Abstract: A fluidic valve may include an inlet, a control port, an additional control port, an outlet, a fluid channel configured to convey fluid from the inlet to the outlet, and a piston that includes (1) a restricting gate transmission element configured to block, when the piston is in a first position, the fluid channel and unblock, when the piston is in a second position, the fluid channel, (2) a controlling gate transmission element configured to interface with a control pressure from the control port that forces the piston towards the first position when applied to the controlling gate transmission element, and (3) an additional controlling gate transmission element configured to interface with an additional control pressure from the additional control port that forces the piston towards the second position when applied to the additional controlling gate transmission element. Various other related devices, systems, and methods are also disclosed.

Abstract: A method creates haptic stimulations on a user of an artificial reality system. The system includes a head-mounted display (HMD) and a wearable device. The HMD includes a display and speakers. The wearable device includes a plurality of transducers that can each generate waves to provide haptic feedback to a user. The system displays media content on the display and, in accordance with the displayed media content, determines a virtual object location in the displayed media content corresponding to a physical object location. The system provides, to the user, audio directed to the virtual object location. The system activates one or more transducers to provide haptic feedback at a target location on the user, distinct from the physical object location, to produce haptic feedback whose perceptual interpretation is at the physical object location based on a combination of the displayed media, the provided audio, and the haptic feedback.

Abstract: Example devices include a fluidic device, such as a fluidic valve, including a body formed from a rigid body material including a fluidic source, a fluidic drain, and a fluidic gate, each of which may have a fluid connection with a chamber, or a portion thereof. The device may further include a gate transmission element, located within the chamber, that is controllable between at least a first position and a second position using a gate pressure received through the fluidic drain. Adjustment of the position of the gate transmission element may allow control of fluid flow through the device. Other devices, methods, systems, and computer-readable media are also disclosed.

Abstract: A fluidic device controls fluid flow in channel from a source to a drain. In some embodiments, the fluidic devices comprise a gate, a channel, and an obstruction. The gate comprises at least one chamber whose volume increases with fluid pressure. A high-pressure state of the gate corresponds to a first chamber size and a low-pressure state of the gate corresponds to a second chamber size that is smaller than the first chamber size. The obstruction controls a rate of fluid flow within the channel based on the fluid pressure in the gate. The obstruction induces at most a first flow rate of fluid in the channel in accordance with the low-pressure state of the gate, and at least a second flow rate of the fluid in the channel in accordance with the high-pressure state of the gate.

Abstract: The disclosed method of manufacturing may include positioning a membrane on top of a channeled layer where the channeled layer includes a shim portion that is dimensioned to limit the amount of compression appliable to the membrane. The membrane may be positioned at a juncture in the channeled layer. The method may next include positioning a transmission housing layer membrane and the channeled layer. The method may also include fastening the channeled layer, the membrane, and the transmission housing layer together. The channeled layer, the membrane, and the transmission housing layer may be held together with at least one fastening member. Various other methods, systems, and computer-readable media are also disclosed.

Abstract: The disclosed apparatus may include a fluidic channel connecting an inlet port and an outlet port. The apparatus may further include a gate transmission element configured to limit fluid flow between the inlet port and the outlet port. Still further, the apparatus may include a primary gate terminal connected to a second fluidic inlet port, where pressure or force at the primary gate may at least partially control movement of the gate transmission element. The apparatus may also include a secondary gate terminal connected to the second fluidic inlet port. Pressure or force at the secondary gate may at least partially control movement of the gate transmission element. Various other associated methods, systems, and computer-readable media are also disclosed.

Abstract: In some examples, a device includes a first fluidic amplifier stage, configured to receive a fluidic input and provide a first stage fluidic output, and a second fluidic amplifier stage, configured to receive the first stage fluidic output and provide a second stage fluidic output. The first fluidic amplifier stage may include a fluidic valve, for example having a source, a gate, and a drain. The fluidic input may be connected to the gate of the fluidic valve through a fluid channel, and a fluid flow between the source and the drain of the fluidic valve may be controlled by the fluidic input. An example device may be configured to provide a fluidic output, wherein the fluidic output is based on the fluidic input, and the fluidic output may be provided to a fluidic load such as an actuator.

