Micro-electro-mechanical systems (MEMS) tactile display

What is claimed is: 1 . A tactile human-user interface system, the system comprising: an interface including a cover sheet configured to receive input from an electronic device, the input includes text and/or at least one image comprising objects; an image defeature filter configured to: defeature each image of the at least one image, wherein to defeature each image, the image defeature filter is configured to: determine that at least one object of the objects is unessential and remove the at least one unessential object from the at least one image to produce a simplified form of each of the at least one image of the input; a conversion engine configured to: responsive to defeaturing the at least one image, translate the input into a tactile form, and convert the tactile form into a set of electrical signals, such that the set of electrical signals is associated with a set of pixels; and a set of transducers arranged below the cover sheet of the interface, each transducer or a subset of the set of transducers corresponding to a respective pixel of the set of pixels, and the set of transducers is configured to: receive, from the conversion engine, the set of electrical signals, and generate, in response to the set of electrical signals, outputs detectable by a finger of a human user at the cover sheet, at locations corresponding to the respective pixel of the set of pixels, wherein alternating pixels in the set of pixels are configured to be actuated with waveforms that are 180° out of phase, so as to reduce the outputs by 20-40 dB for quiet operation of the system, compared to actuating each of the set of pixels with the same phase. 2 . The system according to claim 1 , wherein the system comprises a micro-electro-mechanical system (MEMS). 3 . The system according to claim 1 , wherein the electronic device comprises a computing device that provides the input from data retrieved and/or displayed by the computing device, the computing device including a tablet, mobile phone, laptop computer, or personal computer. 4 . The system according to claim 1 , wherein the electronic device comprises a device that captures the input from surroundings of the user, including a camera, a scanner, or a LIDAR. 5 . The system according to claim 1 , wherein the image defeature filter is configured to defeature an image in the input by (i) enhancing edges of the image, (ii) converting objects in the image to iconic form, (iii) sorting objects in the image by proximity or range, and/or (iv) removing details from objects in the image to create an outline of the objects. 6 . The system according to claim 1 , wherein the tactile form comprises Braille or a tactile pattern. 7 . The system according to claim 6 , wherein for the image, the conversion engine is configured to code the tactile pattern into the set of electrical signals by modulating at multiple frequencies, modulating at multiple amplitudes, or double modulation. 8 . The system according to claim 7 , wherein the electrical signals represent (i) distance, (ii) proximity, and/or (iii) color. 9 . The system according to claim 1 , wherein the outputs are vibration, pressure, or bi-static displacement. 10 . The system according to claim 1 , wherein the outputs have a frequency of about 250 Hz. 11 . The system according to claim 1 , wherein an audio circuit coupled to the conversion engine is configured to generate the speech output corresponding to the outputs. 12 . The system according to claim 1 , wherein the set of transducers function as a directional speaker that projects generated speech output to ears of the user. 13 . The system according to claim 1 , wherein the outputs are configured to provide a tactile navigation display to the human user. 14 . The system according to claim 1 , wherein the set of transducers comprises an array of capacitive micro-machined transducers (cMUTs), such that each cMUT or a sub-array of the array of cMUTs corresponds to a respective pixel of the set of pixels. 15 . The system according to claim 14 , wherein each cMUT includes an electret layer, which is configured either: (i) over a bottom conductive electrode of the cMUT, (ii) as part of a membrane layer of the cMUT, or (iii) as a porous layer between the bottom conductive electrode and a top conductive electrode of the cMUT. 16 . The system according to claim 14 , wherein each cMUT defines a ventilation through hole. 17 . The system according to claim 14 , wherein each cMUT comprises a boss. 18 . The system according to claim 1 , wherein: each transducer is configured to detect a capacitance level at a corresponding pixel of the set of pixels, the capacitance level being caused by the finger of the human user touching a location corresponding to the pixel; and the system further comprises: a differential capacitance readout circuit is configured to compare the capacitance level at the pixel with (i) capacitance levels at adjacent pixels or (ii) a threshold value, and determine input provided by the human user at the pixel. 19 . The system according to claim 18 , wherein a transducer is further configured to activate the outputs at the respective pixel of the set of pixels, in response to the detected capacitance level at the pixel. 20 . The system according to claim 1 , wherein the set of transducers comprises an array of electromagnetic actuators, such that each electromagnetic actuator or a sub-array of the array of actuators corresponds to the respective pixel of the set of pixels. 21 . The system according to claim 20 , wherein: the array of electromagnetic actuators are positioned above a magnetic material formed to concentrate flux and/or achieve bi-stability, and each electromagnetic actuator includes: (i) a permanent magnet and (ii) a coil, such that an electrical signal drives each electromagnetic actuator by causing the permanent magnet and/or the coil to vibrate. 22 . The system according to claim 21 , wherein the array of electromagnetic actuators has a pressure switch configured to detect pressure by the finger of the user at a pixel of the set of pixels, and in response, activate the outputs at a location corresponding to the pixel. 23 . The system according to claim 1 , wherein the set of transducers comprises an array of piezoelectric micro-machined transducers (pMUTs), such that each pMUT or a sub-array of the array of pMUTs corresponds a respective pixel of the set of pixels. 24 . The system according to claim 1 , wherein the set of transducers is formed into a thin device layer that fits over a screen of a computing device, including a cell phone, tablet, laptop, or personal computer. 25 . The system according to claim 1 , wherein the set of transducers is configured as part of a glove worn by the human user. 26 . A tactile human-user interface system, the system comprising: an interface including a cover sheet configured to receive images from a processor; an image defeature filter configured to defeature the images to produce a simplified form of the images; a conversion engine configured to: translate the input into a tactile form, and convert the tactile form into a set of electrical signals associates with a set of pixels; and a set of transducers arranged below the cover sheet of the interface, each of the transducers corresponding to a respective one of the set of pixels, the