HAPTIC ACTUATOR ASSEMBLY WITH A SPRING PRE-LOAD DEVICE
A haptic actuator assembly includes a haptic actuator configured to output displacement along a perpendicular axis and a pre-load device. The pre-load device is disposed adjacent to the haptic actuator and configured to generate a compressive load on the haptic actuator along the perpendicular axis to oppose expansion of the haptic actuator along the perpendicular axis. The pre-load device includes a casing and at least a first spring component. The casing includes a cover and a base spaced apart from and extending parallel to the cover. The haptic actuator is disposed between the cover and the base, and the first spring component is configured to exert a force in order to create the compressive load on the haptic actuator along the perpendicular axis.
The present invention is directed to a haptic actuator assembly with a mechanical pre-load device that has application in gaming, consumer electronics, automotive, entertainment, and other industries.
BACKGROUNDHaptics provide a tactile and force feedback technology that takes advantages of a user's sense of touch by applying haptic effects, such as forces, vibrations, and other motions to a user. Devices such as mobile devices, tablet computers, and handheld game controllers can be configured to generate haptic effects. Haptic effects can be generated with haptic actuators, such as an eccentric rotating mass (ERM) actuator or a linear resonant actuator (LRA). The haptic effects may include a vibrotactile haptic effect that provides a vibration at a surface or other portion of such devices.
SUMMARYOne aspect of embodiments described herein relates to a haptic actuator assembly including a haptic actuator and a pre-load device. The haptic actuator includes a layer of piezoelectric material configured to generate strain along a parallel axis, the parallel axis being parallel to a planar surface of the layer, and includes a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along a perpendicular axis, the perpendicular axis being perpendicular to the planar surface of the layer. The expansion or contraction of the haptic actuator is configured to generate a displacement of the haptic actuator along the perpendicular axis. The pre-load device is adjacent to the haptic actuator and configured to generate a compressive load on the haptic actuator along the perpendicular axis. The pre-load device includes a casing having a cover and a base spaced apart from and extending parallel to the cover. The haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof. A first spring component is disposed within the casing such that a first end of the first spring component is coupled to an interior surface of the cover and a second opposing end of the first component is coupled to an outer surface of the haptic actuator. The first spring component is configured to exert a force in order to create the compressive load on the haptic actuator along the perpendicular axis.
Another aspect of the embodiments herein relates to a haptic actuator assembly including a haptic actuator and a pre-load device. The haptic actuator includes a layer of piezoelectric material configured to generate strain along a parallel axis, the parallel axis being parallel to a planar surface of the layer, and includes a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along a perpendicular axis, the perpendicular axis being perpendicular to the planar surface of the layer. The expansion or contraction of the haptic actuator is configured to generate a displacement of the haptic actuator along the perpendicular axis. The pre-load device is adjacent to the haptic actuator and configured to generate a compressive load on the haptic actuator along the perpendicular axis. The pre-load device includes a casing having a cover, a base spaced apart from and extending parallel to the cover, a first spring component, and a second spring component. The first spring component and the second spring component are disposed at respective opposite ends of the cover and each of the first spring component and the second spring component extends between the cover and the base. The first spring component and the second spring component are configured to collectively exert a force in order to create the compressive load on the haptic actuator along the perpendicular axis. The haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof.
Another aspect of the embodiments herein relates to is a haptic-enabled device including a housing, a power source, a control device, and a haptic actuator assembly configured to generate a haptic effect at an outer surface of the housing. The haptic actuator includes a layer of piezoelectric material configured to generate strain along a parallel axis, the parallel axis being parallel to a planar surface of the layer, and includes at least two electrodes attached to or embedded within the layer of piezoelectric material, and includes a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along a perpendicular axis, the perpendicular axis being perpendicular to the planar surface of the layer. The expansion or contraction of the haptic actuator is configured to generate a displacement of the haptic actuator along the perpendicular axis. The pre-load device is adjacent to the haptic actuator and configured to generate a compressive load on the haptic actuator along the perpendicular axis. The pre-load device includes a casing having a cover and a base spaced apart from and extending parallel to the cover. The haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof. A first spring component is disposed within the casing such that a first end of the first spring component is coupled to an interior surface of the cover and a second opposing end of the first component is coupled to an outer surface of the haptic actuator. The first spring component is configured to exert a force in order to create the compressive load on the haptic actuator along the perpendicular axis. The control unit is configured to control the power source to provide power to the at least two electrodes of the haptic actuator.
The foregoing and other features, objects and advantages of the invention will be apparent from the following detailed description of embodiments hereof as illustrated in the accompanying drawings. The accompanying drawings, which are incorporated herein and form a part of the specification, further serve to explain the principles of the invention and to enable a person skilled in the pertinent art to make and use the invention. The drawings are not to scale.
The following detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary or the following detailed description.
One aspect of the embodiments herein relates to providing a pre-load device for a haptic actuator assembly. The haptic actuator assembly may include a haptic actuator, such as a piezoelectric actuator, that is configured to output displacement (e.g., strain or other deformation) and force. In one example, the displacement may be used to generate a vibrotactile haptic effect, by oscillating between a first displacement value and a second displacement value. The pre-load device may be configured to generate a pre-load on the haptic actuator that constrains the displacement provided by the haptic actuator. The constraint may still allow the haptic actuator to output displacement, but reduces an amplitude of the displacement relative to a situation in which the pre-load device is absent. In some instances, the displacement may take the form of strain that causes the haptic actuator to expand along a particular axis, and the pre-load generated by the pre-load device may be a compressive load that opposes expansion of the haptic actuator along that axis. In some instances, the pre-load may be a load that is independent of user interaction or influences that are external to the haptic actuator assembly. In other words, the pre-load may be a load that is, e.g., built into the haptic actuator assembly or internal to the haptic actuator assembly. The pre-load may constrain a displacement from the haptic actuator, an amount of change in the displacement of the haptic actuator, or a combination thereof.
In an embodiment, the pre-load device may constrain or otherwise oppose displacement from the haptic actuator in order to prevent a force that is also output by the haptic actuator from becoming too weak. For instance, the haptic actuator may have a force-displacement profile like that in
In an embodiment, the pre-load device may constrain or otherwise oppose displacement from the haptic actuator in order to protect the haptic actuator. For instance, a haptic actuator that includes piezo ceramic material may be brittle and thus may suffer cracking or other damage from excessive strain or other displacement. In such an instance, the pre-load device may constrain a range of motion from the haptic actuator by constraining its displacement, and thus may guard against the haptic actuator suffering damage associated with excessive strain. Stated another way, the pre-load device may protect the haptic actuator by opposing excessive displacement from the haptic actuator.
In an embodiment, the pre-load device may be a mechanical in nature and may be configured to generate a pre-load via a spring force or spring forces. Stated another way, the pre-load device may include at least one spring component that generates a spring force to provide a pre-load on the haptic actuator. The spring force or spring forces may, e.g., generate a compressive load that opposes expansion of the haptic actuator along one or more axes of motion. A spring component is utilized to compress the haptic actuator, and thereby pre-load the haptic actuator, and the total stiffness of the system is thereby changed. The displacement output by the haptic actuator is a function of the stiffness of the system, and thus the spring component constrains or reduces the displacement or strain from the haptic actuator.
