DE2743855A1 - Tone control for hearing aid - includes two transistors and potentiometer for controlling frequency determining resistors and voltage stabilisation - Google Patents

Abstract

The tone control for a hearing aid allows the amplifier frequency response to be matched t characteristics of an individual's ear. A frequency response determining network is included in the input of one amplifier stage. Voltage stabilisation is provided for the transistor circuit which controls the frequency determining variable resistors. The control circuit includes two transistors (23, 24). The base of the first transistor (23) is connected over a resistor (32) to the upper of a potentiometer, one fixed contact of the potentiometer and to the voltage stabiliser. The base of the other transistor (24) is connected over a resistor (38) to a voltage divider (34, 35) connected between the other end of the potentiometer and the emitter of the second transistor (24).

Description

Hearing aid

The invention relates to hearing aids according to DT-PT 26 58 301, in which between the microphone and the listener there is a transistor amplifier with a stage contains a frequency-determining network. Such circuits are used to to be able to adapt the effectiveness of hearing aids to the type of hearing loss (cf. e.g. Journ. Acoustics. Social Am., Vol. 11 (1940) pages 406 to 419).

Accordingly, many attempts have been made to find the Adjust the frequency response that was found as residual sensitivity in the case of a hearing impaired person will. For this purpose, microphones have been used in the hearing aid, the increasing frequency response have and also has the coupling capacitors between the individual stages so reduced that a high frequency characteristic is created. Besides, you still have Sound baffles are used by increasing the input resistance of an amplifier stage in the hearing aid is reduced in size in cooperation with the aforementioned coupling capacitor. These Measures left something to be desired, because the effectiveness of such sound screens it did not allow to optimally compensate for most of the treble losses. The sound screen Rather, it should be effective in a single stage at 12 dB / octave.

From DT-OS 23 16 939, for example, there is an electrical hearing aid circuit known, in which the transmitted frequency range is divided into separately controllable sub-ranges is divided. Through this aims to improve adaptation to the Frequency dependence of reduced hearing can be achieved. For such arrangements however, it is necessary to be able to vary the filter edge within wider limits as before. This undoubtedly requires a great deal of effort, which is a particular disadvantage is if you want to set up the small hearing aids to be worn on the head, which ones only little installation space is available. It is also disadvantageous that because of Battery voltage fluctuations costly stabilization for the continuous Variability of the filter edge become necessary.

The invention is based on the object of a hearing aid according to to specify a frequency-determining network in the preamble of claim 1, which is a more effective sound screen in terms of optimal adaptation. According to the invention, this object is achieved by what is stated in the characterizing part of this claim specified measures resolved.

The effective sound screen is obtained in the aforementioned sense by the use of a network at the input of an amplifier stage of the hearing aid amplifier lies. In the signal input line to the base of transistor T1 (21) of this stage there is a first capacitor C1 (8) and a second capacitor C2 (9). In brackets are for better clarity for the abbreviations in each case the corresponding Reference numbers from Fig. 2 indicated. A third branch branches off between C1 and C2 Capacitor C3 (13) connects to the collector electrode of transistor T1 this stage, at which the output and a connection to one pole of the power source lie. The collector of the transistor T1 is also connected via a resistor R2 (14) connected to the base electrode of T1 and the connection point between the first and second capacitor with resistor R1 (19) as well as the emitter electrode to the second pole of the power source. Others to be described below Variants result in hearing aids with two- and multi-channel characteristics in which the Frequency by which the channels are separated can be shifted by one octave can. This can be done, for example, by changing the resistances R1 and R2 at the same time, e.g. by an additional variable resistor R7 (25). In addition, the Gain in the blocking range of the filter, i.e. at frequencies less than regulate the cutoff frequency of the filter via another control so that at the same time a slight loss of bass can be compensated for by the patient.

I) the transistor amplifier necessary for the construction of the active filter can also be modified, e.g. by adding an emitter resistor or executes the amplifier in multiple stages and the operating point by modifying R2 readjusts, which then also leads to a resizing of C1, C2, C3 and R1 for Consequence.

