Analog input device, computing system and method for receiving and processing analog input

What is claimed is: 1. An analog input device comprising: at least one mounting panel; a matrix of analog push button assemblies mounted to the at least one mounting panel, each analog push button assembly comprising an analog pressure sensor, wherein the analog pressure sensor comprises: a pressure reception arrangement having an optical sensing sub-arrangement configured to measure an amount of light varied according to a pressure sensed at the pressure reception arrangement and an output terminal for outputting an analog signal corresponding to the amount of light measured, and a plunger element configured to exert the pressure on the pressure reception arrangement when the analog push button assembly is pressed by a user's finger; a multiplexer including an input side and an output side, wherein the input side is coupled to the output terminals of the matrix of analog push button assemblies; an analog-to-digital converter which is coupled to the output side of the multiplexer; a processor which is coupled to the analog-to-digital converter and which is configured to output a data packet including a button identity (ID) of the push button assembly pressed by the user's finger and a digital-step-value corresponding to the analog signal from the push button assembly; a communication interface configured to transmit the data packet to a host computing device; and a lighting arrangement including a plurality of light sources respectively associated with the matrix of analog push button assemblies in a manner so as to individually illuminate each of the matrix of analog push button assemblies, wherein the plurality of light sources is lit based on the digital-step-value corresponding to the analog signal from the push button assembly pressed by the user's finger such that a number of light sources among the plurality of light sources to be lit is proportional to the digital-step-value. 2. The input device as claimed in claim 1 , wherein the pressure reception arrangement comprises a biasing element which is arranged between the plunger element and the at least one mounting panel and which biases the plunger element away from the at least one mounting panel in a biasing direction. 3. The input device as claimed in claim 2 , wherein the optical sensing sub-arrangement comprises: a light emitter which is disposed at an intermediate level between the plunger element and the at least one mounting panel and which is oriented to emit light along a light path perpendicular to a biasing direction of the biasing element; a light sensor which is disposed in the light path and which is configured to generate the analog signal based on the amount of light sensed by the light sensor for outputting via the output terminal; and a light blocking element which is associated with the plunger element in a manner so as to be movable together with the plunger element along a movement direction parallel to the biasing direction and which is extending towards the mounting panel to intersect the light path between the light emitter and the light sensor, wherein the light blocking element comprises a cut-out profile which varies the amount of light passing through the light blocking element as the light blocking element moves transversely across the light path when the plunger element is moved towards the at least one mounting panel. 4. A computing system for receiving and processing analog input, the computing system comprising: a host processor; and an analog input device connected to the host processor, wherein the analog input device comprises: at least one mounting panel, a matrix of analog push button assemblies mounted to the at least one mounting panel, each analog push button assembly comprising an analog pressure sensor, wherein the analog pressure sensor comprises: a pressure reception arrangement having an optical sensing sub-arrangement configured to measure an amount of light varied according to a pressure sensed at the pressure reception arrangement and an output terminal for outputting an analog signal corresponding to the amount of light measured, and a plunger element configured to exert the pressure on the pressure reception arrangement when the analog push button assembly is pressed by a user's finger, a multiplexer including an input side and an output side, wherein the input side is coupled to the output terminals of the matrix of analog push button assemblies, an analog-to-digital converter which is coupled to the output side of the multiplexer, a processor which is coupled to the analog-to-digital converter and which is configured to output a data packet including a button identity (ID) of the push button assembly pressed by the user's finger and a digital-step-value corresponding to the analog signal from the push button assembly, and a communication interface connecting the processor of the analog input device to the host processor to transmit the data packet to the host processor, wherein the host processor is configured to receive the data packet from the analog input device, to determine an amount of depression of the push button assembly based on the digital-step-value corresponding to the analog signal from the push button assembly, and to generate a corresponding predetermined application event in an application based on the determined amount of depression of the push button assembly and an input setting for the application, wherein the analog input device further comprises a plurality of light sources respectively associated with the matrix of analog push button assemblies in a manner so as to individually illuminate each of the matrix of analog push button assemblies, wherein the plurality of light sources is lit based on the digital-step-value corresponding to the analog signal from the push button assembly pressed by the user's finger such that a number of light sources among the plurality of light sources to be lit is proportional to the digital-step-value. 5. The computing system as claimed in claim 4 , wherein the host processor is further configured to transform the determined amount of depression onto a non-linear scale prior to generating the corresponding predetermined application event. 6. The computing system as claimed in claim 4 , wherein the corresponding predetermined application event comprises a continuous variable action, and wherein the host processor is configured to generate a state of the continuous variable action according to the determined amount of depression; or wherein the corresponding predetermined application event comprises a discrete action, and wherein the host processor is configured to generate the discrete action when the determined amount of depression is equal to or greater than a pre-set depression level; or wherein the corresponding predetermined application event comprises a first discrete action and a second discrete action, and wherein the host processor is configured to generate the first discrete action when the determined amount of depression is equal to a first pre-set depression level or between the first pre-set depression level and a second pre-set depression level, and to generate the second discrete action when the determined amount of depression is equal to or greater than the second pre-set depression level. 7. The computing system as claimed in claim 4 , wherein the host processor is configured to toggle between a first input setting and a second input setting for the application based on a user input command via a physical modifier key or a virtual modifier key, and wherein a first corresponding predetermined application event associated with the first input setting is different from a second corresponding predetermined application event associated with the second input setting.