In an embodiment, a haptic actuator assembly having the pre-load device may be disposed at a location at which the haptic actuator assembly will experience little to no external load. For instance, the haptic actuator assembly may be disposed at a back side of a mobile phone, such as on an inner surface of a back panel of the mobile phone. The back panel may have a low mass (e.g., less than 1 g), and may exert less than 1 N of external load on the haptic actuator assembly. In such a situation, the pre-load device may advantageously provide a pre-load to constrain displacement of a haptic actuator of the assembly.
In an embodiment, the power source 140 may include a battery or other energy storage device that is configured to provide power for the haptic actuator assembly 120 to generate a haptic effect (the terms power and energy are used interchangeably herein). In an embodiment, the control unit 130 may be configured to control the power source 140 to drive a haptic actuator, which is described below in more detail, of the haptic actuator assembly 120. For instance, the control unit 130 may be configured to control the power source 140 to generate a drive voltage signal or a drive current signal to be applied to the haptic actuator of the haptic actuator assembly 120. The power source 140 may be configured to generate a drive signal for the haptic actuator of the haptic actuator assembly 120 that has an amplitude in a range of 50 V to 100 V (e.g., a 60 V drive signal).
In an embodiment, the control unit 130 may be dedicated to controlling the generating of haptic effects on the haptic-enabled device 100, or may be a general purpose control unit that controls other operations on the haptic-enabled device 100. In an embodiment, the control unit 130 may include one or more microprocessors, one or more processing cores, a programmable logic array (PLA), a field programmable gate array (FPGA), an application specific integrated circuit (ASIC), or any other processing circuit.
In an embodiment, the displacement conversion device 121c may be configured to convert strain or other displacement that is along a first axis (e.g., an x-axis) to displacement that is along a second axis (e.g., a z-axis). In an embodiment, the first axis may be a parallel axis, wherein the parallel axis is parallel to a planar surface of the piezoelectric layer 121a. In an embodiment, the second axis may be a perpendicular axis, wherein the perpendicular axis is perpendicular to the planar surface of the piezoelectric layer 121a. In some cases, the displacement conversion device 121c may be a displacement amplification device that is configured to amplify a displacement along the first axis (e.g., Δx) to a greater displacement (e.g., Δz) along the second axis.
As illustrated in
As discussed in more detail below, the haptic actuator assembly 220 may include a pre-load device that constrains expansion by the haptic actuator assembly along an axis, such as the axis 217. The sub-layer 214c, or more generally the back panel 214, may by itself lack sufficient stiffness to constrain expansion of the haptic actuator assembly 220. For instance, any compressive load applied to the haptic actuator assembly 220 by the sub-layer 214c, or more generally by the back panel 214, may be less than 1 N. More generally speaking, any compressive load applied to the haptic actuator assembly 220 by the housing 210 may be less than 1 N. In some cases, the housing may apply no compressive load on the haptic actuator assembly 220. In such a situation, the absence of a pre-load may allow an amount of displacement that is output from the haptic actuator of the haptic actuator assembly to be excessive, wherein the excessive displacement may reduce a force of the vibrotactile haptic effect at the outer surface 214b and may increase a risk of damage to the haptic actuator of the haptic actuator assembly 220. Thus, a pre-load device in accordance herewith may be advantageous in such an application to constrain displacement along the axis 217 of the haptic actuator assembly 220, and particularly displacement of its haptic actuator along the axis 217.
In an embodiment, a displacement that is output by the haptic actuator assembly 220 may be generated by a haptic actuator of the haptic actuator assembly. For instance, if a haptic actuator of the haptic actuator assembly 220 expands by 5 μm along the axis 217, such that the haptic actuator is outputting a displacement of 5 μm, the haptic actuator assembly 220 may also expand by 5 μm, such that the haptic actuator assembly 220 is also outputting 5 μm of displacement. Accordingly, the amount of displacement by the haptic actuator and the amount of displacement by the haptic actuator assembly 220 may be the same, or may be different.
In an embodiment, a force that is output by the haptic actuator assembly 220, such as a force exerted against the sub-layer 214c, may be equal to a force generated by a haptic actuator of the assembly 220 minus a force of any pre-load. For instance, the haptic actuator assembly 220 may generate a pre-load of 4 N. The pre-load may be a compressive load against the haptic actuator that causes, or results in, the haptic actuator generating a force that is about 20 N. In some instances, a force that is output by the haptic actuator assembly may be about 16 N.
In an embodiment, the haptic-enabled device 200 illustrated in
In an embodiment, a haptic actuator assembly of the embodiments herein may be part of a haptic-enabled system, such as the haptic-enabled system 300 of
Like the haptic actuator assembly 120 or 220, the haptic actuator assembly 320 may be configured to output displacement and force to generate a haptic effect at the touch screen device 310. The haptic actuator assembly 320 may include a pre-load device to constrain displacement so that a sufficient amount of force accompanies the displacement. The touch screen device 310 may be directly or indirectly connected to a mounting component 350. In an embodiment, the mounting component 350 may be part of a body of a vehicle's center console.
In an embodiment, the haptic actuator assembly 420 may include a pre-load device that constrains expansion of the haptic actuator assembly 420 along the axis 417. In the embodiment of
An embodiment of a haptic actuator assembly 520 is illustrated in
In an embodiment, the pre-load device 527 includes at least a first component 527a and a second component 527b that are configured to generate a pre-load, which may be in the form of a compressive load, as represented by arrows 560 in
As illustrated in
In an embodiment, the displacement conversion device 621b-1/621b-2 is a displacement amplification device configured to convert a displacement, i.e., a first amount of displacement, caused by the strain along the axis 618 or axis 619, to a greater amount of displacement, i.e., a second amount of displacement, along the axis 617, wherein the second displacement is greater than the first displacement (see
In an embodiment, the displacement amplification device includes a lever device that is configured to perform the conversion from the first displacement to the second displacement. For instance, the displacement conversion device 621b-1/621b-2 in
In an embodiment, the haptic actuator 621 may interface with other components (e.g., with a pre-load device) via a surface of the displacement conversion device 621b-1/621b-2. For instance, the haptic actuator 621 may interface with the pre-load device via an outer surface 621h-1 of a circular central portion (e.g., 261g-1) of disc 621b-1, and/or with an outer surface 621h-2 of a circular central portion (e.g., 261g-1) of disc 621b-2. The outer surface 621h-1 and the outer surface 621h-2 may form opposite outer surfaces (also referred to as opposing outer surfaces) of the haptic actuator 621, and may act as a first interface surface and a second interface surface, respectively, for the haptic actuator 621. In such an embodiment, a pre-load device may include a first component and a second component that are disposed on the respective opposite surfaces of the haptic actuator 621. In some cases, a layer of adhesive may be applied on the outer surfaces 621h-1, 621h-2 to adhere them to a first component and a second component of a pre-load device.
In an embodiment, as illustrated in
In an embodiment, each sub-layer of the plurality of sub-layers 621p-1 . . . 621p-n may be disposed directly between one of the first set of electrode layers 621d-1 . . . 621d-n and one of the second set of electrode layers 621e-1 . . . 621e-n, such that the two electrode layers are immediately adjacent to the sub-layer. For instance, the sub-layer 621p-1 is disposed directly between the electrode layer 621d-1 and the electrode layer 621e-1, wherein the electrode layer 621d-1 and the electrode layer 621e-1 are immediately adjacent to the sub-layer 621p-1.
