DE102012215976A1 - Hearing instrument e.g. in-the-ear (ITE) hearing aid has comparator circuit which is connected to thermo-resistive resistors for altering temperature difference between resistors, so that output signal of comparator circuit is altered - Google Patents

Abstract

The hearing instrument (1) has a control element (7) which is arranged in outer wall (6) of housing (2) and is connected to a signal processing device (9) for delivering control signal. Control element has thermo-resistive resistors which are arranged on outer wall of housing. An electrical comparator circuit connected to thermo-resistive resistors for altering the temperature difference between two thermoresistive resistors, so that output signal of comparator circuit is altered and is depended on control signal of the control element.

Description

The invention relates to a hearing instrument with temperature-sensitive control element.

Hearing instruments can be designed for example as hearing aids. A hearing aid is used to supply a hearing-impaired person with acoustic ambient signals that are processed and amplified for compensation or therapy of the respective hearing impairment. It consists in principle of one or more input transducers, of a signal processing device, of an amplification device, and of an output transducer. The input transducer is typically a sound receiver, e.g. a microphone, and / or an electromagnetic receiver, e.g. an induction coil. The output transducer is usually as an electroacoustic transducer, z. As miniature speaker, or as an electromechanical transducer, z. B. bone conduction, realized. He is also referred to as a handset or receiver. The output transducer generates output signals that are routed to the patient's ear and are intended to produce a hearing sensation in the patient. The amplifier is usually integrated in the signal processing device. The hearing aid is powered by a battery integrated into the hearing aid housing. The essential components of a hearing aid are usually arranged on a printed circuit board as a circuit carrier or connected thereto.

Hearing instruments can also be designed as hearing aids as so-called tinnitus maskers. Tinnitus maskers are used to treat tinnitus patients. They produce from the respective hearing impairment and depending on the principle of action also dependent on ambient noise acoustic output signals that can contribute to reducing the perception of annoying tinnitus or other ear noises.

Hearing instruments can also be designed as telephones, mobile phones, headsets, headphones, MP3 players or other telecommunications or consumer electronics systems.

In the following, the term hearing instrument is to be understood as meaning both hearing aids and tinnitus maskers, comparable such devices, as well as telecommunications and consumer electronics systems.

Hearing instruments, in particular hearing aids, are known in various basic types. In ITE hearing aids (in-the-ear, also IDO or in-the-ear), a housing containing all functional components including microphone and receiver is at least partially carried in the ear canal. Completely-in-Canal (CIC) hearing aids are similar to ITE hearing aids, but are worn fully in the ear canal. In BTE hearing aids (behind-the-ear, or behind-the-ear or IDO), a housing with components such as battery and signal processing device is worn behind the ear and a flexible sound tube, also referred to as a tube, directs the acoustic output signals of a receiver from the housing to the ear canal, where often an ear piece is provided on the tube for reliable positioning of the tube end in the ear canal. RIC-BTE hearing aids (receiver-in-canal behind-the-ear) are similar to BTE hearing aids, but the receiver is carried in the ear canal and instead of a sound tube, a flexible earpiece tube conducts electrical signals instead of acoustic signals to the receiver, which is at the front of the earpiece tube attached, usually in a reliable positioning in the ear canal serving ear piece. RIC-BTE hearing aids are often used as so-called open-fit devices, in which the auditory canal remains open for the passage of sound and air to reduce the disturbing occlusion effect.

Deep-fit hearing aids (deep-ear canal hearing aids) are similar to CIC hearing aids. However, while CIC hearing aids are typically worn in the outer part of the external auditory canal, deep-fit hearing aids are advanced further toward the eardrum and are at least partially supported in the inner part of the external ear canal. The external (distal) ear canal is a skin-lined canal connecting the pinna to the eardrum. In the outer part of the ear canal, which connects directly to the auricle, this channel is formed of elastic cartilage. In the inner (proximal) part of the channel is formed by the temporal bone and thus consists of bone. The course of the ear canal between cartilaginous and bony part is usually angled and includes a different angle from person to person. In particular, the bony part of the ear canal is relatively sensitive to pressure and contact. Deep-fit hearing aids are at least partially worn in the delicate bony part of the ear canal. When advancing into the bony part of the ear canal, they must also pass the mentioned bend, which can be difficult depending on the angle. In addition, small diameter and tortuous shapes of the ear canal can further complicate advancement.

