Sensing apparatus, artificial skin, method of detecting touch, and sensor

What is claimed is: 1. A sensing apparatus, comprising: a base substrate; a plurality of sensing units on the base substrate, a respective one of the plurality of sensing units comprising a first component and a second component; an elastic layer on a side of the plurality of sensing units distal to the base substrate and configured to undergo a deformation upon a touch; switches configured to, during a first period of the touch, control the first component to emit light, the second component to detect light reflected by a surface of the elastic layer, and output a first sensing signal, and, during a second period of the touch, control the second component to emit light, the first component to detect light reflected by the surface of the elastic layer, and output a second sensing signal; a processor configured to receive the first sensing signal and the second sensing signal, and determine a degree of the deformation of the elastic layer at each local position based on the first sensing signal and the second sensing signal; an input voltage signal line; a first output voltage signal line; a reference voltage signal line; a ground voltage signal line; a first selector switch configured to selectively couple a first terminal of the first component to one of the input voltage signal line or the first output voltage signal line; a second selector switch configured to selectively couple a second terminal of the first component to one of the reference voltage signal line or the ground voltage signal line; a third selector switch configured to selectively couple a first terminal of the second component to one of the input voltage signal line or the first output voltage signal line; and a fourth selector switch configured to selectively couple a second terminal of the second component to one of the reference voltage signal line or the ground voltage signal line. 2. The sensing apparatus of claim 1 , further comprising a reflective layer on a side of the elastic layer distal to the base substrate, and configured to block light emitted from the first component or the second component from emitting out of the elastic layer. 3. The sensing apparatus of claim 1 , further comprising: a memory configured to store a plurality of reference sensing signals corresponding to different degrees of deformation; and wherein the processor is configured to compare the first sensing signal and the second sensing signal with the plurality of reference sensing signals, and determine the degree of the deformation of the elastic layer at each local position based on a result of comparing. 4. The sensing apparatus of claim 1 , wherein the respective one of the plurality of sensing units further comprises a third component; wherein the sensing apparatus further comprises a second output voltage signal line; a fifth selector switch configured to selectively couple a first terminal of the third component to one of the input voltage signal line or the second output voltage signal line; and a sixth selector switch configured to selectively couple a second terminal of the third component to one of the reference voltage signal line or the ground voltage signal line; wherein the third component is configured to detect light when a voltage level at the second terminal of the third component is higher than a voltage level at the first terminal of the third component to generate a photocurrent flowing from the second terminal of the third component to the first terminal of the third component. 5. The sensing apparatus of claim 1 , wherein a total number of components in the respective one of the plurality of sensing units configured to emit light is one and a total number of components in the respective one of the plurality of sensing units configured to detect light is two. 6. The sensing apparatus of claim 1 , wherein the first component is a light emitting diode and the second component is a photodiode. 7. The sensing apparatus of claim 1 , wherein the first component is a photodiode and the second component is a photodiode. 8. The sensing apparatus of claim 1 , wherein the elastic layer comprises an elastic resin material. 9. A sensing apparatus, comprising: a base substrate; a plurality of sensing units on the base substrate, a respective one of the plurality of sensing units comprising a first component and a second component; an elastic layer on a side of the plurality of sensing units distal to the base substrate and configured to undergo a deformation upon a touch; switches configured to, during a first period of the touch, control the first component to emit light, the second component to detect light reflected by a surface of the elastic layer, and output a first sensing signal, and, during a second period of the touch, control the second component to emit light, the first component to detect light reflected by the surface of the elastic layer, and output a second sensing signal; and a processor configured to receive the first sensing signal and the second sensing signal, and determine a degree of the deformation of the elastic layer at each local position based on the first sensing signal and the second sensing signal; wherein, during the first period of the touch, the switches are configured to control a voltage level at a first terminal of the first component to be higher than a voltage level at a second terminal of the first component to generate a first current flowing from the first terminal of the first component to the second terminal of the first component, thereby controlling the first component to emit light, and control a voltage level at a second terminal of the second component to be higher than a voltage level at a first terminal of the second component to generate a first photocurrent flowing from the second terminal of the second component to the first terminal of the second component, thereby controlling the second component to detect light reflected by the surface of the elastic layer and output a first sensing signal; wherein, during the second period of the touch, the switches are configured to control a voltage level at the first terminal of the second component to be higher than a voltage level at the second terminal of the second component to generate a second current flowing from the first terminal of the second component to the second terminal of the second component, thereby controlling the second component to emit light, and control a voltage level at the second terminal of the first component to be higher than a voltage level at the first terminal of the first component to generate a second photocurrent flowing from the second terminal of the first component to the first terminal of the first component, thereby controlling the first component to detect light reflected by the surface of the elastic layer and output a second sensing signal. 10. An artificial skin, comprising: a flexible base substrate; a plurality of sensing units on the flexible base substrate, a respective one of the plurality of sensing units comprising a first component and a second component; an elastic layer on a side of the plurality of sensing units distal to the flexible base substrate and configured to undergo a deformation upon a touch; switches configured to, during a first period of the touch, control the first component to emit light, the second component to detect light reflected by a surface of the elastic layer, and output a first sensing signal, and, during a second period of the touch, control the second component to emit light, the first component to detect light reflected by the surface of the elastic layer, and output a second sensing signal; a processor configured to receive the first sensing signal and