In an embodiment, when a voltage difference is created between any electrode layer of the first set of electrode layers 621d-1 . . . 621d-n and a corresponding or adjacent electrode layer of the second set of electrode layers 621e-1 . . . 621e-n, the voltage difference may generate an electric field between the two electrode layers. The electric field may be aligned along the axis 617. In an embodiment, the axis 617 may be parallel with a poling direction of the piezoelectric material of each sub-layer of the plurality of sub-layers 621p-1 . . . 621p-n. In an embodiment, the poling direction of the piezoelectric material may be parallel with each sub-layer of the plurality of sub-layers 621p-1 . . . 621p-n, or more generally may be parallel with the layer 621a. For instance, the poling direction may be parallel with a length dimension or a width dimension of the layer 621a. The electric field along the axis 617 between the two electrode layers may cause a sub-layer of piezoelectric material between them to generate strain. The strain may be along one or more of the axes 617-619. For instance,
As stated above, the displacement conversion device 621b-1/621b-2 may be configured to convert the strain along the axis 619 to displacement and force along the axis 617. In an embodiment, the displacement conversion device 621b-1/621b-2 may form a plurality of linkages that are connected by joints (e.g., living hinges), and a geometry of the linkages may cause the strain along the axis 619 to be converted, and in some cases amplified, to displacement along the axis 617. For instance,
In an embodiment, the first component 827a and the second component 827b may be configured to generate a pre-load through one or more spring components disposed between the first component 527a and the second component 527b in order to create the compressive load. In an embodiment, the first component 827a and the second component 827b may be configured to generate a pre-load, in the form of a compressive load on the haptic actuator 821, which is in a range of 2 N to 4 N. The pre-load in a range of 2N to 4 N enables the haptic actuator 821 to reliably and predictably deform in response to an applied electrical potential. The haptic actuator 821 may break upon application of an electrical potential if it is not sufficiently pre-loaded, while conversely the haptic actuator may not be able to reliably and predictably deform if it is excessively pre-loaded.
The pre-load device 1127 includes the spring component 1160 and a casing 1162. In an embodiment, the casing 1162 includes a cover 1164 and a base 1166 that opposes the cover 1164. In an embodiment, the cover 1164 is spaced apart from but extends generally parallel to the base 1166. In an embodiment, the casing 1162 may be formed from a material that is light weight yet strong, such as acrylonitrile butadiene styrene (ABS), polycarbonate, polypropylene, polyurethane or other polymeric material. The cover 1164 and the base 1166 may be planar components that have the same size and shape (e.g., rectangular or circular shape), or may have different sizes and/or shapes. In some instances, the cover 1164 and the base 1166 may each be rectangular, and may each have a length and a width that are each in a range of 9 mm to 25 mm. In an embodiment, the cover 1164 and the base 1166 each have a thin profile in order to keep a low overall thickness for the haptic actuator assembly 1120. For instance, the cover 1164 and the base 1166 may each have a thickness that is in a range of 1 mm to 2 mm. In an embodiment, the casing 1162 may have an overall thickness that is in a range of 1 mm to 5 mm.
The casing 1162 holds or retains the spring component 1160 and the haptic actuator 621, including both the layer 621a of piezoelectric material and the displacement conversion device 621b-1/621b-2. The haptic actuator 621 is disposed within the casing 1162 between the cover 1164 and the base 1166, with the cover 1164 and the base 1166 being disposed at respective opposite ends of the haptic actuator 621 along the axis 617 thereof. In the embodiment of
In addition to the pre-load functions described in more detail herein, the casing 1162 functions to provide the haptic actuator assembly 1120 as a self-contained device in which the pre-load generated thereby is a load that is, e.g., built into the haptic actuator assembly 1120 or internal to the haptic actuator assembly 1120. As such, the pre-load generated by the pre-load device 1127 may be a load that is independent of user interaction or influences that are external to the haptic actuator assembly 1120. For example, the haptic actuator assembly 1120 having the pre-load device 1127 may be disposed at a location at which the haptic actuator assembly 1120 will experience little to no external load. For instance, the haptic actuator assembly 1120 may be disposed at a back side of a mobile phone, such as on an inner surface of a back panel of the mobile phone as described above with respect to
In an embodiment, the casing 1162 may include one or more sidewalls (not shown) extending between the cover 1164 and the base 1166. In an embodiment, the sidewalls permit movement between the cover 1164 and the base 1166 and therefore function similar to a suspension system that is configured to allow preferential movement of the cover 1164 and/or the base 1166 along a certain axis, such as along the perpendicular axis 617. In another embodiment, the casing 1162 may include one or more partial sidewalls (not shown) that do not extend the full length between the cover 1164 and the base 1166. The partial sidewalls may, for example, extend from the cover 1164 towards the base 1166 or may extend from the base 1166 towards the cover 1164. In yet another embodiment, the casing 1162 may include one or more one or more connectors or columns extending between the cover 1164 and the base 1166. Sidewalls, partial sidewalls, and/or connectors/columns of the casing 1162 may assist in forming the haptic actuator assembly 1120 as a self-contained device.
The spring component 1160 is disposed within the casing 1162 such that a first end 1161A is coupled to an interior surface of the cover 1164 and a second opposing end 1161B is coupled to an outer surface of the haptic actuator 621. The spring component 1160 is configured to create a compressive load on the haptic actuator 621 along the axis 617, and the compressive load opposes expansion of the haptic actuator 621 along the axis 617. The spring component 1160 is shown as a helical element for illustrative purposes only to represent the functional operation of the spring component 1160 and is not intended to limit an actual physical shape thereof. The spring component 1160 may be any type of spring element having the spring properties to exert the desired compressive force, including but not limited to elastomers, helical or coiled springs, leaf springs, flat springs, wave washers, snap dome springs, or a compliant element such as rubber, foam, or flexures. For example,
To generate a pre-load, the cover 1164 urges the spring component 1160 against the haptic actuator 621 to apply a compressive force against haptic actuator 621. In an embodiment, the spring component 1160 may be configured to generate a pre-load that is in a range of 2 N to 4 N. The pre-load in a range of 2 N to 4 N enables the haptic actuator 621 to reliably and predictably deform in response to an applied electrical potential. When the haptic actuator 621 deforms in response to an applied electrical potential, the spring component 1160 exerts a spring force on the haptic actuator 621 that constrains the displacement from the haptic actuator 621 to a value that is a fraction (e.g., ½, ¾) of its rated displacement. By decreasing the displacement output from the haptic actuator 621, the spring component 1160 causes an increase in the force output by the haptic actuator 621. As a result, when a vibrotactile haptic effect is generated by the haptic actuator assembly 1120, the force accompanying the vibrotactile haptic effect may be stronger and more perceivable relative to the situation in which the vibrotactile haptic effect is generated by a haptic actuator having no pre-load.
In an embodiment, the haptic actuator assembly 1120 can function as a harmonic oscillator that runs at a relatively high frequency. In operation, when the power source 1140 provides a sinusoidal drive signal to the haptic actuator assembly 1120, the haptic actuator 621 vibrates as directed by the oscillating drive signal. More particularly, as described above with respect to the operation of the haptic actuator 621, the displacement that is output by the haptic actuator 621 along the axis 617 may come from the expansion or contraction of the haptic actuator 621. In an embodiment, displacement of the haptic actuator 621 along the axis 617 causes movement or vibration of both the cover 1164 and the base 1166. In another embodiment, one of the cover 1164 or the base 1166 is configured to act as a mechanical ground as described in more detail below such that displacement of the haptic actuator 621 along the axis 617 causes movement or vibration of only the other opposing structure that is not configured to be a mechanical ground. The haptic actuator assembly 1120 thus vibrates and provides haptic sensations to the housing or part of the haptic-enabled device to which it is attached.