All types of hearing aids have in common that the smallest possible housing or designs are desired in order to increase the wearing comfort and to reduce the visibility of the hearing aid for cosmetic reasons.

Conventional controls such as on-off switch, program selector switch or Volume controls usually work as mechanical switches with moving parts. Often an on-off switch is integrated into the battery compartment so that the hearing aid is turned off when the battery compartment is opened. Mechanical solutions are relatively expensive and require relatively much space.

From the publication DE 10 2006 028 682 A1 is a hearing instrument with a signal processing device and a sensor device for detecting an independent of an ambient sound of the hearing instrument, physical size from the environment known. The size is used by the signal processing device as an input variable. The sensor is based on silicon in MEMS technology. Among other things, it can detect the ambient temperature.

From the publication US 7,496,206 B2 is a hearing aid with a first hearing aid, a second hearing aid and a switching device for automatically switching from the first hearing aid in the second hearing aid known. The switching device has at least one magnetic-field-controlled impedance whose impedance change can be used as the basis for the automatic switching. The magnetic-field-controlled impedance can be realized by an SMD ferrite whose impedance change is detected via a bridge circuit, for example a so-called Wheatstone bridge.

The Wheatstone bridge or Wheatstone bridge is basically a measuring device for measuring electrical resistances ohmic type, which is particularly suitable for detecting the smallest ohmic resistance changes. The basic structure of the Wheatstone bridge comprises four resistors which are connected together to form a closed ring or a square, with a voltage source in one diagonal and a voltage measuring device in the other diagonal. Two resistors in each case form a voltage divider and the voltmeter establishes a transverse relationship between them. The voltage usually picked up by the voltage measuring device is used by the switching device as a switching signal in the above-explained hearing instrument.

From the publication US 7,561,708 B2 a hearing instrument with at least one operating device is known. The operating device comprises a proximity sensor, which may be embodied for example as an infrared sensor. It is actuated in that the hearing instrument wearer brings a hand and in particular one or more fingers of the hand in the vicinity of the hearing instrument. The proximity sensor replaces a conventionally provided mechanical switch.

From the publication US 7,522,739 B2 a hearing instrument is also known, in which instead of a mechanical switch, a different type of sensor is provided, which may be designed for example as a temperature sensor.

The object of the invention is to provide a hearing instrument with a control that is inexpensive, requires little space, is designed with a small number of components and has a small number of mechanical moving parts. The invention solves this problem by a hearing instrument with operating element with the features of the independent claim.

A basic idea of the invention consists in a hearing instrument comprising a housing, a signal processing device arranged in the housing, and an operating element arranged on an outer wall of the housing, which is connected to the signal processing device and can deliver a control signal to the latter. The operating element comprises a comparator circuit and at least two thermoresistive resistors, which are arranged on the outer wall of the housing, and which are connected to the comparator circuit such that a change in the temperature difference between the two thermoresistive resistors causes a change of an output signal of the comparator circuit, wherein the control signal generated by the control element is dependent on the output signal of the comparator circuit. This results in a comparatively uncomplicated and space-saving design of the operating element. In addition, the electronic components used are designed and connectable using technologies that are used anyway in the manufacture of hearing instruments, for example, as SMD components for reflow soldering.

An advantageous embodiment consists in that the operating element comprises four thermoresistive resistors, of which at least two on the outer wall of the housing are arranged, and which are connected to the comparator circuit such that a change in the temperature difference between the at least two thermoresistive resistors causes a change in the output signal of the comparator circuit. Due to the high number of thermoresistive resistors, an increase in the sensitivity of the operating element can be achieved with a suitable spatial arrangement. In addition, a better compensation of ambient temperature influences can be achieved by suitable spatial arrangement.

A further advantageous embodiment is that the operating element comprises four thermoresistive resistors, which are arranged on the outer wall of the housing, and which are arranged in pairs and connected to the comparator circuit such that a change in the temperature difference between the two pairs of thermoresistive resistors a change the output signal of the comparator circuit causes. By the pairwise inclusion of resistors, an increase in the sensitivity of the operating element can be achieved, since, for example, in a Wheatstone bridge with a suitable spatial arrangement, it is possible to achieve an increased voltage difference with temperature differences.

A further advantageous embodiment is that the comparator circuit comprises a Wheatstone bridge, in which the thermoresistive resistors are arranged. Wheatstone bridges have proven to be particularly suitable for measuring even small resistance fluctuations, which is synonymous with the measurement of even small temperature fluctuations because of the use of thermoresistive resistors. Thereby, an increase in the sensitivity and response speed of the operating element to be actuated by a user can be achieved.

