Microfluidic devices and fluidic logic devices

What is claimed is: 1 . A microfluidic device comprising: a first inlet port configured to convey a first fluid exhibiting a first pressure into the fluidic device; a second inlet port configured to convey a second fluid exhibiting a second pressure into the fluidic device; an output port that is configured to convey 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 through the second inlet port to the output port and a second position that inhibits fluid flow through the first inlet port to the output port, wherein movement of the piston between the first and second positions is determined by control pressure applied against a control gate of the piston, wherein a flange of the piston has an outer diameter of about 10 mm or less. 2 . The microfluidic device of claim 1 , wherein the first fluid and the second fluid comprise at least one of a gas, air, or a liquid. 3 . The microfluidic device of claim 1 , wherein the piston comprises at least one of rubber, a polymer, nitrile, or silicone. 4 . The microfluidic device of claim 1 , wherein the piston is configured in at least one of: a biased down configuration; a biased up configuration; a biased center configuration; or a high gain configuration. 5 . The microfluidic device of claim 1 , wherein the first inlet port, the second inlet port, and the gate provide fluidic input signals and a fluidic output signal is provided at the outlet port, and wherein the microfluidic device is configured as at least one of the following: a buffer; an inverter; an OR gate; or an AND gate. 6 . The microfluidic device of claim 1 , wherein the microfluidic device comprises a plurality of microfluidic devices and the plurality of microfluidic devices are configured as at least one of: a demultiplexer; a full adder; a row-column buffered latch decoder; a row-column demultiplexer; a row-column inverted latch decoder; or a row-column inverted demultiplexer. 7 . The microfluidic device of claim 1 , wherein the microfluidic device comprises a first fluidic device and a second fluidic device configured as at least one of: a NOR gate; a NAND gate; an XOR gate; or an XNOR gate. 8 . The microfluidic device of claim 1 , wherein: the microfluidic device comprises a first fluidic device and a second fluidic device that are together configured as an XOR gate; the first fluidic device comprises: a first source port; a first drain port; a first gate port; a first output; and a first valve element for switching flow from the first source port between the first drain port and the first output; and the second fluidic device comprises: a second source port; a second drain port; a second gate port; a second output; and a second valve element for switching flow from the second source port between the second drain port and the second output; the first source port is connected to a high-pressure source; the first drain port is connected to a low-pressure source; the first output is connected to the second drain port; the first gate port is connected to the second source port; when the high-pressure source is connected to the first gate port or the second gate port, the high-pressure source is connected to the second output; and when the high-pressure source is connected to the first gate port and the second gate port or the low-pressure source is connected to the first gate port and the second gate port, the low-pressure source is connected to the second output. 9 . The microfluidic device of claim 1 , wherein at least one of the first fluid or the second fluid is supplied from a peizoelectric valve. 10 . The microfluidic device of claim 9 , wherein the peizoelectric valve comprises first and second peizoelectric actuators configured as cantilevered beams wherein: the first peizoelectric actuator is configured to control flow of one of the first fluid or the second fluid through a source port; the second peizoelectric actuator is configured to control flow of one of the first fluid or the second fluid through a drain port; and the first and second peizoelectric actuators are configured to be simultaneously actuated in a same direction. 11 . The microfluidic device of claim 9 , wherein the peizoelectric valve is configured to: be electrically actuated; and provide an interface between an electronic control system and the microfluidic device. 12 . The microfluidic device of claim 1 , wherein the microfluidic device is configured to convey at least one of the first fluid or the second fluid to a fluid chamber. 13 . The microfluidic device of claim 1 , wherein: the microfluidic device comprises a first fluidic device and a second fluidic device; and the first fluidic device and the second fluidic device are configured as a push-pull fluid amplifier. 14 . The microfluidic device of claim 13 , wherein: a base port of the first fluidic device is connected to a pressure source; a base port of the second fluidic device is connected to a pressure drain; an output port of the first fluidic device is connected to a fluid chamber; an output port of the second fluidic device is connected to the fluid chamber; a gate port of the first fluidic device is connected to a variable pressure input; a gate port of the second fluidic device is connected to the variable pressure input; and the fluidic device is configured to mirror the variable pressure input in the fluid chamber. 15 . The microfluidic device of claim 14 , wherein a fluid flow rate in the fluid chamber is higher than a fluid flow rate in the gate port of the first fluidic device and the gate port of the second fluidic device. 16 . The microfluidic device of claim 14 , wherein the variable pressure input is provided by a linearized variable pressure regulator device. 17 . The microfluidic device of claim 1 , wherein: at least one of the first inlet port or the second inlet port is connected to a linearized variable pressure regulator device; the linearized variable pressure regulator device comprises a plurality of flow restrictors; each of the flow restrictors comprises a different diameter orifice; and the plurality of flow restrictors are configured to create the linearized variable pressure regulator device. 18 . The microfluidic device of claim 1 , wherein: the microfluidic device is configured to control a flow of fluid to an inflatable bladder in a glove; and the bladder in the glove is configured to provide haptic feedback to a user in association with an artificial-reality application. 19 . A fluidic logic-gate device, comprising: an input port; n select ports; a drive input port; 2 n output ports; 2 n control gates respectively coupled to the output ports; fluid channels configured to route fluid from the input port to the control gates; and select pistons each comprising a gate element fluidically coupled to one of the select ports and configured to, when at a first pressure state, block a first one of the fluid channels and unblock a second one of the fluid channels, and, when at a second pressure state, unblock the first one of the fluid channels and block the second one of the fluid channels, wherein each combination of the first pressure state and the second pressure state on the select ports opens a unique fluid route from the input port to a selected one of the control gates to transmit a state of the drive input port