In the case of the transistor T1 and the resistors R1 and R2 A multiple coupling is achieved through the capacitor C3 in the amplifier stage. These results in cooperation with the first two capacitors C1 and C2 and with the resistor R1 is an active second-order filter. As such is known denotes a filter that, unlike a first-order filter, is a Has a slope of 12 dB / octave instead of 6 dB / octave. The one between collector and the base of the transistor T1 lying resistor is expediently dimensioned in such a way that then on the one hand in cooperation with that in the connection of the collector with the battery lying resistor R3 sets an operating point with which the Stage is optimally controllable so that the limitation starts symmetrically. One any other design is usually always undesirable because it is asymmetrical Limitation of the intelligibility of the hearing aid decreases more than with symmetrical Limitation. On the other hand, together with the capacitors C1, C2 and C3 and the resistor R1 connecting its connection point to ground the desired Set the limit frequency. This results from the general transfer function of the filter. Accordingly, can an increase through simultaneous Downsizing of R1 and R2 can be achieved and a reduction by simultaneous Enlargement of R1 and R2. The circuit is expediently dimensioned in such a way that that all capacitors have the same capacity, because then the dimensioning rules become particularly easy, as can also be seen from the following arithmetic treatment.

The operation of the circuit according to the invention with capacitors of the same capacitance C1 = C2 = C3 = C has a transfer function LI (s), ie a function that determines the Laplace transform of the output signal Ua (s) as a function of the Laplace transform of the input signal Ue (s). If one then sets s = j #, then H (j #) gives information about the transmission properties of the circuit in the frequency range. The transfer function of the circuit described here is approximated by the following equation: = j #; j = ; # = Angular frequency; C = capacity of the capacitors used.

The dimensioning rules result from this relationship: where a1 and a2 are the characteristic filter coefficients; is the cli.c 3 dB cutoff frequency, ie the frequency at which the frequency response is 3 dB below the gain value in the pass band.

R1 and fl2 are to be addressed as <Ile mentioned above.

In the case of the filter according to the invention, a change in the frequency can be achieved without entering the transfer function H (s) third pole which, instead of steepening the filter flange, must be introduced at low frequencies would destroy the steepness of the filter. For this it is necessary to have the parts to influence the circuit, which determine the cutoff frequency.

Such parts are R1 and R2. So it's enough in itself, both of them to change frequency-determining resistors R1 and R2.

This is expediently done synchronously via a double potentiometer, because so that the desired change in frequency response would be the easiest possible. This is not possible in a hearing aid because such double potentiometers are required mechanical dimensions are not available. The change in resistances R1 and R2 can be done electronically according to a further embodiment of the invention by the variable resistances formed by the transistors T2 (23) and T3 (24) that are synchronized via a, for example, by further transistors T4 (45) and T5 ( 46) can be controlled.

The cut-off frequency can be shifted continuously, since the transistors T2 and T3 work in the linear range. This is the case with hearing aids optimal adjustment options.

The stabilization also ensures that the circuit goes down remains functional at 1.1 volts.

In the circuit according to the invention, the attenuation can also be in the stop range of the filter can be changed. For this purpose, a bridging of the inventive Fil terschaltung be provided which contains a potentiometer R11 (63). When adjusting this potentiometer bridges the entire filter circuit. This is by introducing a third pole in the transfer function the attenuation in the blocking range of the filter changes. This is important for hearing aids because slight bass losses of the patient can be compensated for. at this is not so easy to do with other circuits because of the high frequency characteristics at several stages of the amplifier or at the same time the amplification increased in the pass band. In this respect too, the invention thus offers one great advantage over the other circuits scanned from the prior art.

A multi-channel amplifier can also be used with the filter circuit according to the invention can be realized with changeable channel separation by on the one hand the filter flank shift, on the other hand can influence the gain in the damping area. This has ven advantage for hearing aids that with a device due to the very effective Adapters can be used to compensate for practically all treble losses. this will achieved in that to R1 and R2 via the transistors T2 and T3 each a further Resistance is connected in parallel, so that the frequency-determining parts are switchable to be influenced.

In one circuit variant, the transition is from a cutoff frequency switchable to the other. So it is with regard to the components of the circuit causes that by adding resistors to the frequency-determining parts R1 and R2 the channel separation can be done with the same slope as in the previous variant, but switchable with fewer components. On the same Way you can either use as many such resistors as you want at the same time or switch it on individually so that the shift of the filter edge is quantized can make. This variant can also be designed for several channels. In addition only need several such stages to be connected in cascade, whereby it is has proven to be useful to adjust the cutoff frequency.

Further details and advantages of the invention are provided below explained on the basis of the exemplary embodiments shown in the figures.

