MEMS actuated vibratory Risley prism for LiDAR

What is claimed is: 1. An optical sensing system, comprising: a laser emitter, configured to sequentially emit a series of optical signals; a plurality of prisms, configured to receive the series of optical signals and sequentially direct the series of optical signals at different directions in an angle of view of the optical sensing system, wherein at least one prism of the plurality of prisms is configured to rotate relative to at least one other prism of the plurality of prisms to refract the optical signals towards the respective different directions; a plurality of micro-electromechanical system (MEMS)-based angular comb drive actuators configured to individually rotate each prism, wherein the plurality of MEMS-based angular comb drive actuators are circularly mounted around an outer edge of a respective ring-shaped mounting structure corresponding to one prism in the plurality of prisms, and each prism is fixedly mounted around an inner edge of its respective ring-shaped mounting structure such that its surface upon which the series of optical signals impinge is parallel to a plane formed by the inner edge of its respective ring-shaped mounting structure, wherein each MEMS-based angular comb drive actuator comprises a set of stationary teeth, a set of rotary teeth, a first stationary anchor, an elongated beam, a single spring structure, and a second stationary anchor, the set of stationary teeth are coupled to the first stationary anchor, the set of rotary teeth are coupled to a first side of the elongated beam, the elongated beam comprises a first end coupled to the outer edge of its ring-shaped mounting structure and a second end coupled to the second stationary anchor via the single spring structure, the single spring structure is the only spring structure coupled to the elongated beam, and a direction normal to the plane in which the single spring structure provides compliance is parallel to a center axis around which its corresponding ring-shaped mounting structure rotates; and a receiver, configured to receive at least a portion of the series of optical signals reflected from an environment surrounding the optical sensing system. 2. The optical sensing system of claim 1 , where each of the plurality of prisms is configured to rotate independently from each other around a rotation axis aligned with a light path of the series of optical signals. 3. The optical sensing system of claim 1 , wherein each MEMS-based angular comb drive actuator comprises a stationary angular comb formed from the set of stationary teeth and the first stationary anchor and a movable angular comb formed from the set of rotary teeth and the elongated beam. 4. The optical sensing system of claim 3 , wherein radial movements of movable angular comb of the plurality of MEMS-based angular comb drive actuators collectively rotate the respective ring-shaped mounting structure and the corresponding prism inside the respective ring-shaped mounted structure. 5. The optical sensing system of claim 3 , wherein each of the set of stationary teeth and the set of rotary teeth comprise a respective set of arc-shaped teeth. 6. The optical sensing system of claim 1 , wherein the at least one of the plurality of prisms is configured to rotate according to a predefined pattern determined according to the different directions. 7. The optical sensing system of claim 6 , wherein the predefined pattern specifies, for each different direction, a relative rotation angle between the at least one prism and the at least one other prism. 8. The optical sensing system of claim 1 , wherein the plurality of prisms are Risley prisms. 9. An optical sensing method for an optical sensing system, comprising: sequentially emitting, by a laser emitter, a series of optical signals; directing, by a plurality of prisms, the series of optical signals at different directions in an angle of view of the optical sensing system by rotating at least one prism of the plurality of prisms relative to at least one other prism of the plurality of prisms to refract the optical signals towards the respective different directions, wherein a plurality of micro-electromechanical system (MEMS)-based angular comb drive actuators individually rotate each prism, wherein the plurality of MEMS-based angular comb drive actuators are circularly mounted around an outer edge of a respective ring-shaped mounting structure corresponding to one prism in the plurality of prisms, and each prism is fixedly mounted around an inner edge of its respective ring-shaped mounting structure such that its surface upon which the series of optical signals impinge is parallel to a plane formed by the inner edge of its respective ring-shaped mounting structure, wherein each MEMS-based angular comb drive actuator comprises a set of stationary teeth, a set of rotary teeth, a first stationary anchor, an elongated beam, a single spring structure, and a second stationary anchor, the set of stationary teeth are coupled to the first stationary anchor, the set of rotary teeth are coupled to a first side of the elongated beam, the elongated beam comprises a first end coupled to the outer edge of its ring-shaped mounting structure and a second end coupled to the second stationary anchor via the single spring structure, the single spring structure is the only spring structure coupled to the elongated beam, and a direction normal to the plane in which the single spring structure provides compliance is parallel to a center axis around which its corresponding ring-shaped mounting structure rotates; and receiving, by a receiver of the optical sensing system, at least a portion of the series of optical signals reflected from an environment surrounding the optical sensing system. 10. The optical sensing method of claim 9 , wherein, when directing the series of optical signals at different directions, the at least one of the plurality of prisms rotationally move according to a predefined pattern. 11. A prism-based scanning mechanism, comprising: a plurality of prisms; a ring-shaped mounting structure surrounded by each of the plurality of prisms; a plurality of MEMS-based angular comb drive actuators circularly mounted around an outer edge of the ring-shaped mounting structure corresponding to one prism in the plurality of prisms, and each prism is fixedly mounted around an inner edge of its respective ring-shaped mounting structure such that its surface upon which a series of optical signals impinge is parallel to a plane formed by the inner edge of its respective ring-shaped mounting structure, wherein each MEMS-based angular comb drive actuator comprises a set of stationary teeth, a set of rotary teeth, a first stationary anchor, an elongated beam, a single spring structure, and a second stationary anchor, the set of stationary teeth are coupled to the first stationary anchor, the set of rotary teeth are coupled to a first side of the elongated beam, the elongated beam comprises a first end coupled to the outer edge of its ring-shaped mounting structure and a second end coupled to the second stationary anchor via the single spring structure, the single spring structure is the only spring structure coupled to the elongated beam, and a direction normal to the plane in which the single spring structure provides compliance is parallel to a center axis around which its corresponding ring-shaped mounting structure rotates; and at least one controller coupled to the plurality of MEMS-based angular comb drive actuators to control a rotation of each of the plurality of prisms. 12. The prism-based scanning mechanism of claim 11 , wherein each of the set of stationary teeth and the set of rotary teeth include a re