A further advantageous embodiment consists in that a device for improving the thermal coupling, in particular thermal conductive paste, is provided between the arranged on the outer wall of the housing thermoresistive resistors and the outer wall of the housing. As a result, an increase in the sensitivity and response speed of the operating element can be achieved.

A further advantageous embodiment is that the outer wall of the housing is thinner in the region in which a thermoresistive resistor is arranged at her than in an adjacent or surrounding area. Thereby, a further increase of the sensitivity and response speed of the operating element can be achieved.

Further advantages and developments emerge from the dependent claims and from the following description of exemplary embodiments and figures. Show it:

1 The hearing instrument

2 Schematic illustration of hearing instrument with operating element

3 . 4 . 5 Schematic diagram of comparator circuit

In 1 is a hearing instrument 1 shown in perspective. The hearing instrument 1 is designed as an ITE hearing instrument, but the invention can equally be used in other types of housing, eg BTE hearing instruments. It has a housing 2 on, at its side facing the viewer, also referred to as a faceplate, a vent opening 3 , a microphone opening 4 , a battery compartment 5 and a control surface 6 are arranged. At the hearing instrument 1 it is an ITE device whose distal side, ie the side facing away from the eardrum side, facing the viewer in the representation.

In 2 is the hearing instrument 1 shown in a schematic representation. In the case 2 is located below the cover of the battery compartment 5 a battery 8th , The battery 8th is with a signal processing device 9 connected and supplies these and the other electronic components with energy.

Below the microphone opening 4 there is a microphone 7 , The above-mentioned vent opening 3 is not shown for clarity. The microphone 7 is also with the signal processing device 9 connected and outputs electrically converted acoustic signals to this. The signal processing device 9 Converts or processes the acoustic signals and amplifies them to a receiver 10 which generates acoustic output signals.

Below the control surface 6 is located in the housing an operating element 11 , which also with the signal processing device 9 connected is. The signal processing by the signal processing device 9 can be influenced by a variety of parameter settings and user input. User entries are made via the control panel 6 or the operating element 11 , Possible user inputs include, for example, on / off switching, volume adjustment, and hearing program selection.

To change a setting, a user touches the hearing instrument 1 the control surface 6 , The control surface 6 works as a switching or adjusting element, depending on how the underlying control element 11 is executed and interconnected. The operating element 11 works non-mechanically, ie without moving mechanical parts. Instead, it responds to temperature changes caused by the approach of a user's finger. Advantageous embodiments of the control element 11 are explained in the following figures.

In 3 is a schematic representation of essential components of the control 11 shown. In the area of the control surface 6 placed in the outer wall of the housing 2 is integrated thermoresistive resistors 20 . 21 arranged. These are via a respective thermal coupling device 17 with the control surface 6 connected. The thermal coupling device 17 is preferably in a conventional, easy to process thermal conductive paste. Alternatively or additionally, however, metallic heat conductors can also be provided.

The thermoresistive resistors 20 . 21 are with more resistances 22 . 23 interconnected in a Wheatstone bridge. The supply voltage of the Wheatstone bridge is indicated by "+" and "-". An output signal S of the circuit is by means of a differential amplifier 16 . 32 generated and tapped for further processing.

By the thermal coupling of both thermoresistive resistors 20 . 21 with the control surface 6 or the housing 2 Variations in the ambient temperature are compensated insofar as with a suitable design of the circuit no change of the differential amplifier 32 generated output signal S occurs. However, a user approaches a finger one of the two thermoresistive resistors 20 . 21 On, so is a temperature difference between the two resistors 20 . 21 caused. This leads to a change in the output signal S. In this sense, the illustrated Wheatstone bridge operates as a comparator circuit 13 that is the temperature of each resistor 20 . 21 compares.

A change in the output signal S occurs whenever a temperature difference between the resistors 20 . 21 is caused, wherein the magnitude change of the output signal S indicates the occurrence of a temperature difference per se. In addition, the sign of the change of the output signal S indicates which of the two resistors 20 . 21 warmer or less warm compared to the other. For example, when a user approaches his finger to the resistance 20 On, it becomes low-impedance and therefore the potential at the input of the differential amplifier shown in the figure above 32 raised. Instead, a user approaches his finger to the resistance 21 on, so the potential at the input of the differential amplifier shown in the figure below 32 raised. As a result, the output of the differential amplifier 32 either raised or positive or lowered or negative. In this way, in addition to the occurrence of the operating signal itself, for example, for switching on / off, also a direction of the signal, for example, for louder / quieter places, are determined.