In Fig. 1 is the block diagram of one with the invention Sound screen equipped hearing aid drawn, in Fig. 2 with the enlarged Variations drawn out, sound screen used in Fig. 1, in Fig. 2a a modified control voltage generation for the edge shift of the active Filters, 3 to 5 graphs of the effectiveness of the in Fig. 2 and 2a drawn variations and in Fig. 6 one with respect to switchable Adjustability trained variant.

In Fig. 1, 1 denotes a microphone, which the sound input in a hearing aid and which sends its signals to a preamplifier 2, followed by a sound filter 3, behind which there is a volume control 4, which is followed by a power amplifier 5, from which the signals reach a listener. In a known application in a hearing aid constructed in this way, those on the microphone 1 incoming sound events are converted into electrical signals, which are then sent to the Amplifier arrangement 2 to 5 modified in a manner suitable for the hearing impaired and fed through the listener to the hearing of the hearing impaired in order to enable him to hear or to enable improved hearing.

A sound screen 3 designed according to the invention is shown in FIG the framed area 3 'drawn. There are in a line 7, the comes from preamplifier 2 according to the indication through a connection point 2 ', two capacitors 8 and 9. The line 7 then leads on to the base 10 of one Transistor 11. At the connection point 12 between the two capacitors 8 and 9 there is a further capacitor 13, which is connected to the collector via a further line 14 15 of the transistor 11 is located. There is also a resistor 16 on the collector in the line to the positive pole of the battery and a line 17 to a connection point 4 ', which leads to the volume control 4 (Fig. 1). This line also contains a capacitor 18, so once a DC voltage decoupling to the volume control takes place and at the same time in cooperation with the potentiometer 63 a correct Phase relationship between input and output signal comes about.

The point 12 is connected to a line 20 via a resistor 19, which comes from the negative pole of the battery. At this Line 20 Nucii is the emitter 21 of the transistor 11. The circuit also contains a resistor 22 between lines 1 and 1 4.

Regarding the operation of the circuit, it should be noted that the sound screen in principle from one comprising the transistor 11 and the resistors 16 and 22 Amplifier stage exists. The capacitor 13 creates multiple negative feedback, in cooperation with the remaining capacitors 8 and 9 and the resistor 19 forms an alc-ti ves filter of the second order The resistor 22 is dimensioned in such a way that that in cooperation with the resistor 16 reached optimal level control will. The capacities of the capacitors 8, 9 and 13 as well as the value of the resistor 19 are selected for a cutoff frequency of 1000 Ii by the relationships of Page 4 (calculation formulas) have been taken into account. Here are the capacities of the capacitors 8, 9 and 13 are the same, in order to comply with simple dimensioning rules such as on Page m4. The actual mode of operation of the sound filter 3 results in such a way that when a sound event arrives at the microphone 1, an electrical Signal results, which is composed of a frequency mixture of speech signals. This is then electrically amplified in the preamplifier 2 and via the line 7 dem Sound filter 3 supplied. I) he capacitor 18 is already in the transfer function of the filter and serves at the same time for DC voltage decoupling to preamplifier stage 2.

A signal then appears at the starting point 4 'of the filter, which the frequencies below the cut-off frequency of the filter from the speech frequency mixture depending on the setting of the potentiometer 63 suppressed. This can then be done using of the volume control, i.e. a variable resistor, brought to a higher level after going through the power amplifier 5 in the handset 6 the hearing impaired desired volume.

By adding the sound filter circuit contained in area 3 ' by means of transistors 23 and 24 by means of a variable resistor 25, the effectiveness is determined of the one contained in 3 ' Sound filter changeable. Here is the emitter 26 of the transistor 23 is connected via a line 27 to the line 14 and the Collector 28 via a line 29 containing a capacitor 30 with the line 7. The base 31 of the transistor 23 is connected to the tap 33 via a resistor 32 of the variable resistance 25, one end of which is connected to a resistor 34, which is connected via a resistor 35 to a line 36 leading to the negative Lead pole of the battery. The tap 33 is connected to the other end of 32 directly. The connection point 37 of the two resistors 34 and 35 is via a resistor 38 connected to the base 39 of the transistor 24, its emitter I0 on the line 36, i.e. the negative pole of the battery, urld its collector 41 1 via a capacitor 42 is at the connection of the resistor 19 to the point 12. The second ending and the tap of the variable resistor 25 are applied via a resistor 43 the base of a transistor 45, which together with a further transistor 46 the Stabilization of the operating voltage causes. For this purpose are the collector 47 of the transistor 45 through a resistor 48 with a line 49 connected to the positive terminal of a battery is, and the emitter 50 of the transistor 45 to the collector 51 of the transistor 46 and the emitter 52 of this transistor with the line 36 to the negative pole connected to the battery. In each case the collector 47 and the base 44 as well as the collector 51 and the base 53 are short-circuited via lines 54 and 55. The collector 47 is also connected via a capacitor 56 with the line 36, that is to say the Ilinus pole the battery.

