This specification relates to distributed mode actuators (DMAs), electromagnetic (EM) actuators, and distributed mode loudspeakers that feature DMAs and EM actuators.
Many conventional loudspeakers produce sound by inducing piston-like motion in a diaphragm. Panel audio loudspeakers, such as distributed mode loudspeakers (DMLs), in contrast, operate by inducing uniformly distributed vibration modes in a panel through an electro-acoustic actuator. Typically, the actuators are piezoelectric or electromagnetic actuators.
During the operation of a typical actuator, components of the actuator bend, causing these components to experience mechanical stress. This stress may decrease the performance and lifetime of the actuator. Conventional DMAs and EM actuators featuring flexible components with fixed widths and conventional EM actuators having flexible components bent at right angles are particularly susceptible to decreased performance due to mechanical stress.
Disclosed are improvements to conventional distributed mode actuators (DMAs) and electromagnetic (EM) actuators. For example, implementations of such DMAs and EM actuators feature flexible components with portions having increased dimensions compared to conventional devices. The portions having increased dimensions are strategically located in high stress regions. The components can also be shaped so that the increased dimension does not significantly increase the volume occupied by the actuator.
By attaching a DMA or an EM actuator to a mechanical load, such as an acoustic panel, the actuators can be used to induce vibrational modes in the panel to produce sound.
In general, in a first aspect, the invention features a panel audio loudspeaker that includes a panel extending in a plane and an actuator coupled to the panel and configured to couple vibrations to the panel to cause the panel to emit audio waves. The actuator includes a rigid frame attached to a surface of the panel, the rigid frame including a portion extending perpendicular to the panel surface. The actuator also includes an elongate flexure attached at one end to the portion of the frame extending perpendicular to the panel surface, the flexure extending parallel to the plane and having a first width where the flexure is attached to the frame different from a second width where the flexure is unattached to the frame. The actuator further includes an electromechanical module attached to a portion of the flexure unattached to the frame, the electromechanical module being configured to displace an end of the flexure that is free of the frame in a direction perpendicular to the surface of the panel during operation of the actuator.
Embodiments of the panel audio loudspeaker can include one or more of the following features and/or one or more features of other aspects. For example, the actuator can include a beam that includes the elongate flexure and the electromechanical module, and the frame can include a stub to which the beam is anchored at one end. The stub can include a slot for receiving an end of the elongate flexure to anchor the beam.
In some embodiments, the electromechanical module includes one or more layers of a piezoelectric material supported by the elongate flexure.
In some embodiments, a width of the elongate flexure at the slot is greater than a width of the slot. Portions of the flexure extending laterally from the slot can be folded out of a plane of the elongate flexure.
In some embodiments, the first width is larger than the second width, while in other embodiments, the first width is smaller than the second width.
In certain embodiments, the actuator includes a magnet and a voice coil forming a magnetic circuit. In some embodiments the electromagnetic module can include the magnet and the voice coil is rigidly attached to the frame. In other embodiments, the electromagnetic module includes the voice coil and the magnet is rigidly attached to the frame.
The rigid frame can include a panel extending parallel to the plane and at least one pillar extending perpendicular to the plane. The elongate flexure can be attached to the pillar. In some embodiments, the elongate flexure includes a first portion extending parallel to the plane and a second portion extending perpendicular to the plane, the second portion being affixed to the pillar to attach the elongate flexure to the frame. In some embodiments, the first portion has a tapered width as the elongate flexure extends away from the pillar.
In some embodiments, the elongate flexure includes a sheet of a material bent to form the first and second portions. The elongate flexure can be formed from a metal or alloy. In some embodiments, the elongate flexure is attached to the electromagnetic module at an end opposite an end of the elongate flexure attached to the pillar.
In some embodiments, the panel includes a display panel.
In another aspect, the invention features an actuator that includes a frame that includes a panel extending in a plane and pillars extending perpendicular from the plane. The actuator also includes a magnetic circuit assembly including a magnet and a voice coil, the magnet and voice coil being moveable relative to each other during operation of the actuator along an axis perpendicular to the plane of the panel. The actuator further includes one or more suspension members attaching the frame to a portion of the magnetic circuit assembly. Each suspension member includes a first portion extending parallel to the plane from one of the sidewall to an end free from any sidewall and a second portion extending in an axial direction affixing the suspension member to the sidewall. During operation of the actuator the suspension member flexes to accommodate axial displacements of the magnet relative to the voice coil.
