This application claims the benefit of German Application No. 102017126644.5, filed on Nov. 13, 2017, which application is hereby incorporated herein by reference.
The present application relates to diaphragm element arrangements and corresponding methods, for example for generating sound.
To generate sound, use is usually made of loudspeakers which have one or more diaphragms which are set vibrating. The loudspeakers can also be fabricated as a microelectromechanical system (MEMS), in which a diaphragm is, for example, produced in a silicon wafer by etching and integrated on the silicon wafer, possibly together with the activation electronics.
Diaphragms of this type in microelectromechanical systems can be fabricated by appropriate configuration as bistable diaphragms, i.e. as diaphragms which have two stable states. In the two bistable states, the diaphragm is oppositely curved. Conventionally, the bistable diaphragm is then activated to change over between the two stable states, which generates an appropriate sound wave. By the combination of a plurality of such bistable diaphragms in an arrangement, desired sound waves, for example based on a signal which contains sound information, can then be generated.
It is desirable to increase the dynamics, sound level and/or modulation depth of such arrangements in order, for example, also to reduce total harmonic distortion (THD).
According to one exemplary embodiment, a diaphragm element arrangement is provided, comprising: at least one bistable diaphragm element having a first stable state and a second stable state, and a control system for activating the at least one diaphragm element, wherein the control system is configured to activate a diaphragm element of the at least one bistable diaphragm element with a control signal above a changeover threshold in order to change over between the first stable state and the second stable state, and to activate the diaphragm element or a further diaphragm element of the at least one bistable diaphragm element with an activation signal below the changeover threshold.
According to a further exemplary embodiment, a diaphragm element arrangement is provided, comprising: a bistable diaphragm element having a first stable state and a second stable state, and a control system for activating the at least one diaphragm element, wherein the control system is configured to activate the diaphragm element to excite a self-resonant vibration, and to activate the diaphragm element with a control signal below a changeover threshold which, without the resonant vibration, would be necessary to change over between the stable states, in order to change over between the stable states.
According to an additional exemplary embodiment, methods are provided, comprising: activating a bistable diaphragm element having a first stable state and a second stable state above a changeover threshold in order to change over between the first and second stable state, and activating the bistable diaphragm element or a further bistable diaphragm element below the changeover threshold.
According to a still further exemplary embodiment, a method is provided, comprising: setting a diaphragm of a bistable diaphragm element vibrating at a self-resonant frequency of the diaphragm, and changing over the bistable diaphragm element between two stable states by activation below a changeover threshold which, without the excitation to vibrate at the self-resonance, is necessary for the changeover.
The above summary should merely be understood as a brief overview over some possible exemplary embodiments and is not to be interpreted as restrictive.
In the following text, various exemplary embodiments will be explained in detail. It should be noted that these exemplary embodiments serve merely for illustration and are not to be interpreted as restrictive. For example, components illustrated in the figures can be adapted or modified. In addition to the components illustrated, further components can be used, in particular in conventional devices for generating sound such as, for example, corresponding microelectromechanical systems.
Features or components of various exemplary embodiments can be combined with one another in order to form further exemplary embodiments. Variants and adaptations which are described for one of the exemplary embodiments can also be applied to other exemplary embodiments.
The mechanical preloading can be achieved, for example, by additional layers having a defined tension being applied to a basic diaphragm, or by tension being introduced into the diaphragm directly, e.g. by implantation of a material, or by appropriate stressing of the diaphragm being carried out in the surroundings (e.g. on carrier 10). The diaphragm can likewise comprise a semiconductor material such as silicon or other layer materials, for example silicon nitride, silicon carbon compounds or the like, and can have one or more layers. Thus, in a multilayer system, for example a mechanical stress can also be produced by materials of different lattice constants.
Changing over between the bistable states can be carried out by a piezoelectric actuator.
Activation of this type, which effects the changeover of the diaphragm 11 between the two stable states, will also be designated within the context of the present invention as activation above a changeover threshold or digital activation (since it changes over between two states, similar to digital values 0 and 1).
It should be noted that the actuator with the piezoelectric element 20 does not necessarily have to be arranged on the diaphragm, as illustrated in
In exemplary embodiments, in addition to the aforementioned digital activation, activation below the changeover threshold, also designated as analog activation below, is used. In some exemplary embodiments, a single diaphragm element as illustrated in
In exemplary embodiments, as explained, both digital activation and analog activation are used. In some exemplary embodiments, a single diaphragm element (as illustrated in
In some exemplary embodiments, digital generation of sound by digital activation of one or more bistable diaphragm elements can have an analog activation signal superimposed, in order as a result to achieve more dynamics and sound level or to increase the modulation depth. In this way, in particular, the total harmonic distortion (THD) which, in an arrangement of multiple diaphragms, arises for example as a result of a finite value of a digitization step width, can be reduced. In other words, in such an arrangement with pure digital activation, only specific “sound pressures” can be generated, since each individual bistable diaphragm element can either be changed over or not during a switching operation. By additional analog activation, “intermediate values” can be generated here.