As stated above, in an embodiment hereof, one of the cover 1164 or the base 1166 may be configured to act as a mechanical ground while the other structure vibrates/displaces. For example, in the embodiment of
Alternatively, in another embodiment, the base 1166 may be configured to act as a mechanical ground and thereby translate the force generated by the haptic actuator 621 to the spring component 1160 and the cover 1164. The spring component 1160 may be compressible along the axis 617, such that when the haptic actuator 621 expands along the axis 617, the spring component 1160 and the cover 1164 provide much less resistance against that expansion than does the base 1164. As a result, most or all of the expansion of the haptic actuator 621 may be channeled toward vibrating or displacing the cover 1164, rather than toward the base 1166. The base 1166 may be of a relatively stiffer material having a suitable Young's modulus and/or thickness to be configured to act as a mechanical ground.
In an embodiment, the components of the haptic actuator assembly 1120 can be chosen to provide more effective haptic sensations and the resonant frequency of the haptic actuator assembly 1120 is tailored via the spring component 1160. The haptic actuator 621 has a first resonant frequency and the haptic actuator assembly 1120 has a second resonant frequency, the second resonant frequency being different than the first resonant frequency. The second resonant frequency is a function of or is determined via a spring constant of the first spring component 1160. For example, if the haptic actuator 621 oscillates at a natural frequency of the haptic actuator assembly 1120 (including the haptic actuator 621 as well as the pre-load device 1127), then stronger forces and more effective haptic sensations can be output. More particularly, when the power source 1140 provides a drive signal to the haptic actuator assembly 1120 and the drive signal is a periodic signal having a frequency equal to a resonant frequency of the haptic actuator assembly 1120, the haptic actuator assembly 1120 resonates to provide more effective haptic sensations. Due to the addition of the spring component 1160, the total spring constant of the haptic actuator assembly 1120 is different than the spring constant of the haptic actuator 621 alone. As such, the resonant frequency of the haptic actuator assembly 1120 varies depending on the spring constant of the spring component 1160 and the resonant frequency of the haptic actuator assembly 1120 may be controlled by selecting a particular or predetermined spring component 1160. Stated another way, the spring component 1160 may be chosen to change or alter the resonant frequency of the haptic actuator 621 alone such that the haptic actuator assembly 1120 has a desired or predetermined resonant frequency in order to amplify the output force and effects. By controlling the resonant frequency, the haptic actuator assembly 1120 may be configured to resonate at a certain frequency to present a wide spectrum of frequencies by amplitude modulation techniques. The haptic actuator assembly 1120 thus may be configured to realize mechanical resonance as described above when the drive signal has a frequency equal to a resonant frequency of the haptic actuator assembly 1120.
In addition to tuning or tailoring the resonant frequency of the haptic actuator assembly 1120 via the spring component 1160, additional mass may be included on the base 1166 (or the cover 1164 if the base 1166 is configured to be the mechanical base and the cover 1164 is configured to resonate) to ensure that the base 1166 has sufficient acceleration in the resonant frequency. Additional mass may be included on the base 1166 by attaching a separate component of a predetermined mass to the base 1166, or by forming the base 1166 to have the predetermined mass.
The pre-load device 1327 includes the first spring component 1360A, the second spring component 1360B and a casing 1362. The casing 1362 is similar to the casing 1162 described above and includes a cover 1364 and a base 1366 spaced apart from and extending parallel to the cover 1364. The casing 1362 holds or retains the first spring component 1360A, the second spring component 1360B, and the haptic actuator 621, including both the layer 621a of piezoelectric material and the displacement conversion device 621b-1/621b-2. The haptic actuator 621 is disposed between the cover 1364 and the base 1366, with the cover 1364 and the base 1366 being disposed at respective opposite ends of the haptic actuator 621 along the axis 617. In this embodiment, however, the haptic actuator 621 does not contact the cover 1364 or the base 1366 but rather is suspended between the cover 1364 and the base 1366 via the first spring component 1360A and the second spring component 1360B as will be described in more detail below.
As described above with respect to casing 1162, the casing 1362 functions to provide the haptic actuator assembly 1320 as a self-contained device in which the pre-load generated thereby is a load that is, e.g., built into the haptic actuator assembly 1320 or internal to the haptic actuator assembly 1320. As such, the pre-load generated by the pre-load device 1327 may be a load that is independent of user interaction or influences that are external to the haptic actuator assembly 1320. For example, the haptic actuator assembly 1320 having the pre-load device 1327 may be disposed at a location at which the haptic actuator assembly 1320 will experience little to no external load. For instance, the haptic actuator assembly 1320 may be disposed at a back side of a mobile phone, such as on an inner surface of a back panel of the mobile phone as described above with respect to
More particularly, the first spring component 1360A is disposed within the casing 1362 such that a first end 1361A is coupled to an interior surface of the cover 1364 and a second opposing end 1361B is coupled to an outer surface of the haptic actuator 621. The second spring component 1360B is disposed within the casing 1362 such that a first end 1361C is coupled to an interior surface of the base 1366 and a second opposing end 1361D is coupled to an outer surface of the haptic actuator. Collectively, the first spring component 1360A and the second spring component 1360B are configured to create a compressive load on the haptic actuator 621 along the axis 617, and the compressive load opposes expansion of the haptic actuator 621 along the axis 617. The first spring component 1360A and the second spring component 1360B are shown as helical elements for illustrative purposes only to represent the functional operation thereof and the depiction is not intended to describe or limit an actual physical shape thereof. The first spring component 1360A and the second spring component 1360B may be any type of spring element having the spring properties to exert the desired compressive force, including but not limited to elastomers, helical or coiled springs, leaf springs, flat springs, wave washers, snap dome springs, or a compliant element such as rubber, foam, or flexures. Further, although there is a single spring element illustrated in
To generate a pre-load, the cover 1364 urges the first spring component 1360A against the haptic actuator 621 while the base 1366 urges the second spring component 1360B against the haptic actuator 621 to collectively apply a compressive force against haptic actuator 621. In an embodiment, first spring component 1360A and the second spring component 1360B may be configured to collectively generate a pre-load that is in a range of 2 N to 4 N. The pre-load in a range of 2 N to 4 N enables the haptic actuator 621 to reliably and predictably deform in response to an applied electrical potential. When the haptic actuator 621 deforms in response to an applied electrical potential, the first spring component 1360A and the second spring component 1360B each exert a spring force on the haptic actuator 621 that constrains the displacement from the haptic actuator 621 to a value that is a fraction (e.g., ½, ¾) of its rated displacement. By decreasing the displacement output from the haptic actuator 621, the first spring component 1360A and the second spring component 1360B collectively cause an increase in the force output by the haptic actuator 621. As a result, when a vibrotactile haptic effect is generated by the haptic actuator assembly 1320, the force accompanying the vibrotactile haptic effect may be stronger and more perceivable relative to the situation in which the vibrotactile haptic effect is generated by a haptic actuator having no pre-load.