The output signal S of the comparator circuit 13 is further processed, for example by means of a comparator, that an on / off signal or a suitable other signal, for example, louder / quieter or program selection, is generated, then the signal processing device 9 is supplied. Depending on the design, the further signal processing of the output signal S can also be carried out directly in the signal processing device 9 be carried out, for example, after A / D conversion, so more circuit components in the control 11 or the comparator circuit 13 are not required. In the manner explained, the comparator circuit forms 13 together with the further processing of the output signal S, an operating element by which a user inputs to influence or change the signal processing by the signal processing device 9 can make.

The comparator circuit 13 is built in conventional technology, eg using SMD components, which are processed in reflow soldering. It can be separated from the signal processing device as a separate component 9 , as a module, made and in the hearing instrument 1 be mounted.

In 4 is another embodiment of the comparator circuit 14 shown schematically. It comprises thermoresistive resistors as explained above 24 . 25 connected via thermal coupling device 18 with the control surface 6 are connected. The control surface 6 is as previously explained in the housing 2 integrated, with the outer wall of the housing in the area of the control surface 6 comparatively thinner than the outer wall of the adjacent, surrounding areas 12 of the housing 2 is executed. Due to the thinner design of the outer wall of the housing is a better thermal coupling of the thermoresistive resistors 24 . 25 with the environment of the housing 2 achieved so that a faster and more sensitive response to temperature changes by approaching the finger of a user is achieved.

The further resistances 26 . 27 the comparator circuit implemented as a Wheatstone bridge 14 are also designed as thermoresistive resistors. This results in an improved compensation of the comparator circuit 14 achieved against fluctuations in the ambient temperature. Here are the other thermoresistive resistors 26 . 27 not with the outer wall of the housing 2 but are inside the case 2 ,

The further resistances 26 . 27 are connected to the resistors connected to the outer wall 24 . 25 in comparison to the previously explained comparator circuit 13 interconnected crosswise. This results in a greater sensitivity to temperature changes to the resistors 24 . 25 , A user approaches his finger to the resistance 24 on, so the potential at the input of the differential amplifier shown in the figure above 33 raised. Approaching the resistance 25 reduces the potential at the underlying input of the differential amplifier 33 , Approaching both resistors simultaneously increases the differential amplifier 33 applied potential difference and thus causes the increased sensitivity. Depending on the version of the differential amplifier 33 is the comparator circuit 14 unable to output different output signals S depending on which of the resistors 24 and 25 was heated or touched. In such an embodiment, the comparator circuit is used 14 to implement a keypad. Each key signal ("keystroke") could then, for example, each switch between on / off or, for example, through volume or listening programs sequentially.

The output signal S of the comparator circuit 14 is via a differential amplifier 33 provided and, as otherwise explained above, further processed. With regard to the further processing, reference is made to the preceding explanations.

In 5 is another embodiment of a comparator circuit 15 shown. It includes thermoresistive resistors 28 . 29 . 30 . 31 all in the area of the control surface 6 on the outside wall of the housing 2 are arranged. As explained above, devices for improving the thermal coupling, such as thermal conductive paste or metallic heat conductors, are used, which are not shown for clarity.

The resistors 28 . 29 are arranged in pairs, as well as the resistors 30 . 31 , By pairwise arrangement is meant a spatially closer together lying arrangement. The comparator circuit 15 is designed in such a way that that of the differential amplifier 34 generated output signal S changes the temperature difference between the first resistor pair 28 . 29 and the second resistor pair 29 . 30 displays.

By the arrangement of all thermoresistive resistors 28 . 29 . 30 . 31 on the outside wall of the housing 2 a further improved compensation for fluctuations in the ambient temperature is achieved. In addition, by incorporating the resistors 28 . 29 . 30 . 31 in paired arrangement achieves improved sensitivity to temperature differences caused by the approach of a user's finger. With regard to the further use of the output signal S as the input signal of the signal processing device 9 Reference is made to the preceding explanations.