In another aspect, the actuator includes a stub that includes a slot having a width in a first direction. The actuator also includes a beam extending along a second direction perpendicular to the first direction and attached to the stub at one end forming a cantilever, the beam including a vane and a piezoelectric material supported by the vane. The slot of the stub can receive a first portion of the vane to attach the beam to the stub, while a second portion of the vane can extend free from the stub in the second direction. The first length of the vane can have a width in the first direction that is larger than the width of the slot. The second length of the vane can have a width in the first direction that is the same as or smaller than the width of the slot. During operation of the actuator, the piezoelectric material is energized to displace a portion of the beam extending from the stub along an axial direction perpendicular to a plane defined by the first and second directions.
In another aspect, the invention features a mobile device that includes an electronic display panel extending in a plane, a chassis attached to the electronic display panel and defining a space between a back panel of the chassis and the electronic display panel, and an electronic control module housed in the space, the electronic control module including a processor. The mobile device also includes an actuator an actuator housed in the space and attached to a surface of the electronic display panel. The actuator includes a rigid frame attached to a surface of the electronic display panel, the rigid frame including a portion extending perpendicular to the electronic display panel surface. The actuator also includes an elongate flexure attached at one end to the portion of the frame extending perpendicular to the electronic display panel surface, the flexure extending parallel to the plane and having a larger width where the flexure is attached to the frame than where the flexure is unattached to the frame. The actuator further includes an electromechanical module attached to a portion of the flexure unattached to the frame, the electromechanical module being configured to displace an end of the flexure that is free of the frame in a direction perpendicular to the surface of the electronic display panel during operation of the actuator.
Among other advantages, embodiments include actuators that have a decreased chance of failure from mechanic stress caused by bending when compared to conventional actuators.
Another advantage is that the actuator occupies substantially the same space as conventional actuators. This can be particularly beneficial where an actuator is integrated into a larger electronic device and is required to fit within a prescribed volume.
Other advantages will be evident from the description, drawings, and claims.
Like reference symbols in the various drawings indicate like elements.
The disclosure features actuators for panel audio loudspeakers, such as distributed mode loudspeakers (DMLs). Such loudspeakers can be integrated into a mobile device, such as a mobile phone. For example, referring to
Mobile device 100 also produces audio output. The audio output is generated using a panel audio loudspeaker that creates sound by causing the flat panel display to vibrate. The display panel is coupled to an actuator, such as a DMA or EM actuator. The actuator is a movable component arranged to provide a force to a panel, such as touch panel display 104, causing the panel to vibrate. The vibrating panel generates human-audible sound waves, e.g., in the range of 20 Hz to 20 kHz.
In addition to producing sound output, mobile device 100 can also produces haptic output using the actuator. For example, the haptic output can correspond to vibrations in the range of 180 Hz to 300 Hz.
In general, actuator 210 includes a frame that connects the actuator to display panel 104 via a plate 106. The frame serves as a scaffold to provide support for other components of actuator 210, which commonly include a flexure and an electromechanical module.
The flexure is typically an elongate member that extends in the X-Y plane, and when vibrating, is displaced in the Z-direction. The flexure is generally attached to the frame at at least one end. The opposite end can be free from the frame, allowed to move in the Z-direction as the flexure vibrates.
The electromechanical module is typically a transducer that transforms electrical signals into a mechanical displacement. At least a portion of the electromechanical module is usually rigidly coupled to the flexure so that when the electromechanical module is energized, the module causes the flexure to vibrate.
Generally, actuator 210 is sized to fit within a volume constrained by other components housed in mobile device 100, including electronic control module 220 and battery 230. Actuator 210 can be one of a variety of different actuator types, such as an electromagnet actuator or a piezoelectric actuator.
Turning now to specific embodiments, in some implementations the actuator is a distributed mode actuator (DMA). For example,
Referring specifically to
While
The length of vane 312 measured in the X-direction is denoted LF, and is also called the end-to-end extension.
The end of vane 312, anchored by frame 320 has a first width WF1, which is greater than the width of the frame 320, denoted WS. Towards the anchored end, the width of vane 312 increases to form two wings that extend laterally from slot 322. In this implementation, the wings are symmetric about a central axis 350 that runs in the X-direction and divides vane 312 into symmetric top and bottom portions, although in other implementations, the wings need not be symmetric. Referring to the top wing (i.e., the wing above central axis 350), the edges of the wing are contiguous with the edge of the top portion of vane 312 that is parallel to the X-axis. The width of the top wing, denoted WW, is measured from the top edge of vane 312, to the point of the wing farthest from central axis 350. The width of either wing, WW, the width of the free end of the flexure, WF2, and the width of the anchored end of the flexure, WF1, are related by the equation, WF1=WF2+2WW.