Similar to the haptic actuator assembly 1120, the haptic actuator assembly 1320 can function as a harmonic oscillator that runs at a relatively high frequency and operates similar to the haptic actuator assembly 1120. In operation, when a power source (not shown in
As stated above, in an embodiment hereof, one of the cover 1364 or the base 1366 may be configured to act as a mechanical ground while the other structure vibrates/displaces. For example, in the embodiment of
In an embodiment, the components of the haptic actuator assembly 1320 can be chosen to provide more effective haptic sensations. More particularly, the spring constants of the first spring component 1360A and the second spring component 1360B may be different from each other. For example, as described above, the spring constants of the first spring component 1360A and the second spring component 1360B may be different from each other and may be configured such that one of the cover 1364 or the base 1366 is configured to act as a mechanical ground and displacement of the haptic actuator 621 along the axis 617 causes movement or vibration of only the other opposing structure that is not configured to be a mechanical ground. When the haptic actuator assembly 1320 is disposed underneath of a touchscreen of a mobile device, for example, such differential spring constants that provide a mechanical ground via the second spring component 1360B while permitting movement or vibration via the first spring component 1360A will essentially suspend the touchscreen and permit the haptic effects to be felt by the user.
In addition, in an embodiment, the spring constants of the first spring component 1360A and the second spring component 1360B may be different from each other and may be configured such that the haptic actuator assembly 1320 is configured to realize mechanical resonance. Stated another way, the resonant frequency of the haptic actuator assembly 1320 is tailored via the first spring component 1360A and the second spring component 1360B. The haptic actuator 621 has a first resonant frequency and the haptic actuator assembly 1320 has a second resonant frequency, the second resonant frequency being different than the first resonant frequency. The second resonant frequency is a function of or is determined via the spring constants of the first spring component 1360A and the second spring component 1360B. Due to the addition of the first spring component 1360A and the second spring component 1360B, the total spring constant of the haptic actuator assembly 1320 is different than the spring constant of the haptic actuator 621 alone. As such, the resonant frequency of the haptic actuator assembly 1320 varies depending on the spring constants of each of the first spring component 1360A and the second spring component 1360B and the resonant frequency of the haptic actuator assembly 1320 may be controlled by selecting particular or predetermined spring components 1360A, 1360B. Stated another way, the first spring component 1360A and the second spring component 1360B may be chosen to change or alter the resonant frequency of the haptic actuator 621 alone such that the haptic actuator assembly 1320 has a desired or predetermined resonant frequency in order to amplify the output force and effects. By controlling the resonant frequency, the haptic actuator assembly 1320 may be configured to resonate at a certain frequency to present a wide spectrum of frequencies by amplitude modulation techniques. Utilizing two spring components in the haptic actuator assembly 1320 (i.e., the first spring component 1360A and the second spring component 1360B) allows for a wide range of possibilities for tailoring the resonant frequency of the haptic actuator assembly 1320 since two spring components contribute to the overall stiffness of the system. Stated another way, the resonant frequency of the system is a function of the overall stiffness of the system, which can be tuned or tailored by various combinations of spring constants of the first spring component 1360A and the second spring component 1360B.
In addition to tuning or tailoring the resonant frequency of the haptic actuator assembly 1320 via the first spring component 1360A and the second spring component 1360B, additional mass may be included on the base 1366 (or the cover 1364 if the base 1366 is configured to be the mechanical base and the cover 1364 is configured to resonate) to ensure that the base 1366 has sufficient acceleration in the resonant frequency. Additional mass may be included on the base 1366 by attaching a separate component of a predetermined mass to the base 1366, or by forming the base 1366 to have the predetermined mass.
The pre-load device 1627 includes the first spring component 1660A, the second spring component 1660B and the casing 1662. The casing 1662 includes a cover 1664 and a base 1666 spaced apart from and extending parallel to the cover 1664. In an embodiment, the base 1666 includes a sidewall 1668 that is disposed around a perimeter of the base 1666 and extends in a direction towards the cover 1664. The sidewall 1668 does not extend between the base 1666 and the cover 1664, and does not directly contact the cover 1664. The sidewall 1668 defines an end surface 1674. The first spring component 1660A and the second spring component 1660B are each attached to and extend outwardly from a respective outer end 1676 of the cover 1664, as best shown in
After the cover 1664 and the base 1666 are assembled such that they are coupled together via the first spring component 1660A and the second spring component 1660B, the casing 1662 is configured to hold or contain the haptic actuator 621, including both the layer 621a of piezoelectric material and the displacement conversion device 621b-1/621b-2. The haptic actuator 621 is disposed between the cover 1664 and the base 1666, with the cover 1664 and the base 1666 being disposed at respective opposite ends of the haptic actuator 621 along the axis 617 thereof. In an embodiment, the base 1666 supports the haptic actuator 621, or stated another way the haptic actuator 621 is disposed on an interior surface of the base 1166. In an embodiment, the base 1666 may be attached to the haptic actuator 621 via an adhesive or some other manner of attachment.
As described above with respect to casing 1162, the casing 1662 functions to provide the haptic actuator assembly 1620 as a self-contained device in which the pre-load generated thereby is a load that is, e.g., built into the haptic actuator assembly 1620 or internal to the haptic actuator assembly 1620. As such, the pre-load generated by the pre-load device 1627 may be a load that is independent of user interaction or influences that are external to the haptic actuator assembly 1620. For example, the haptic actuator assembly 1620 having the pre-load device 1627 may be disposed at a location at which the haptic actuator assembly 1620 will experience little to no external load. For instance, the haptic actuator assembly 1620 may be disposed at a back side of a mobile phone, such as on an inner surface of a back panel of the mobile phone as described above with respect to
Collectively, the first spring component 1660A and the second spring component 1660B are configured to create a compressive load on the haptic actuator 621 along the axis 617, and the compressive load opposes expansion of the haptic actuator 621 along the axis 617. The first spring component 1660A and the second spring component 1660B may be any type of spring element having the spring properties to exert the desired compressive force, including but not limited to elastomers, helical or coiled springs, leaf springs, flat springs, wave washers, snap dome springs, or a compliant element such as rubber, foam, or flexures. Further, although there is a single spring element illustrated in
To generate a pre-load, the first spring component 1660A and the second spring component 1660B each provide a pulling spring force to urge the cover 1664 and the base 1666 against the haptic actuator 621. Stated another way, the first spring component 1660A and the second spring component 1660B may each be considered to be a tensioner that applies a force to urge the cover 1664 and the base 1666 towards each other. In turn, the cover 1664 and the base 1666 thereby exert the desired compressive force against the haptic actuator 621 to generate the pre-load. In an embodiment, first spring component 1660A and the second spring component 1660B may be configured to collectively generate a pre-load that is in a range of 2 N to 4 N. The pre-load in a range of 2 N to 4 N enables the haptic actuator 621 to reliably and predictably deform in response to an applied electrical potential. When the haptic actuator 621 deforms in response to an applied electrical potential, the pre-load exerted on the haptic actuator 621 constrains the displacement from the haptic actuator 621 to a value that is a fraction (e.g., ½, ¾) of its rated displacement. By decreasing the displacement output from the haptic actuator 621, the first spring component 1660A and the second spring component 1660B are configured to collectively cause an increase in the force output by the haptic actuator 621. As a result, when a vibrotactile haptic effect is generated by the haptic actuator assembly 1620, the force accompanying the vibrotactile haptic effect may be stronger and more perceivable relative to the situation in which the vibrotactile haptic effect is generated by a haptic actuator having no pre-load.
