Abstract: An optical path folding element includes a main body, a light absorption film layer and a matte structure. The main body has optical surface including an incident surface, a reflective surface and an emitting surface. A light enters into the optical folding element through the incident surface. The reflective surface reflects the light so as to change a traveling direction thereof. The light exits the optical folding element through the emitting surface. The light absorbing film layer is configured to reduce reflectance and provided adjacent to at least part of the optical surface, and the light absorbing film layer is in physical contact with the main body. The matte structure is disposed adjacent to at least part of the optical surface. The matte structure provides an undulating profile on a surface of the optical path folding element, and the matte structure is formed in one-piece with the main body.

Abstract: An imaging lens module includes a plastic lens barrel, a first optical element assembly and a second optical element assembly, wherein both of the first optical element assembly and the second optical element assembly are disposed in the plastic lens barrel. The plastic lens barrel includes a first inner annular surface and a second inner annular surface. The first inner annular surface forms a first receiving space. The second inner annular surface forms a second receiving space. The first optical element assembly is disposed in the first receiving space and includes a plurality of optical lens elements and a first retainer. The second optical element assembly is disposed in the second receiving space and includes a first light blocking sheet and a second retainer.

Abstract: A driving event recording method and system for non-image-based car accident cause determination are disclosed. The system includes an external-event determination unit, an internal-driving-behavior-event determination unit, and a processor electrically connected to both determination units. The method is carried out as follows. The external-event determination unit generates information about an external event, and at the same time the internal-driving-behavior-event determination unit generates information about an internal driving behavior event. The processor receives the external-event information and the internal-driving-behavior-event information and uploads both pieces of information to a cloud storage space in a text or program code format for storage in a blockchain.

Abstract: An embodiment of the invention provides a power saving method for an electronic device with positioning function. The method includes steps of acquiring a positioning cycle of the electronic device; estimating power consumptions corresponding to at least two operating modes during the positioning cycle; and choosing an operating mode with minimum power consumption from the at least two operating modes to be the operating mode of the electronic device during the positioning cycle.

Abstract: A method of determining affirmative and negative response areas in a cerebral cortex of a human subject under a test, comprises (A) providing a testing apparatus to detect real-time variations in cerebral blood flow, (B) generating a test array consisting of a plurality of test points in a tested area of the subject's head to detect real-time variations of the cerebral blood flow in the tested area, wherein the tested area approximately corresponds to an affirmative or negative response area in the cortex; (C) asking a question to the human subject, wherein the question is designed so that an answer for the question is either yes or no; and (D) determining a precise position of the affirmative or negative response area in the cortex, according to an active region corresponding to the real-time variations of the cerebral blood flow generated in 3 seconds within the tested area after answering.

Abstract: A method of detecting a suicide terrorist, comprises: (A) selecting a test subject; (B) installing a testing device that can detect real-time variations in cerebral blood flows at a first tested area and second tested area of the subject, wherein the first tested area corresponds to a suicide intent area of a cortex, and the second tested area corresponds to a negative response area of the cortex; (C) using the testing device to detect cortex activity information related to the cerebral blood flow variations of the first tested area within a predetermined time; (D) comparing the cortex activity information with a control group associated with normal individuals to obtain a result; (E) according to the result of step (D), determining whether the subject has suicide intent; (F)asking whether the subject is a terrorist; (G) using the testing device to detect a cortex activity information related to the cerebral blood flow variations of the second tested area within a predetermined time to obtain a result; and (H

Abstract: A method of determining affirmative and negative response areas in a cerebral cortex of a human subject under a test, comprises (A) providing a testing apparatus to detect real-time variations in cerebral blood flow, (B) generating a test array consisting of a plurality of test points in a tested area of the subject's head to detect real-time variations of the cerebral blood flow in the tested area, wherein the tested area approximately corresponds to an affirmative or negative response area in the cortex; (C) asking a question to the human subject, wherein the question is designed so that an answer for the question is either yes or no; and (D) determining a precise position of the affirmative or negative response area in the cortex, according to an active region corresponding to the real-time variations of the cerebral blood flow generated in a predetermined time within the tested area after answering.