A projection device and a controlling method of the projection device are provided. The projection device includes a light emitting module, a driver, a light valve, a projection lens and a processor. The light emitting module generates a light beam according to a driving current respectively. The driver generates the driving current and transmit the driving current to the light emitting module according to an operating signal. The light valve receives the light beam to form an image light beam. The projection lens projects the image light beam. The processor provides the operating signal with a default period to the driver and provides an operation of the light valve. According to the operating signal or the operation of the light valve, the driver generates the driving current lower than a default current during a first time interval in the default period.

A light source module and a projection apparatus comprising the same are provided. The light source module comprises a light source unit, a light splitting element, and a condenser lens. The light source unit is configured to provide first color light beams including a first sub-light beam and a third sub-light beam, and second color light beams including a second sub-light beam and a fourth sub-light beam. The light source unit comprises a first light source unit to provide the first and second sub-light beams, and a second light source unit to provide the third and fourth sub-light beams. One of the first sub-light beam and the third sub-light beam is transmitted to the condenser lens after being reflected by the light splitting element, and the other of the first sub-light beam and the third sub-light beam is transmitted to the condenser lens after passing through the light splitting element.

A lens module includes a fixing seat, a moving assembly, a lens unit, a first sliding member, a first knob, and a first fixing member. The fixing seat has a first guide slot extended along a first axis. The moving assembly is disposed on the fixing seat and includes a first inclined surface. The lens unit is fixed to the moving assembly. The first sliding member is movably disposed on the fixing seat along a second axis and connected to the moving assembly, and the first sliding member includes a second inclined surface. The first knob is disposed on the fixing seat and connected to the first sliding member, and the first knob is configured to drive the first sliding member to move relative to the fixing seat. The first fixing member passes through the moving assembly and the first guide slot and is fixed on the fixing seat.

A projection apparatus includes a screen, a reel, a projection display structure and a control assembly. The projection display structure is configured to project at least one image to be displayed. Each image to be displayed includes an optical image with content. The screen is configured to display at least one optical image with content in the at least one image to be displayed. The control assembly is connected to the reel and is configured to control the reel to rotate. The reel is further connected to the screen and is configured to drive the screen to move when rotating. The control assembly is further connected to the projection display structure, and the control assembly is further configured to control the projection display structure to project the optical image with content in the image to be displayed onto an unfolded portion of the screen.

A novel projection system includes a light source, a phase modulator, an amplitude modulator, and a controller having temporal lightfield simulation capabilities. The phase modulator spatially modulates a lightfield from the light source to generate an intermediate image on the amplitude modulator. The amplitude modulator spatially modulates the intermediate image to form a final image. The controller models the phase state of the phase modulator during transitions between phase modulator frames and generates lightfield simulations of the intermediate image during the transition. The controller utilizes the lightfield simulations to generate and provide sets of amplitude drive values to the amplitude modulator at a faster rate than that at which the phase modulator is capable of switching.

An LCD projector optical system includes: an LED light source, a transflective plate, a condensing device, a first focusing lens, a polarization modulation plate, a brightness-increasing polarizing plate, an LCD light valve, a field lens, a reflector, and a projection lens, which are all arranged sequentially along a light travel direction; wherein the transflective plate has a light-transmitting portion and a reflecting portion. Light from the LED light source enters the condensing device from the light-transmitting portion, and then transmitted light and reflected light in illumination light are separated by the brightness-increasing polarizing plate. A beam of polarized light useless for the LCD light valve is reflected back and condensed by the first focusing lens and the condensing device on the reflection portion and the light-transmitting portion of the transflective plate, and then reflected back to the brightness-increasing polarizing plate through the reflection portion and the light-transmitting portion.

An optical engine module includes a housing, an assembling element, a light valve and a first heat exchange assembly. The assembling element has an opening corresponding to an assembly hole of the housing and is assembled on the housing in a non-direct contact mode. The light valve includes a base and an imaging element. The base bears against the assembling element, and an imaging surface of the imaging element faces the opening. The housing, the assembling element and the light valve define a chamber. The first heat exchange assembly is disposed on the assembling element and includes at least one first heat conduction component and a first heat dissipation fin set. The first heat dissipation fin set is located outside the housing. The first heat conduction component extends from the assembling element to the outside of the housing and is connected with the first heat dissipation fin set.

A projection system, a protection circuit and a current monitoring method of an image resolution enhancement device are provided. A light valve converts an illumination beam into an image beam. The image resolution enhancement device changes a transmission path of the image beam according to a driving current. The protection circuit detects the driving current. When the driving current is greater than or equal to a first current threshold, the protection circuit further compares the driving current with a second current threshold. When a duration time that the driving current is smaller than the second current threshold and greater than or equal to the first current threshold is greater than or equal to a time threshold, the protection circuit decreases the driving current to be smaller than the first current threshold to control the image resolution enhancement device. The projection lens converts the image beam into a projection beam.

A display system includes a projector configured to project first image light based on first image information onto a projection surface, a detecting device configured to detect whether a person is present on a path on which the first image light passes, and a control device configured to cause, when the detecting device detects that a person is present on the path, the projector to project, instead of the first image light, second image light based on second image information different from the first image information.

A projection system includes a first camera that captures an image of a projection surface, a second camera that is disposed in a position different from the position of the first camera and captures an image, a first light radiator that radiates light having a first optical characteristic onto the projection surface, a second light radiator that radiates light having a second optical characteristic different from the first optical characteristic onto the projection surface, and a detection section that detects a pointing element based on a first captured image captured with the first camera, detects another pointing element based on a second captured image captured with the second camera, and detects a position at which the pointing element is pointing and a position which is located on the projection surface and at which the other pointing element is pointing based on the first and second captured images.