In the exemplary embodiment of
In the exemplary embodiment of
As explained with reference to
In exemplary embodiments, these overswings can be compensated by an analog signal which runs in anti-phase relative to the overswings of curve 60 being applied to analog-activated diaphragm elements (for example diaphragm elements 50A, 50B of
The curve 62 of
A further possible use of excitation below the changeover threshold is a changeover between the two stable states by resonance. This is illustrated in
A curve 70 in
By amplitude modulation, i.e. additional pulses, which are superimposed on the pulses of curve 71, with which the resonance is increased, the changeover operation can then be triggered, wherein a voltage is needed which actually lies below the changeover threshold and, because of the resonant excitation, nevertheless suffices to change over between the stable states. One example of this is illustrated by a curve 74 of
In
At 81, the diaphragm element or else a further diaphragm element of a diaphragm element arrangement like the arrangement shown in
Details of the activation above the changeover threshold and below the changeover threshold can be carried out as explained above with reference to
At least some exemplary embodiments are defined in the following examples:
Diaphragm element arrangement, comprising: at least one bistable diaphragm element having a first stable state and a second stable state, and a control system for activating the at least one diaphragm element, wherein the control system is configured to activate a diaphragm element of the at least one bistable diaphragm element with a control signal above a changeover threshold in order to change over between the first stable state and the second stable state, and to activate the diaphragm element or a further diaphragm element of the at least one bistable element with an activation signal below the changeover threshold.
Diaphragm element arrangement according to example 1, wherein the control system is configured to carry out the activation below the changeover threshold in order to increase a dynamic range and/or a modulation depth.
Diaphragm element arrangement according to example 1, wherein the at least one bistable diaphragm element comprises a multiplicity of bistable diaphragm elements, which are grouped into a multiplicity of groups, wherein each of the groups is assigned to a bit, wherein the control system is configured to activate a first part of the groups above the changeover threshold and to activate a second part of the groups below the changeover threshold.
Diaphragm element arrangement according to example 3, wherein the control system is configured to activate the second part of the groups to compensate the overswings produced by activating the first part of the groups above the changeover threshold.
Diaphragm element arrangement, comprising: a bistable diaphragm element having a first stable state and a second stable state, and a control system for activating the diaphragm element, wherein the control system is configured to activate the diaphragm element to excite a self-resonant vibration, and to activate the diaphragm element with a control signal below a changeover threshold which, without the resonant vibration, would be necessary to change over between the stable states, in order to change over between the stable states.
Diaphragm element arrangement according to example 5, wherein the activation to change over between the stable states comprises applying voltage pulses to a piezoelectric element coupled to the diaphragm.
Diaphragm element arrangement according to example 5, wherein the control system is configured to activate a further diaphragm element in anti-phase to the diaphragm element in order to excite a self-resonant vibration.
Diaphragm element arrangement according to example 5, wherein the diaphragm element arrangement is configured in accordance with example 1.
Method, comprising: activating a bistable diaphragm element having a first stable state and a second stable state above a changeover threshold in order to change over between the first and second stable state, and activating the bistable diaphragm element or a further bistable diaphragm element below the changeover threshold.
Method according to example 9, wherein the bistable diaphragm element and the further bistable diaphragm element are provided in a diaphragm element arrangement, wherein diaphragm elements of the diaphragm element arrangement are activated in groups, wherein each group is assigned to a bit, wherein at least one group assigned to a higher-value bit is activated above the changeover threshold, and at least one group assigned to a lower-value bit is activated below the changeover threshold.
Method according to example 9, wherein the activation below the changeover threshold compensates overswings which are produced by the activation above the changeover threshold.
Method according to example 9, wherein the activation below the changeover threshold increases a dynamic range and/or a modulation depth.
Method, comprising: setting a diaphragm of a bistable diaphragm element vibrating at a self-resonant frequency of the diaphragm, and changing over the bistable diaphragm element between two stable states by activation below a changeover threshold which, without the excitation to vibrate at the self-resonance, is necessary for the changeover.
Method according to example 13, wherein the activation below the changeover threshold comprises applying voltage pulses to a piezoelectric element coupled to the diaphragm.
Method according to example 13, further comprising setting a further diaphragm of a further bistable diaphragm element vibrating at a natural frequency of the further diaphragm in anti-phase to the vibrations of the diaphragm.
Method according to example 13, wherein the method is carried out according to example 9.
In view of the variations and adaptations explained above, it can be seen that the exemplary embodiments illustrated serve merely for illustration and are not to be interpreted as restrictive.
Number | Date | Country | Kind |
---|---|---|---|
102017126644.5 | Nov 2017 | DE | national |