Abstract: A fluidic device controls fluid flow in channel from a source to a drain. In some embodiments, the fluidic devices comprise a gate, a channel, and an obstruction. The gate comprises at least one chamber whose volume increases with fluid pressure. A high-pressure state of the gate corresponds to a first chamber size and a low-pressure state of the gate corresponds to a second chamber size that is smaller than the first chamber size. The obstruction controls a rate of fluid flow within the channel based on the fluid pressure in the gate. The obstruction induces at most a first flow rate of fluid in the channel in accordance with the low-pressure state of the gate, and at least a second flow rate of the fluid in the channel in accordance with the high-pressure state of the gate.

Abstract: Microfluidic devices may include a first inlet port for conveying a first fluid exhibiting a first pressure into the fluidic device, a second inlet port for conveying a second fluid exhibiting a second pressure into the fluidic device, an output port for conveying one of the first fluid or the second fluid out of the fluidic device, and a piston that is movable between a first position that inhibits fluid flow from the second inlet port to the output port and a second position that inhibits fluid flow from the first inlet port to the output port. Movement of the piston between the first and second positions may be determined by control pressure applied against a control gate of the piston. A flange of the piston may have an outer diameter of about 10 mm or less. Various other related methods and systems are also disclosed.

Abstract: A fluidic logic-gate device may include inlet ports, input ports, an output port, fluid channels each configured to route fluid from one of the inlet ports to the output port, and pistons that each include (1) a restricting gate transmission element configured to block, when the piston is in a first blocking position and unblock, when the piston is in a second blocking position, one of fluid channels, (2) a first controlling gate transmission element configured to interface with a first control pressure that, when applied to the first controlling gate transmission element, forces the piston towards the first blocking position, and (3) a second controlling gate transmission element configured to interface with a second control pressure that, when applied to the second controlling gate transmission element, forces the piston towards the second blocking position. Various other related devices and systems are also disclosed.

Abstract: A fluidic device may include inlet ports, control input ports, one or more output channels, inlet channels that are each configured to convey fluid from one of the inlet ports to one of the one or more output channels, and pistons. In some examples, each piston may include (1) a restricting gate transmission element configured to inhibit, when the piston is in a first position, and uninhibit, when the piston is in a second position, one of the inlet channels, (2) a control gate configured to interface with a first control pressure that, when applied to the control gate, forces the piston towards the first position, and (3) an additional control gate configured to interface with a second control pressure that, when applied to the additional control gate, forces the piston towards the second position. Various other related devices, systems, and methods are also disclosed.

Abstract: A fluidic haptic device includes a chamber, a compressible or incompressible fluid disposed within the chamber, and an actuatable element in hydraulic or pneumatic contact with the fluid. The actuatable element is adapted to be displaced by movement of a user of the device, which can apply pressure to the fluid. The haptic device may interact directly with one or more body parts of a user, including the user's skin, and may be operable without an external pressure source.

Abstract: A fluidic device may include inlet ports, input ports, one or more output ports, fluid channels each configured to route fluid from one of the inlet ports to one of the one or more output ports, and pistons. In some examples, each piston may include (1) a restricting gate transmission element configured to block, when the piston is in a first position, and unblock, when the piston is in a second position, one of the fluid channels, (2) a controlling gate transmission element configured to interface with a first control pressure that, when applied to the controlling gate transmission element, forces the piston towards the first position, and (3) an additional controlling gate transmission element configured to interface with a second control pressure that, when applied to the additional controlling gate transmission element, forces the piston towards the second position. Various other related devices and systems are also disclosed.