Similar to the haptic actuator assembly 1120, the haptic actuator assembly 1620 can function as a harmonic oscillator that runs at a relatively high frequency and operates similar to the haptic actuator assembly 1120. In operation, when a power source (not shown in
As stated above, in an embodiment hereof, one of the cover 1664 or the base 1666 may be configured to act as a mechanical ground while the other structure vibrates/displaces. For example, one of the cover 1664 or the base 1666 may be of a relatively stiffer material having a suitable Young's modulus and/or thickness to be configured to act as a mechanical ground. The mechanical ground (i.e., one of the cover 1664 or the base 1666) translates the force generated by the haptic actuator 621 to the other planar element (i.e., the other of the cover 1664 or the base 1666). Stated another way, the mechanical ground functions to essentially channel displacement from the haptic actuator assembly 1620 toward the other planar element. As a result, most or all of the expansion of the haptic actuator 621 may be channeled toward vibrating or displacing the other planar element.
In an embodiment, the components of the haptic actuator assembly 1620 can be chosen to provide more effective haptic sensations. More particularly, the spring constants of first spring component 1660A and the second spring component 1660B may be selected to tune the respective spring component and tailor the haptic effects accordingly. For example, in an embodiment, the haptic actuator assembly 1620 may be configured to realize mechanical resonance. Stated another way, the resonant frequency of the haptic actuator assembly 1620 is tailored via the first spring component 1660A and the second spring component 1660B. The haptic actuator 621 has a first resonant frequency and the haptic actuator assembly 1620 has a second resonant frequency, the second resonant frequency being different than the first resonant frequency. The second resonant frequency is a function of or is determined via the spring constants of the first spring component 1660A and the second spring component 1660B. Due to the addition of the first spring component 1660A and the second spring component 1660B, the total spring constant of the haptic actuator assembly 1620 is different than the spring constant of the haptic actuator 621 alone. As such, the resonant frequency of the haptic actuator assembly 1620 varies depending on the spring constants of each of the first spring component 1660A and the second spring component 1660B and the resonant frequency of the haptic actuator assembly 1620 may be controlled by selecting particular or predetermined spring components 1660A, 1660B. Stated another way, the first spring component 1660A and the second spring component 1660B may be chosen to change or alter the resonant frequency of the haptic actuator 621 alone such that the haptic actuator assembly 1620 has a desired or predetermined resonant frequency in order to amplify the output force and effects. By controlling the resonant frequency, the haptic actuator assembly 1620 may be configured to resonate at a certain frequency to present a wide spectrum of frequencies by amplitude modulation techniques.
In addition to tuning or tailoring the resonant frequency of the haptic actuator assembly 1620 via the first spring component 1660A and the second spring component 1660B, additional mass may be included on the moving planar element (i.e., one of the cover 1664 or the base 1664, which is not configured to be the mechanical ground) to ensure that the moving planar element has sufficient acceleration in the resonant frequency. Additional mass may be included on the moving planar element by attaching a separate component of a predetermined mass, or by forming the moving planar element to have the predetermined mass.
In an embodiment, the spring constants of the first spring component 1660A and the second spring component 1660B may be different from each other. More particularly, when the first spring component 1660A and the second spring component 1660B have different spring constants and the haptic actuator 621 expands or otherwise generates displacement along the axis 617, the displacement of the base 1666 and/or the cover 1664 is off-center relative to its center of mass, and thus may generate a torque (also referred to as a moment) about the center of mass of the base 1666 and/or the cover 1664. The base 1666 and/or the cover 1664 may thus exhibit some rotation about its center of mass when being pushed by the haptic actuator 621. Stated differently, when the first spring component 1660A and the second spring component 1660B have different spring constants, part of the base 1666 and/or the cover 1664 may act as a lever when being pushed by the haptic actuator 621. This lever configuration may be able to enhance a haptic effect generated by the movement of the haptic actuator 621 and of the base 1666 and/or the cover 1664.
In the embodiment of
The first spring component 1760A is disposed such that a first end 1761A is coupled to an interior surface of the cover 1764 and a second opposing end 1761B is coupled to an interior surface of the base 1766. Similarly, the second spring component 1760B is disposed such that a first end 1761C is coupled to the interior surface of the cover 1764 and a second opposing end 1761D is coupled to the interior surface of the base 1766. The first spring component 1760A and the second spring component 1760B are shown as helical elements for illustrative purposes only to represent the functional operation thereof and this depiction is not intended to describe, or limit, an actual physical shape thereof. The first spring component 1760A and the second spring component 1760B may be any type of spring element having the spring properties to tune the resonant frequency of the haptic actuator assembly 1720 as described in more detail below, including but not limited to elastomers, helical or coiled springs, leaf springs, flat springs, wave washers, snap dome springs, or a compliant element such as rubber, foam, or flexures.
In the embodiment of
The haptic actuator assembly 1720 is configured to realize mechanical resonance via the first spring component 1760A and the second spring component 1760B. More particularly, the haptic actuator 621 has a first resonant frequency and the haptic actuator assembly 1720 has a second resonant frequency, the second resonant frequency being different than the first resonant frequency. The second resonant frequency is a function of or is determined via the spring constants of the first spring component 1760A and the second spring component 1760B. Due to the addition of the first spring component 1760A and the second spring component 1760B, the total spring constant of the haptic actuator assembly 1720 is different than the spring constant of the haptic actuator 621 alone. As such, the resonant frequency of the haptic actuator assembly 1720 varies depending on the spring constants of each of the first spring component 1760A and the second spring component 1760B and the resonant frequency of the haptic actuator assembly 1720 may be controlled by selecting particular or predetermined spring components 1760A, 1760B. Stated another way, the first spring component 1760A and the second spring component 1760B may be chosen to change or alter the resonant frequency of the haptic actuator 621 alone such that the haptic actuator assembly 1720 has a desired or predetermined resonant frequency in order to amplify the output force and effects. By controlling the resonant frequency, the haptic actuator assembly 1720 may be configured to resonate at a certain frequency to present a wide spectrum of frequencies by amplitude modulation techniques.
In an embodiment, an overall thickness of the haptic actuator assembly 1720/1620/1520/1420/1320/1120 may be in a range of 2 mm to 10 mm.
In an embodiment, when a voltage difference of, e.g., 50 V to 100 V is applied to two electrodes of a haptic actuator 621, and when the compressive load or other pre-load is applied to the haptic actuator 621 by the pre-load device 1727/1627/1527/1427/1327/1127, the haptic actuator 621 outputs a displacement (relative to a baseline state in which no voltage difference is being applied to the haptic actuator 621) that is in a range of 5 μm to 15 μm, and the haptic actuator assembly 1720/1620/1520/1420/1320/1120 is configured to output a force along the axis 617 that is in a range of 2N to 10 N.
In an embodiment, when the voltage difference being applied to the haptic actuator 621 is, e.g., between 50 V and 100 V, and when the compressive load is applied to the haptic actuator 621 by the pre-load device 1727/1627/1527/1427/1327/1127, the haptic actuator outputs a displacement (relative to the baseline state) that is in a range of 25% to 50% of a defined nominal displacement for the haptic actuator 621, wherein the nominal displacement may be specific to the voltage difference. Further in this example, the haptic actuator assembly 1720/1620/1520/1420/1320/1120 may be configured to output a force along the axis 617 that is in a range of 50% to 75% of a defined blocking force for the haptic actuator 621, wherein the blocking force may also be specific to the voltage difference.