Based on the above-described mode of action of the 3 ' contained basic circuit results in a shift of the frequency-determining Resistors 19 and 22 by means of transistors 23 and 24 by removing from the arriving at 2 ' Signal more or less low frequencies are filtered out. The cutoff frequency is variable with the variable resistor 25, because one through the transistors 45 and 46 stabilized voltage via the change in the operating point of the transistor 23 and 24 - whose internal resistance varies.

In FIG. 3, in a diagram on f the ordinate, the amplitude is the output voltage plotted against the abscissa on which the frequency is plotted. Both axes have logarit} imisc} ie scales. The input voltage is constant in amplitude Shifting the tap 33 can thus shift the gain increase from the line 60 to 61, i.e. the gain is higher Frequencies shifted. Since a continuous displacement of the tap 53 is possible is -t is also a continuous shift in the gain increase e.g. 60 to 61 possible.

While the components shown below 3 'create a The limit frequency can be influenced by bridging 62 of the Input point 2 'with the starting point 4' via a potentiometer 63 a change the attenuation in the stop band of the filter, i.e. setting the gain in Restricted area. To do this, the adjuster is set so that for an increase the damping the resistance value of the controller increases, for a decrease the damping the resistance value is reduced. The controller should be at the high resistance Interrupt the end, i.e. the bridging should be able to be made ineffective in order to to be able to eliminate the third pole entirely.

The mode of operation of the potentiometer 63 can also be seen from the graph can be seen in FIG. 4. As in FIG. 3, the abscissa 65 is the frequency and plotted on the ordinate 66, the amplitude of the output voltage. At one position of the tap 64, in which there is practically no passage through the bridge 62 remains open, the gain slope 67 extends from the abscissa 65 to the through the line 68 indicated maximum value. But it is done by reducing the resistance If a passage is created through the bridge 62, the rise 6'7 is shortened according to the Q output voltages indicated by the limit lines 69 to 72, , i.e. the increase in gain 67 is achieved by widening the passage through the Bridging 62 decreased. In the event of a short circuit, i.e.

at zero resistance, the gain of the passband, which by the same position of the boundary line 72 and the uppermost reinforcement option 68 is indicated. There is then no longer any increase in gain 67 between these.

When the influencing of the limit frequency indicated in FIG. 3 interacts with the change in the attenuation of the stop band of the filter explained in FIG becomes the variability of the operation of the sound filter shown in FIG. 5 achieved. Here, too, is the frequency in the abscissa 73 and the frequency in the ordinate 74 Output voltage plotted at point 4 '.

A change in the variable resistor 25 results in a shift the gain increase 75 shown in dashed lines to the solid increase, 76 or the opposite is possible. On the other hand, will correspond to the indicated -q Boundary lines 77 to 79 a change due to a shift on the potentiometer 63 the start of reinforcement is possible according to the boundary line 77 to 79. So a wide variation of the setting options is obtained, so that depending on the position the potentiometers 25 and 63 between an external broadband character and a narrow-band high-frequency character, all variants of the frequency response can be set can.

In Fig. 6 a variation is shown in which two fixed set limit frequencies are pre-set, which by means of a switch 80 into one another can be transferred. The actual basic circuit agrees with that which is contained in 3 'and consists of three capacitors 81 to 83, which are connected to each other at point 84. The capacitor is on the outside 81 at the input point 85 of the sound diaphragm, the capacitor 82 at the collector 86 of the transistor 87 and the capacitor 83 at the base 88 of the transistor 87. The associated Emitter 89 is connected to line 90 to the negative pole of a battery while the collector 86 via a resistor 91 with a line 92 to the pulse pole of the battery connected is. The collector 86 is also over with the base a Resistor 93 connected. In addition, a resistor 94 leads from point 84 a line 95 to line 90, which is connected to the negative pole of the battery stands. Corresponding to the part contained below in the area 3t in FIG. 2, i.e.