Each wing also has a length, denoted LW. In the implementation shown in
The width of slot 322 is proportioned to be larger than the width of the wings. For example, WS can be two or more times WW, three or more times WW, or four or more times WW. The height of slot 322, as measured in the Z-direction, is approximately equal to the height of vane 312, which can be approximately 0.1 to 1 mm, e.g., 0.2 mm to 0.8 mm, such as 0.3 mm to 0.5 mm.
In general, the gap between frame 320 and piezoelectric stacks 314a and 314b is smaller than either LW or WW. For example, the gap can be one half or less of LW or WW, one third or less of LW or WW, or one fifth or less of LW or WW.
In the example of
The wings of vane 312 extend on either side of frame 320 to distribute mechanical stress that results from the operation of DMA 300. The dimensions of the wings can be chosen such that the wings most effectively distribute stress. For example LF can be on the order of approximately 150 μm or more, 175 μm or more, or 200 μm or more, such as about 1000 μm or less, 500 μm or less. As another example, WW can be 4 μm or more, 6 μm or more, or 8 μm or more, such as about 50 μm or less, 20 μm or less.
The shape of the wings is chosen to improve (e.g., optimize) the distribution of stress. For example, when viewed from above, as in
While
DMA 400 includes a beam 410 connected to frame 320. Like beam 310 of
In the example of
Like the wings of vane 312, those of vane 412 contribute to the distribution of stress experienced by the vane during the operation of DMA 400. One difference between vane 312 and 412, is that the latter can distribute stress on DMA 400 while occupying a smaller volume than the former. In systems that include multiple components occupying a limited space, it is advantageous to reduce the volume of the multiple components. For example, the electrical components housed in a mobile device must all fit within the limited space of the chassis of the mobile device. Therefore, the smaller volume occupied by vane 412, when compared to vane 312, is advantageous, although the functional performance of the two vanes is approximately the same.
The one or more piezoelectric layers of piezoelectric stacks 314a and 314b may be any appropriate type of piezoelectric material. For instance, the material may be a ceramic or crystalline piezoelectric material. Examples of ceramic piezoelectric materials include barium titanate, lead zirconium titanate, bismuth ferrite, and sodium niobate, for example. Examples of crystalline piezoelectric materials include topaz, lead titanate, barium neodymium titanate, potassium sodium niobate (KNN), lithium niobate, and lithium tantalite.
Vanes 312 and 412 may be formed from any material that can bend in response to the force generated by piezoelectric stacks 314a and 314b. The material that forms vanes 312 and 412 should also being sufficiently rigid to avoid being substantially deformed as a result of bending. For example, vanes 312 and 412 can be a single metal or alloy (e.g., iron-nickel, specifically, NiFe42), a hard plastic, or another appropriate type of material. The material from which vane 312 is formed should have a low CTE mismatch.
While in some implementations, the actuator 210 is a distributed mode actuator, as shown in
In general, an EM actuator includes a magnetic circuit assembly, which in turn includes a magnet and a voice coil. The EM actuator also includes one or more suspension members that attach the magnetic circuit assembly to a frame. The frame includes one or more pillars each attached to a suspension member along a vertical segment of the suspension member. In addition to the vertical segment, each suspension member also includes an arm that extends perpendicularly from a respective pillar and is attached at one end to the magnetic circuit assembly.
An embodiment of an EM actuator 500 is shown in
EM actuator 500 includes a frame 520, which connects the actuator to panel 106. Referring to
While, in the example of
Between outer magnet assembly 542 and inner magnet assembly 544, is an air gap 546. Voice coil 548 is attached to frame 520 and is positioned in air gap 546. During the operation of EM actuator 500, voice coil 548 is energized, which induces a magnetic field in air gap 546. Because magnet assembly 542, is positioned in the induced magnetic field and has a permanent axial magnetic field, parallel to the Z-axis, the magnet assembly experiences a force due to the interaction of its magnetic field with that of the voice coil. Flexures 530a-530d bend to allow electromechanical module 540 to move in the Z-direction in response to the force experienced by magnet assembly 542.
Frame 520 includes a panel that extends primarily in the XY-plane and four pillars that extend primarily in the Z-direction. Each of the four pillars have a width measured in the X-direction that is sized to allow it to attach to one of flexures 530a-530d. Although in this implementation, EM actuator 500 includes four pillars, each connected to one of flexures 530a-530d, in other implementations, the actuator can include more than four flexures connected to an equal number of pillars, while in yet other implementations, the actuator can include less than four flexures connected to an equal number of pillars.
Flexures 530a-530d include vertical segments extending in the Z-direction, which attach the flexures to the pillars of frame 520.