In an embodiment, the control unit 130/1130 may be configured to generate a drive signal for the haptic actuator 621 that is at a resonant frequency of the respective haptic actuator assembly 1720/1620/1520/1420/1320/1120. In an embodiment, the drive signal may have an amplitude (e.g., peak-to-peak amplitude) that is below a defined threshold, in order to further avoid generating excessive force or displacement that would damage the haptic actuator, even with the presence of a pre-load.
In an embodiment, the control unit 130/1130 may be configured to generate a drive signal with a frequency content that includes at least a first frequency that is a resonant frequency of the haptic actuator assembly 1720/1620/1520/1420/1320/1120 and a second frequency that is not the resonant frequency of the haptic actuator assembly 1720/1620/1520/1420/1320/1120. In other words, the drive signal may include a first component having the first frequency and a second component having the second frequency. In some cases, the first component and the second component may be the only frequencies of the drive signal. The control unit 130/1130 may cause the first component of the drive signal to have a first amplitude that is below the defined threshold (because the first component has the resonant frequency), and may cause the second component to have a second amplitude that is higher than the first amplitude and above the defined threshold.
Additional discussion of various embodiments is presented below:
Embodiment 1 is a haptic actuator assembly, comprising: a haptic actuator and a pre-load device. The haptic actuator includes a layer of piezoelectric material configured to generate strain along a parallel axis, the parallel axis being parallel to a planar surface of the layer, and includes a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along a perpendicular axis, the perpendicular axis being perpendicular to the planar surface of the layer. The expansion or contraction of the haptic actuator is configured to generate a displacement of the haptic actuator along the perpendicular axis.
The pre-load device is adjacent to the haptic actuator and configured to generate a compressive load on the haptic actuator along the perpendicular axis. The pre-load device includes a casing having a cover and a base spaced apart from and extending parallel to the cover. The haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof. A first spring component is disposed within the casing such that a first end of the first spring component is coupled to an interior surface of the cover and a second opposing end of the first component is coupled to an outer surface of the haptic actuator. The first spring component is configured to exert a force in order to create the compressive load on the haptic actuator along the perpendicular axis.
Embodiment 2 includes the haptic actuator assembly of embodiment 1, wherein the displacement conversion device of the haptic actuator is a displacement amplification device configured to convert a displacement output by the layer of piezoelectric material along the parallel axis due to the strain thereof to a greater displacement of the haptic actuator along the perpendicular axis.
Embodiment 3 includes the haptic actuator assembly of embodiment 2, wherein the displacement amplification device of the haptic actuator includes a lever device configured to convert the displacement along the parallel axis to the greater displacement along the perpendicular axis.
Embodiment 4 includes the haptic actuator assembly of embodiment 3, wherein the lever device of the haptic actuator includes a first disc and a second disc disposed on respective opposite planar surfaces of the layer of piezoelectric material, wherein each disc of the first disc and the second disc forms a truncated cone with a respective planar surface of the layer of piezoelectric material.
Embodiment 5 includes the haptic actuator assembly of any one of embodiments 1-4, wherein the first spring component is a spring plunger.
Embodiment 6 includes the haptic actuator assembly of any one of embodiments 1-4, wherein the first spring component includes a screw and a flexible film component, the screw being configured to adjust a spring force of the flexible film component.
Embodiment 7 includes the haptic actuator assembly of any one of embodiments 1-6, wherein the pre-load device further includes a second spring component disposed within the casing such that a first end of the second spring component is coupled to an interior surface of the base and a second opposing end of the second spring component is coupled to an outer surface of the haptic actuator. The first spring component and the second spring component are configured to collectively exert the force in order to create the compressive load on the haptic actuator along the perpendicular axis.
Embodiment 8 includes the haptic actuator assembly of embodiment 7, wherein the first spring component has a first spring constant and the second spring component has a second spring constant, the first spring constant being different than the second spring constant.
Embodiment 9 includes the haptic actuator assembly of any one of embodiments 1-8, wherein the compressive load along the perpendicular axis generated by the first component and the second component of the pre-load device is in a range of 2 N to 4 N.
Embodiment 10 includes the haptic actuator assembly of any one of embodiments 1-9, wherein the haptic actuator further comprises at least two electrodes attached to or embedded within the layer of piezoelectric material and configured to create a voltage difference along the perpendicular axis. The layer of piezoelectric material is configured to contract along the parallel axis in response to the voltage difference along the perpendicular axis.
Embodiment 11 includes the haptic actuator assembly of embodiment 10, wherein when the voltage difference between the at least two electrodes is between 50 V and 100 V and when the compressive load is applied to the haptic actuator by the pre-load device, the haptic actuator outputs a displacement along the perpendicular axis, relative to a baseline state in which there is no voltage difference between the at least two electrodes, that is in a range of 1 μm to 15 μm, and the haptic actuator assembly is configured to output a force along the perpendicular axis that is in a range of 2 N to 10 N.
Embodiment 12 includes the haptic actuator assembly of any one of embodiments 1-11, wherein the haptic actuator has a first resonant frequency and the haptic actuator assembly has a second resonant frequency, the second resonant frequency being different than the first resonant frequency and the second resonant frequency being determined via a spring constant of the first spring component.
Embodiment 13 is a haptic actuator assembly, comprising: a haptic actuator and a pre-load device. The haptic actuator includes a layer of piezoelectric material configured to generate strain along a parallel axis, the parallel axis being parallel to a planar surface of the layer, and includes a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along a perpendicular axis, the perpendicular axis being perpendicular to the planar surface of the layer. The expansion or contraction of the haptic actuator is configured to generate a displacement of the haptic actuator along the perpendicular axis.
The pre-load device is adjacent to the haptic actuator and configured to generate a compressive load on the haptic actuator along the perpendicular axis. The pre-load device includes a casing having a cover, a base spaced apart from and extending parallel to the cover, a first spring component, and a second spring component. The first spring component and the second spring component are disposed at respective opposite ends of the cover and each of the first spring component and the second spring component extends between the cover and the base. The first spring component and the second spring component are configured to collectively exert a force in order to create the compressive load on the haptic actuator along the perpendicular axis. The haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof.
Embodiment 14 includes the haptic actuator assembly of embodiment 13, wherein the first spring component and the second spring component are attached to the cover and are releasably attached to the base.
Embodiment 15 is a haptic-enabled device comprising: a housing, a power source, and a haptic actuator assembly configured to generate a haptic effect at an outer surface of the housing. The haptic actuator includes a layer of piezoelectric material configured to generate strain along a parallel axis, the parallel axis being parallel to a planar surface of the layer, and includes at least two electrodes attached to or embedded within the layer of piezoelectric material, and includes a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along a perpendicular axis, the perpendicular axis being perpendicular to the planar surface of the layer. The expansion or contraction of the haptic actuator is configured to generate a displacement of the haptic actuator along the perpendicular axis.
The pre-load device is adjacent to the haptic actuator and configured to generate a compressive load on the haptic actuator along the perpendicular axis. The pre-load device includes a casing having a cover and a base spaced apart from and extending parallel to the cover. The haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof. A first spring component is disposed within the casing such that a first end of the first spring component is coupled to an interior surface of the cover and a second opposing end of the first component is coupled to an outer surface of the haptic actuator. The first spring component is configured to exert a force in order to create the compressive load on the haptic actuator along the perpendicular axis.
The haptic-enabled device further comprises a control unit configured to control the power source to provide power to the at least two electrodes of the haptic actuator.