For example, a user approaches a finger only to the resistor 28 on, so the potential at the input of the differential amplifier in the figure above 34 raised. Approaches the user's finger because of the pairwise arrangement at the same time even the resistance 29 The potential at the input of the differential amplifier shown in the figure below is thereby switched on 34 lowered and thus the potential difference increased overall. The same applies with the opposite sign of the potential difference for a contact of the other resistor pair 30 . 31 ,

A basic idea of the invention can be summarized as follows: The object of the invention is to provide a hearing instrument with a control element which is cost-effective, requires little space, is designed with a small number of components and has a small number of mechanical moving parts. A basic idea of the invention is a hearing instrument 1 comprising a housing 2 , one in the case 2 arranged signal processing device 9 , and one on an outside wall 6 of the housing 2 arranged operating element 7 that with the signal processing device 9 is connected and can give a control signal to this. The operating element comprises an electrical comparator circuit 13 . 14 . 15 and at least two thermoresistive resistors 20 . 21 . 24 . 25 28 . 29 . 30 . 31 attached to the outside wall of the housing 2 are arranged, and with the comparator circuit 13 . 14 . 15 are connected, that a change in the temperature difference between the two thermoresistive resistors, a change of an output signal S of the comparator circuit 13 . 14 . 15 causes, that of the operating element 7 generated control signal from the output signal S of the comparator circuit 13 . 14 . 15 is dependent. This results in a comparatively uncomplicated and space-saving design of the operating element. In addition, the electronic components used are designed and connectable using technologies that are used anyway in the manufacture of hearing instruments, for example, as SMD components for reflow soldering.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102006028682 A1 [0010]
• US 7496206 B2 [0011]
• US 7561708 B2 [0013]
• US 7522739 B2 [0014]

Claims (6)

Hearing instrument ( 1 ) comprising a housing ( 2 ), one in the housing ( 2 ) arranged signal processing device ( 9 ), and one on an outer wall ( 6 ) of the housing ( 2 ) arranged control element ( 7 ) connected to the signal processing device ( 9 ) and can deliver a control signal to this, characterized in that the operating element is an electrical comparator circuit ( 13 . 14 . 15 ) and at least two thermoresistive resistors ( 20 . 21 . 24 . 25 . 28 . 29 . 30 . 31 ), which on the outer wall of the housing ( 2 ) are arranged, and which with the comparator circuit ( 13 . 14 . 15 ), that a change in the temperature difference between the two thermoresistive resistors, a change of an output signal (S) of the comparator circuit ( 13 . 14 . 15 ), whereby that of the operating element ( 7 ) generated control signal from the output signal (S) of the comparator circuit ( 13 . 14 . 15 ) is dependent. Hearing instrument ( 1 ) according to claim 1, characterized in that the operating element ( 7 ) four thermoresistive resistors ( 24 . 25 . 26 . 27 . 28 . 29 . 30 . 31 ), of which at least two on the outer wall of the housing ( 2 ) are arranged, and which with the comparator circuit ( 14 . 15 ), that a change in the temperature difference between the at least two thermoresistive resistors is a change in the output signal of the comparator circuit ( 13 . 14 . 15 ) causes. Hearing instrument ( 1 ) according to claim 1, characterized in that the operating element comprises four thermoresistive resistors ( 28 . 29 . 30 . 31 ), which on the outer wall of the housing ( 2 ) are arranged, and arranged in pairs and so with the comparator circuit ( 15 ), that a change in the temperature difference between the two pairs of thermoresistive resistors, a change of the output signal (S) of the comparator circuit ( 15 ) causes. Hearing instrument ( 1 ) according to one of the preceding claims, characterized in that the comparator circuit ( 13 . 14 . 15 ) comprises a Wheatstone bridge in which the thermoresistive resistors ( 20 . 21 . 24 . 25 . 26 . 27 . 28 . 29 . 30 . 31 ) are arranged. Hearing instrument ( 1 ) according to one of the preceding claims, characterized in that a device ( 17 . 18 ) for improving the thermal coupling, in particular thermal conductive paste, between the on the outer wall of the housing ( 2 ) arranged thermoresistive resistors ( 20 . 21 . 24 . 25 . 28 . 29 . 30 . 31 ) and the outer wall of the housing ( 2 ) is provided. Hearing instrument ( 1 ) according to one of the preceding claims, characterized in that the outer wall of the housing ( 2 ) in that area ( 6 ), in which a thermoresistive resistor ( 20 . 21 . 24 . 25 . 28 . 29 . 30 . 31 ) is thinner than in an adjacent or surrounding area ( 12 ).

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