the switching transistors inserted between the taps and the emitter-col allocated ringing frequencies corresponding to the number of switching transistors inserted into the receiver is provided.
Resistances which, due to the different Liche turn length of the connected coil 35 arrangement of the type in question under strict divide conditional differences in resistance, it is necessary that both the (on it is ensured that the resonant circuits have the frequency-related bandwidth of the passageways Tuning frequencies the same circular quality curve of the band pass as well as its input (quality factor) have, characterized by the characteristic impedance and the ratio of input and characterizes that the call signal is sent to one of the 40 output voltage of the bandpass filter in the pass-through train the input resonant circuit of the band pass was independent of the respective call frequency intended to resist the resonance. This oscillating circuit was extremely low ohmic. The mentioned condition for the transmission curve gene resistance (2? 8) is applied and that the is independent of the frequency Capacity of the output resonant circuit of the band- 45 circular quality fulfilled. Such a constant circular passport as a capacitive voltage divider (C 2, C 4) good would result from the above described is whose one capacitance (C 4) settles by itself if the winding length is at compared to its other capacitance (C 2) is large, all partial windings of the coil would be the same. It and over its large capacity (C 4) the output can be ensured that through in the compulsory signal is removed. 5 ° see taps and constant capacity running connections inserted, the alternating Different winding lengths of the various coil parts compensating resistances a corresponding correction and thus one for all pass frequencies The invention relates to a circuit quality of constant circular quality of said oscillating arrangement according to the generic term of the patent circle. demanding. A practically constant ratio of A two-circuit band-pass filter can be switched between the input and output voltage of the band-pass filter by having a constant conduction state and a constant single inductance alternating with different 6 ° input impedance for each resonant circuit, however, provided that - as in the present case - capacities or a constant capacitance are lost - At the input and at the output only one partial voltage of the resonant circuit voltage is alternately connected to different taps or connected to a coil. The last-mentioned type is led away, not easily achieved, is a switchable bandpass, provided that the number Because for this purpose it is necessary that the different frequencies are high, when using the ratio between the voltage of the input or output ordinary coils not easily borrowed possible signal and the resonant circuit voltage, since the ratio of the inductances remains the same
The Swiss patent 34 05 32 shows that different sub-coils have a larger spread