Embodiment 16 includes the haptic-enabled device of embodiment 15, wherein any compressive load applied to the haptic actuator assembly by the housing of the haptic-enabled device is less than 1 N.
Embodiment 17 includes the haptic-enabled device of any one of embodiments 15-16, further comprising a touch screen device that forms a first side of the housing. The housing comprises a back panel that forms a second and opposite side of the housing. The haptic actuator assembly is disposed at the second side of the housing, so that force generated by the haptic actuator assembly is exerted against the second side of the housing.
Embodiment 18 includes the haptic-enabled device of any one of embodiments 15-17, wherein the control unit is configured to control the power source to provide a drive signal to the haptic actuator and wherein the drive signal is a periodic signal having a frequency equal to a resonant frequency of the haptic actuator assembly.
Embodiment 19 includes the haptic-enabled device of any one of embodiments 15-18, wherein the haptic actuator has a first resonant frequency and the haptic actuator assembly has a second resonant frequency, the second resonant frequency being different than the first resonant frequency and the second resonant frequency being determined via a spring constant of the first spring component.
Embodiment 20 includes the haptic-enabled device of any one of embodiments 15-19, wherein the pre-load device further includes a second spring component disposed within the casing such that a first end of the second spring component is coupled to an interior surface of the base and a second opposing end of the second spring component is coupled to an outer surface of the haptic actuator, the first spring component and the second spring component being configured to collectively exert the force in order to create the compressive load on the haptic actuator along the perpendicular axis.
While various embodiments have been described above, it should be understood that they have been presented only as illustrations and examples of the present invention, and not by way of limitation. It will be apparent to persons skilled in the relevant art that various changes in form and detail can be made therein without departing from the spirit and scope of the invention. Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the appended claims and their equivalents. It will also be understood that each feature of each embodiment discussed herein, and of each reference cited herein, can be used in combination with the features of any other embodiment. All patents and publications discussed herein are incorporated by reference herein in their entirety.
Claims
1.-20. (canceled)
21. A haptic actuator assembly, comprising:
- a haptic actuator having a planar surface and configured to generate a displacement of the haptic actuator along a perpendicular axis that is perpendicular to the planar surface of the haptic actuator; and
- a pre-load device configured to exert an elastic force to generate a compressive load on the haptic actuator along the perpendicular axis.
22. The haptic actuator assembly of claim 21, wherein the pre-load device comprises:
- a casing having a cover and a base spaced apart from and extending parallel to the cover, wherein the haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof, and
- at least one elastic component disposed within the casing and configured to exert the elastic force to generate the compressive load on the haptic actuator along the perpendicular axis.
23. The haptic actuator assembly of claim 22, wherein the at least one elastic component includes a first elastic component, and wherein a first end of the first elastic component is coupled to an interior surface of the cover and a second opposing end of the first elastic component is coupled to an outer surface of the haptic actuator.
24. The haptic actuator assembly of claim 23, wherein the at least one elastic component includes a second elastic component, and wherein a first end of the second elastic component is coupled to an interior surface of the base and a second opposing end of the second elastic component is coupled to the outer surface of the haptic actuator, the first component and the second component being configured to collectively exert the force in order to create the compressive load on the haptic actuator along the perpendicular axis
25. The haptic actuator assembly of claim 24, wherein the first elastic component has a first spring constant and the second elastic component has a second spring constant, the first spring constant being different than the second spring constant.
26. The haptic actuator assembly of claim 22, wherein the at least one elastic component comprises a first elastic component and a second elastic component, and each of the first elastic component and the second elastic component extends between the cover and the base.
27. The haptic actuator assembly of claim 26, wherein the first elastic component and the second elastic component are configured to collectively exert the elastic force to generate the compressive load on the haptic actuator along the perpendicular axis.
28. The haptic actuator assembly of claim 27, wherein the first elastic component and the second elastic component are disposed at respective opposite ends of the cover
29. The haptic actuator assembly of claim 28, wherein the first elastic component and the elastic spring component are attached to the cover and are releasably attached to the base.
30. The haptic actuator assembly of claim 21, wherein the pre-load device is configured to exert the elastic force on the haptic actuator regardless of whether the displacement of the haptic actuator is generated or not.
31. The haptic actuator assembly of claim 21, wherein the haptic actuator is configured to expand or contract along the perpendicular axis to generate the displacement of the haptic actuator.
32. The haptic actuator assembly of claim 21, wherein the haptic actuator is configured to generate strain along a parallel axis that is parallel to the planar surface and to convert the strain to the displacement of the haptic actuator along the perpendicular axis.
33. The haptic actuator assembly of claim 32, wherein the haptic actuator comprises:
- a layer of piezoelectric material configured to generate the strain along the parallel axis, and
- a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along the perpendicular axis,
- wherein the expansion or contraction of the haptic actuator is configured to generate the displacement of the haptic actuator along the perpendicular axis
34. The haptic actuator assembly of claim 22, wherein the at least one elastic component includes at least one of a spring plunger or a spring-loaded device.
35. The haptic actuator assembly of claim 22, wherein the at least one elastic component includes a screw and a flexible film component, the screw being configured to adjust a spring force of the flexible film component.
36. The haptic actuator assembly of claim 21, wherein the compressive load along the perpendicular axis generated by the first component and the second component of the pre-load device is in a range of 2 N to 4 N.
37. A haptic actuator assembly, comprising:
- a haptic actuator having a planar surface and configured to generate strain along a parallel axis that is parallel to the planar surface and to convert the strain to expansion or contraction of the haptic actuator along a perpendicular axis, the perpendicular axis being perpendicular to the planar surface of the haptic actuator, wherein the expansion or contraction of the haptic actuator is configured to generate a displacement of the haptic actuator along the perpendicular axis; and
- a pre-load device configured to exert an elastic force to generate a compressive load on the haptic actuator along the perpendicular axis.
38. The haptic actuator assembly of claim 37, wherein the haptic actuator comprises:
- a layer of piezoelectric material configured to generate the strain along the parallel axis, and
- a displacement conversion device configured to convert the strain of the layer of piezoelectric material along the parallel axis to expansion or contraction of the haptic actuator along the perpendicular axis,
39. The haptic actuator assembly of claim 38, wherein the pre-load device comprises:
- a casing having a cover and a base spaced apart from and extending parallel to the cover, wherein the haptic actuator is disposed between the cover and the base, the cover and the base being disposed at respective opposite ends of the haptic actuator along the perpendicular axis thereof, and
- at least one elastic component disposed within the casing and configured to exert the elastic force to generate the compressive load on the haptic actuator along the perpendicular axis.
40. A haptic-enabled device, comprising:
- a housing;
- a power source;
- a haptic actuator assembly configured to generate a haptic effect at an outer surface of the housing, the haptic actuator assembly comprising a haptic actuator having a planar surface and configured to generate a displacement of the haptic actuator along a perpendicular axis that is perpendicular to the planar surface; and a pre-load device and configured to exert an elastic force to generate a compressive load on the haptic actuator along the perpendicular axis; and
- a control unit configured to control the power source to provide power to the haptic actuator.
Type: Application
Filed: Jul 2, 2019
Publication Date: Dec 19, 2019
Inventors: Vahid KHOSHKAVA (Montreal), Juan Manuel CRUZ HERNANDEZ (Montreal), Kaniyalal SHAH (Fremont, CA)
Application Number: 16/460,085