Abstract: The disclosed tactile input mechanisms may include a bladder dimensioned to hold a fluid, a pressure sensor coupled to the bladder and configured to sense a pressure exerted against the bladder, and a fluidic valve coupled to the bladder and configured to vent the bladder in response to the sensed pressure reaching a predetermined threshold. Various other related systems and methods are also disclosed.

Abstract: A fluidic latch device may include an input port, an additional input port, an output port, an additional output port, a pressure chamber, an additional pressure chamber, and a flexible membrane. The pressure chamber may include an inlet coupled to the input port by a first fluid channel and an outlet coupled to the output port by a second fluid channel, and the additional pressure chamber may include an additional inlet coupled to the additional input port by a third fluid channel and an additional outlet coupled to the additional output port by a fourth fluid channel. The flexible membrane may separate the pressure chamber and the additional pressure chamber and be configured to (1) block, when the membrane is in an expanded state, the outlet of the pressure chamber and (2) block, when the membrane is in an additional expanded state, the additional outlet of the additional pressure chamber.

Abstract: Example devices include a fluidic device, such as a fluidic valve, including a body formed from a rigid body material including a fluidic source, a fluidic drain, and a fluidic gate, each of which may have a fluid connection with a chamber, or a portion thereof. The device may further include a gate transmission element, located within the chamber, that is controllable between at least a first position and a second position using a gate pressure received through the fluidic drain. Adjustment of the position of the gate transmission element may allow control of fluid flow through the device. Other devices, methods, systems, and computer-readable media are also disclosed.

Abstract: A fluidic device may include inlet ports, control input ports, one or more output channels, inlet channels that are each configured to convey fluid from one of the inlet ports to one of the one or more output channels, and pistons. In some examples, each piston may include (1) a restricting gate transmission element configured to inhibit, when the piston is in a first position, and uninhibit, when the piston is in a second position, one of the inlet channels, (2) a control gate configured to interface with a first control pressure that, when applied to the control gate, forces the piston towards the first position, and (3) an additional control gate configured to interface with a second control pressure that, when applied to the additional control gate, forces the piston towards the second position. Various other related devices, systems, and methods are also disclosed.

Abstract: A method creates haptic stimulations on a user of an artificial reality system. The system includes a head-mounted display (HMD) and a wearable device. The HMD includes a display and speakers. The wearable device includes a plurality of transducers that can each generate waves to provide haptic feedback to a user. The system displays media content on the display and, in accordance with the displayed media content, determines a virtual object location in the displayed media content corresponding to a physical object location. The system provides, to the user, audio directed to the virtual object location. The system activates one or more transducers to provide haptic feedback at a target location on the user, distinct from the physical object location, to produce haptic feedback whose perceptual interpretation is at the physical object location based on a combination of the displayed media, the provided audio, and the haptic feedback.

Abstract: A method of creating localized haptic stimulations on a user includes a wearable device including a plurality of transducers that can each generate one or more waves that propagate away from the wearable device through a medium. The method includes activating two or more transducers of the plurality of transducers, selecting values for characteristics of waves to be generated by the two or more transducers based at least in part on a known impedance of the medium. The method further includes generating, by the two or more transducers, waves that constructively interfere at a target location to create a haptic stimulation on a user of the wearable device, the waves having the selected values.

Abstract: A fluidic device controls fluid flow in channel from a source to a drain. In some embodiments, the fluidic devices comprises a gate, a channel, and an obstruction. The gate comprises at least one chamber whose volume increases with fluid pressure. A high pressure state of the gate corresponds to a first chamber size and a low pressure state of the gate corresponds to a second chamber size that is smaller than the first chamber size. The obstruction controls a rate of fluid flow within the channel based on the fluid pressure in the gate. The obstruction induces at most a first flow rate of fluid in the channel in accordance with the low pressure state of the gate, and at least a second flow rate of the fluid in the channel in accordance with the high pressure state of the gate.