Low-power always-on event-based vision sensor

What is claimed is: 1. An event-based vision sensor, comprising: an event-based vision sensor pixel array comprising: a plurality of always-on pixels; and a plurality of major pixels; an always-on row scanner and an always-on column scanner for the plurality of always-on pixels; and a major row scanner and a major column scanner for the plurality of major pixels, wherein when the event-based vision sensor is configured to be operated in an always-on mode, the plurality of major pixel are powered down, and the plurality of always-on pixels, the always-on row scanner and the always-on column scanner are in operation. 2. The event-based vision sensor according to claim 1 , wherein, when the event-based vision sensor is configured to be operated in the always-on mode, the major row scanner and the major column scanner are powered down. 3. The event-based vision sensor according to claim 1 , wherein, when the event-based vision sensor is configured to be operated in an activity mode, at least part of the plurality of major pixels are turned on and the major row scanner and the major column scanner are also turned on. 4. The event-based vision sensor according to claim 3 , further comprising a region-of-interest control for controlling the power of the plurality of major pixels. 5. The event-based vision sensor according to claim 4 , wherein the at least part of the plurality of major pixels are turned on based on the region-of-interest control. 6. The event-based vision sensor according to claim 5 , wherein, when the event-based vision sensor switches to the activity mode, the signal processor generates a valid row address and a valid column address to the region-of-interest control to indicate the at least part of the plurality of major pixels to be turned on. 7. The event-based vision sensor according to claim 4 , wherein the region-of-interest control comprises a row region-of-interest control and a column region-of-interest control. 8. The event-based vision sensor according to claim 3 , further comprising a signal processor, wherein, when the event-based vision sensor switches to the activity mode, the signal processor generates a valid trigger signal to the major row scanner and the major column scanner. 9. An image sensing apparatus, comprising: a hybrid pixel array comprising: a plurality of always-on event-based vision sensor pixels; and a plurality of CMOS image sensor (CIS) pixels an always-on row scanner and an always-on column scanner for the plurality of always-on pixels; and a CIS row scanner and a CIS column scanner for the plurality of CIS pixels, wherein, when the image sensing apparatus is configured to be operated in an always-on mode, the plurality of CIS pixels are powered down and the plurality of always-on event-based vision sensor pixels, the always-on row scanner and the always-on column scanner are in operation. 10. The image sensing apparatus according to claim 9 , wherein, when the image sensing apparatus is configured to be operated in the always-on mode, the CIS row scanner and the CIS column scanner are powered down. 11. The image sensing apparatus according to claim 9 , wherein, when the image sensing apparatus is configured to be operated in an activity mode, the at least part of the plurality of CIS pixels are turned on and the CIS row scanner and the CIS column scanner are also turned on. 12. The image sensing apparatus according to claim 11 , further comprising a region-of-interest control controlling the power of the plurality of CIS pixels. 13. A method for operating an event-based vision sensor comprising an event-based vision sensor pixel array, wherein the event-based vision sensor pixel array comprises a plurality of always-on pixels and a plurality of major pixels, the method comprising: when the event-based vision sensor is in an always-on mode: receiving, by a signal processor, first events detected by the plurality of always-on pixels; determining, by the signal processor, whether the received first events meet a first predefined threshold; and in response to determining the received first events meet the first predefined threshold, generating, by the signal processor, a valid trigger signal to turn on at least part of the plurality of major pixels and switching the event-based vision sensor to be in an activity mode. 14. The method according to claim 13 , further comprising: when the event-based vision sensor is in the activity mode: receiving, by the signal processor, second events detected by the at least part of the plurality of major pixels; determining, by the signal processor, whether the received second events meet a second predefined threshold; in response to determining the received second events meet the second predefined threshold, analyzing, by the signal processor, the second events; and in response to determining the received second events does not meet the second predefined threshold, generating, by the signal processor, an invalid trigger signal to power down the at least part of the plurality of major pixels and switching the event-based vision sensor to be in the always-on mode. 15. The method according to claim 14 , wherein analyzing the second events comprises analyzing shapes, detecting one or more objects or recognizing a human face. 16. The method according to claim 13 , further comprising a region-of-interest control for controlling the power of the plurality of major pixels. 17. The method according to claim 16 , wherein the at least part of the plurality of major pixels are turned on based on the region-of-interest control. 18. The method according to claim 17 , further comprising: when switching the event-based vision sensor to the activity mode, generating, by the signal processor, a valid row address and a valid column address to the region-of-interest control to indicate the at least part of the plurality of major pixels to be turned on. 19. The method according to claim 13 , further comprising: decoding, by a decoder, the first events before the first events are received by the signal processor. 20. The method according to claim 19 , wherein the event data of the first events is Raw data, and the event data of the decoded first events is human readable data.