the transistors 23 and 24 are transistors according to the present circuit 96 and 97 are provided, bridging the resistor 93 and the resistor 94, respectively. For this purpose, they each have a capacitor in a line 98 or 99, one after the other 100 or 101 and a resistor 102 or 103, which lead to the emitter 104 and collector 105 lead. There is then a direct connection from the collector 106 of the transistor 96 107 to the base 88 of the transistor 87 present, while the emitter 108 has a Line 109 is connected to the line 90 leading to the negative pole of the battery is. Both transistors 86 and 87 are then each connected via a resistor 110 or 111 is connected to switch 80, which is in line 112 to line 92 to the positive Pole of the battery.

In contrast to the arrangement in FIG. 2, the transistors here T 105 and 95 are used as switches that put resistors 103 in parallel with 94 and 102 lay parallel to 93. The capacitors 98 and 99 are used for DC voltage decoupling. When the switch 80 is closed, a current is impressed by the resistors 110 and 111 reached into the base of transistors 105 and 95.

By wah. the dimensioning of the resistors 102 and 103 is the second corner frequency, i.e. the edge 61 in Fig. 3, is set. Man karin e.g. for the diagram in Fig. 3, the corner frequency for the edge 60 to 1000 IIz and that set for edge 61 to 2000 Hz, because when evaluating statistics over Audiograms show a particularly strong accumulation in this area.

In the modification of the aul shown in FIG. 2a from FIG The part following the transistor 23 is the resistor 32 directly to the resistor 34 connected and also with the tap 33 'of the variable resistor 25' , one end of which leads directly to the base 44 of the transistor 45, while the other The end is pre-connected to the line 36 via a resistor 43 '. The connection point between the two resistors 34, 35 remains as in the original version connected to the base 39 of the transistor 24 via a resistor 38.

The effectiveness of the present circuit, as shown in FIG. 3 until 5 is expressed remains unchanged because the new arrangement of the potentiometer 25 'only improves the DC voltage control of transistor 23 and 24 and the leaves the rest of the effect unaffected.

The improvement brought about by the relocation of the changeable resistance 25 and the subsequent resistance 43 is achieved, is based on the fact that the At the end, tap 33 always has that potential which, by means of the transistors 45 and 46 formed tension sterilization is set. This makes it possible to be used for the potentiometer 25 'actuator with larger wicierstand tolerances than in the arrangement of FIG. 2; on the other hand, the frequency curve 61 (Fig. 3) or

76 (Fig. 5) closer tolerances than with the circuit of the potentiometer 25 (Fig. 2) L e r s e i t e

Claims (2)

Claims 1. Hearing aid, in which between the microphone and the listener A transistor amplifier is connected to a stage that forms a frequency-determining network contains and where according to patent ... (P 26 58 301.7-31) the network is in the input of an amplifier stage and one after the other in the connection of the input to the base of the transistor contains a first and a second capacitor, between which has a further Capacitor connects to the collector of the transistor, which is also still via a resistor to the positive pole of the operating current battery and a connection is connected to the starting point of the stage that the connection of the first and the second capacitor also has a resistor as well as the emitter of the transistor are connected to the negative pole of the battery that the collector also connected to the base of the transistor via a further resistor is and in which the frequency-determining resistors are designed to be changeable by to change a continuous transistor control is provided, for voltage stabilization is provided for the operation of the transistor control, d u r c h e k e n n n z e i c h n e t that the transistor control consists of two transistors (23, 24), the base of the first transistor (24) via a resistor (32) with the wiper (33) of a potentiometer (25) and its one fixed connection and the voltage stabilization is connected and that the base of the other transistor (24) via a resistor (38) to the connection point of the two resistors (34, 35) of a voltage divider, one resistor (34) with the second fixed Connection of the potentiometer (25) and its other resistor (35) to the emitter line (36) of the second transistor (24) leads. 2. Hearing aid according to claim 1, characterized in that the from two transistors (23, 24) existing control the base (31) of the first transistor (23) via a resistor (32) on Wiper (33 ') of a potentiometer (25 ') and the base (39) of the second transistor (24) via a resistor (38) and via the connection point of the two resistors (34, 35) of a voltage divider on the one hand (35) on the emitter line (36) of the second transistor (24) and on the other hand (34) is on a fixed connection of the potentiometer (25 '), the other more fixed Connection is directly connected to the voltage stabilization.