Turning now to the structure of the flexures,
Flexure 600 includes two arms 601 and 602, both extending parallel to the XY plane. First arm 601 includes a first straight segment 611A bounded by dotted lines and extending in the Y-direction. A second straight segment 612A of first arm 601 extends in the X-direction. First arm 601 further includes a first curved segment 621A that connects first straight segment 611A and second straight segment 612A. A third straight segment 613A of first arm 601 extends in the Y-direction. Second straight segment 612A is connected to third straight segment 613A by a second curved segment 622A.
Second arm 602 is parallel and identical to first arm 601. Second arm 602 includes a first straight segment 611B connected to a second straight segment 612B by a first curved segment 621B. Additionally, second arm 602 includes a third straight segment 613B connected to second straight segment 612B by a second curved segment 622B. Although no magnet assembly is shown, third straight segments 613A and 613B are each connected to opposite sides of the magnet assembly. That is, the third straight segment of the first arms of each flexure 630a-630d connect to the structural element positioned above the magnet A, while the third straight segment of the second arms of each flexure 630a-630d connect to bottom plate 550. The structural element positioned above magnet A has a substantially polygonal shape, e.g., a quadrilateral shape.
Flexure 600 includes a vertical segment 630. Vertical segment 630 extends perpendicular to the first and second arms 601 and 602. A first arm connector 631 attaches first arm 601 to vertical segment 630, while a second arm connector 632 attaches second arm 602 to vertical segment 630. Both connectors 631 and 632 are curved such that each the connectors along with vertical segment 630 collectively form a C-shaped segment.
As described above with regard to
Accordingly, the width of a flexure can be increased at locations that experience higher stress in order to reduce failure at these points. For example, flexures 530a-530d do not have a fixed width. Instead, to reduce the chances of failure, flexures 530a-530d have a maximum width at the bending portions.
The free end of the third straight segment of flexure 700 has a first width denoted Wmin1, which is measured from the bottom or outside edge of third straight segment 713 to the top or inside edge of the third straight segment. Although not shown in
While the third straight segments of flexure 700 is attached to the magnet assembly, second curved segment 722 extends away from the connection with the magnet assembly. When the magnet assembly moves along the Z-axis during the operation of the EM actuator, second curved segment 722 also moves along the Z-axis. To accommodate the movement of the magnet assembly, second curved segment 722 also bends along the Z-axis. The bending along the Z-axis causes second curved segment 722 to experience mechanical stress.
Moving counterclockwise from the free end of third straight segment 713, the width of the first portion increases until it reaches a maximum width, wmax1, which can be about 1.4 mm to about 1.6 mm, e.g., 1.45 mm, 1.5 mm, 1.55 mm. As discussed above, the location of Wmax1 corresponds to a portion of second curved segment 722 that experiences higher stress during the operation of the EM actuator, as compared to the average stress experienced by flexure 700. The increased width at second curved segment 722 reinforces the flexure so that it is less likely to fail during the operation of the EM actuator. More specifically, during operation of the actuator, second curved segment 722 twists as a result of the portion closest to the boundary with third straight segment 713 being displaced by an amount that is different from the displacement of the portion closest to second straight segment 712. Stress focuses at the twisting location, causing fatigue of the flexure. By maximizing wmax1, the structural stiffness of second curved segment 722 is maximized, and as a result the twisting motion of the segment is minimized.
Second curved segment 722 has a first radius of curvature along an outer edge that is smaller than a second radius of curvature along an inner edge of the second curved segment. Both the rounded bend and the increased width of second curved segment 722 serve to reduce the stress experienced by flexure 700, by redistributing the stress on the flexure from higher than average stress areas to lower than average stress areas.
Similarly to the rounded bend of second curved segment 722, the curvature of first curved segment 722 also serves to reduce the stress experienced by flexure 700. The width of first curved segment 721 has a width labeled Wmin2. Wmin2 can be about 0.4 mm to about 0.6 mm, e.g., 0.45 mm, 0.5 mm, 0.55 mm. Moving counterclockwise from Wmax1 to Wmin2, the width of the flexure gradually decreases. Continuing counterclockwise from Wmin2 to the edge of the first arm connector 731, the width of the flexure gradually increases to a width Wmax2, measured at the boundary between first straight segment 711A and first arm connector 731. Wmax2 can be about 0.7 to about 0.9 mm, e.g., 0.75 mm, 0.8 mm, 0.85 mm.
Referring to
During operation of the actuator, the ends of first and second arm connectors 731 and 732 that are closest to first straight segments 711A and 711B experience a greater displacement in the Z-direction compared to the ends that are closest to the vertical segment 730, due to bending of the second and first arm connectors. By virtue of their positions, first and second arm connectors 731 and 732 experience greater stress than the average stress experienced by flexure 700. To reduce the likelihood of first and second arm connectors 731 and 732 failing due to stress, the width of the connectors increases from a width Wmin3, measured at the boundary between the first or second arm connectors and vertical segment 730, to the width Wmax2. Wmin3 can be about 0.4 mm to about 0.6 mm, e.g., 0.45 mm, 0.5 mm, 0.55 mm.
In general, the disclosed actuators are controlled by an electronic control module, e.g., electronic control module 220 in
Processor 810 may be implemented as any electronic device capable of processing, receiving, or transmitting data or instructions. For example, processor 810 can be a microprocessor, a central processing unit (CPU), an application-specific integrated circuit (ASIC), a digital signal processor (DSP), or combinations of such devices.
Memory 820 has various instructions, computer programs or other data stored thereon. The instructions or computer programs may be configured to perform one or more of the operations or functions described with respect to the mobile device. For example, the instructions may be configured to control or coordinate the operation of the device's display via display driver 830, signal generator 840, one or more components of I/O module 850, one or more communication channels accessible via network/communications module 860, one or more sensors (e.g., biometric sensors, temperature sensors, accelerometers, optical sensors, barometric sensors, moisture sensors and so on), and/or actuator 210.
Signal generator 840 is configured to produce AC waveforms of varying amplitudes, frequency, and/or pulse profiles suitable for actuator 210 and producing acoustic and/or haptic responses via the actuator. Although depicted as a separate component, in some embodiments, signal generator 840 can be part of processor 810. In some embodiments, signal generator 840 can include an amplifier, e.g., as an integral or separate component thereof.
Memory 820 can store electronic data that can be used by the mobile device. For example, memory 820 can store electrical data or content such as, for example, audio and video files, documents and applications, device settings and user preferences, timing and control signals or data for the various modules, data structures or databases, and so on. Memory 820 may also store instructions for recreating the various types of waveforms that may be used by signal generator 840 to generate signals for actuator 210. Memory 820 may be any type of memory such as, for example, random access memory, read-only memory, Flash memory, removable memory, or other types of storage elements, or combinations of such devices.
As briefly discussed above, electronic control module 800 may include various input and output components represented in
Each of the components of I/O module 850 may include specialized circuitry for generating signals or data. In some cases, the components may produce or provide feedback for application-specific input that corresponds to a prompt or user interface object presented on the display.
As noted above, network/communications module 860 includes one or more communication channels. These communication channels can include one or more wireless interfaces that provide communications between processor 810 and an external device or other electronic device. In general, the communication channels may be configured to transmit and receive data and/or signals that may be interpreted by instructions executed on processor 810. In some cases, the external device is part of an external communication network that is configured to exchange data with other devices. Generally, the wireless interface may include, without limitation, radio frequency, optical, acoustic, and/or magnetic signals and may be configured to operate over a wireless interface or protocol. Example wireless interfaces include radio frequency cellular interfaces, fiber optic interfaces, acoustic interfaces, Bluetooth interfaces, Near Field Communication interfaces, infrared interfaces, USB interfaces, Wi-Fi interfaces, TCP/IP interfaces, network communications interfaces, or any conventional communication interfaces.
In some implementations, one or more of the communication channels of network/communications module 860 may include a wireless communication channel between the mobile device and another device, such as another mobile phone, tablet, computer, or the like. In some cases, output, audio output, haptic output or visual display elements may be transmitted directly to the other device for output. For example, an audible alert or visual warning may be transmitted from the electronic device 100 to a mobile phone for output on that device and vice versa. Similarly, the network/communications module 860 may be configured to receive input provided on another device to control the mobile device. For example, an audible alert, visual notification, or haptic alert (or instructions therefore) may be transmitted from the external device to the mobile device for presentation.
The actuator technology disclosed herein can be used in panel audio systems, e.g., designed to provide acoustic and/or haptic feedback. The panel may be a display system, for example based on OLED of LCD technology. The panel may be part of a smartphone, tablet computer, or wearable devices (e.g., smartwatch or head-mounted device, such as smart glasses).
Other embodiments are in the following claims.
This application is a continuation of U.S. application Ser. No. 16/261,420, filed Jan. 29, 2019, which claims the benefit of U.S. Provisional Application No. 62/774,106, filed on Nov. 30, 2018, the contents of each of which are incorporated by reference herein.
Number | Date | Country | |
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62774106 | Nov 2018 | US |
Number | Date | Country | |
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Parent | 16261420 | Jan 2019 | US |
Child | 17071290 | US |