The specification relates generally to image projection systems, and specifically to a system and apparatus for dynamically distributing light between a plurality of projectors.
Projectors with independent light sources (that is, uncorrelated light sources) can be difficult to match in brightness and colorimetry. As a result, images projected by such projectors can appear mismatched. This can become particularly problematic in implementations where the projected images are in tiled arrangements, because mismatches in brightness and colorimetry can become very apparent to viewers due to the close physical proximity of the images. In addition, variations in brightness and contrast needs for the various projectors can be difficult to satisfy, thus negatively impacting the quality of the projected images.
According to an aspect of the specification, a dynamically adjustable light distribution apparatus is provided, comprising: a source conduit having a first end and a second end, and configured to collect light at the first end from a light source and transmit the collected light for emission at the second end; an optical switch switchable between a plurality of discrete resting states each corresponding to a different one of a plurality of projector conduits; the optical switch configured, in each one of the discrete resting states, to direct the light emitted from the source conduit to a corresponding one of the projector conduits; each projector conduit configured to receive the directed light from the optical switch and transmit the directed light to a corresponding one of a plurality of projectors; the optical switch further configured, in a period of time, to rest at each of the discrete resting states for respective portions of the period of time, to regulate what amount of the light emitted by the source conduit during the period of time is received by each projector conduit.
According to another aspect of the specification, a computing device is provided, comprising: a memory; a communications interface connecting the computing device to an optical switch having a plurality of discrete resting states, each resting state for directing light emitted from a light source to a corresponding one of a plurality of projectors; and a processor interconnected with the memory and the communications interface, and configured to: retrieve light distribution settings from the memory, the light distribution settings specifying portions of a total output of the light source to be directed to each of the plurality of projectors; determine, based on the portions, operational parameters for the optical switch; and control the optical switch to direct light to the projectors according to the portions by transmitting the operational parameters to the optical switch via the communications interface.
Embodiments are described with reference to the following figures, in which:
Specifically, system 100 includes an apparatus for distributing light emitted by a light source 104 between a plurality of projectors 108-1, 108-2 (referred to collectively as projectors 108, and generically as a projector 108). Although two projectors 108 are shown, it is contemplated that more than two projectors can also be provided.
The nature of light source 104 and projectors 108 are not particularly limited. Light source 104 can thus be any suitable light source, such as a xenon arc lamp, a laser light source, a Light Emitting Diode (LED) light source, or the like. Light source 104 can also include more than one of the above-mentioned sources, or a combination of such sources. Each one of projectors 108-1 and 108-2, meanwhile, can be any of a wide variety of projector types, albeit without internal light sources of their own. For example, projectors 108 can be any one of, or any suitable combination of, a liquid crystal display (LCD) projector, a digital light processing (DLP) projector or the like.
The apparatus for distributing light from light source 104 between projectors 108 includes a source conduit 112 with a first end 114 and a second end 116. First end 114 of conduit 112 is positioned so as to collect light 120 emitted by light source 104, and conduit 112 transmits the collected light for emission, as emitted light 124, at second end 116. Conduit 112 can be, for example, a fibre optic line (e.g. a bundle of optical fibres) of any suitable length, and can include any necessary optics at first end 114 for collecting light from light source 104. Alternatively, such optics (e.g. a focusing lens) can be included in light source 104. In some embodiments, rather than a bundle of fibres, conduit 112 can be a single solid rod, a hollow rod, or a channel of air.
The light emitted by source conduit 112 is received by an optical switch 128. In the present example, before being received by optical switch 128, emitted light 124 passes through a collimator 132 to collimate emitted light 124. Additional optical elements can be included between second end 116 and collimator 132, or between collimator 132 and optical switch 128, or both. For example, such additional optical elements can include filters, integrator rods, relay lenses, and the like. Collimator 132 and any additional optical elements can be omitted in some embodiments.
As will be discussed in greater detail below, having received the light emitted from source conduit 112, optical switch 128 directs the light to a plurality of projector conduits each corresponding to one of projectors 108. Thus, in the present example, optical switch 128 directs the light to a first projector conduit 136-1 corresponding to projector 108-1, and to a second projector conduit 136-2 corresponding to projector 108-2. As will become apparent in the detailed discussion of optical switch 128 to follow, in the present example optical switch 128 does not direct light to both projector conduits 136 simultaneously, but instead directs light to one projector conduit 136 at a time. Certain other example embodiments, as will be discussed later herein, are capable of simultaneously directing light to more than one projector conduit.
Projector conduits 136-1 and 136-2 (referred to collectively as projector conduits 136, and generically as a projector conduit 136) can be fibre optic lines of any suitable lengths (projector conduit 136-1 need not have the same length as projector conduit 136-2). As mentioned in connection with conduit 112, projector conduits 136 can also be provided by solid or hollow rods, or by channels of air. Each projector conduit 136 has a first end (138-1 and 138-2) for collecting directed light (139-1 and 139-2) from optical switch 128, and transmits the collected light to a second end (140-1 and 140-2) for delivery to the respective one of projectors 108. Optical elements such as focusing lenses (not shown) can be provided at first ends 138 and second ends 140 for collecting directed light 139 and for delivering the light to projectors 108.
Turning now to
Each resting state of optical switch 128 corresponds to a different one of projector conduits 136. In each of the resting states, optical switch 128 directs light received from source conduit 112 towards the corresponding one of projector conduits 136. In other words, each projector conduit 136 is located so as to collect light from optical switch 128 only when optical switch 128 is parked in the resting state corresponding to that projector conduit. Returning briefly to
Returning to
In
The discrete resting positions of optical switch 128a are defined by different angles of rotation of mirror 200a about axis 208a. For example, the rotation of mirror 200a can be driven by one or more servomotors, which can be configured to stop rotation at a plurality of preconfigured angles, with reference to a preset zero angle 210a. As a result, each discrete resting position corresponds to a different angle of the surface of mirror 200a in relation to preset zero angle 210a. Light received from source conduit 112 is therefore reflected by mirror 200a in a different direction in each resting position.
Referring now to
References to optical switch 128 hereafter will be understood to be a reference to any one of, or any combination of, the examples discussed in connection with
It will now be apparent that optical switch 128 can be used to control how much of the light emitted by light source 104 reaches each projector conduit 136. Specifically, optical switch 128 can be configured, in a given period of time, to rest at each of the discrete resting positions for configurable portions of the period of time. Because optical switch 128 directs light to a different projector conduit 136 in each resting position, the amount of time optical switch 128 spends in each resting position determines what proportion of the total light output of light source 104 is directed to the projector conduit 136 (and thus the corresponding projector 108) corresponding to that resting position.
A variety of mechanisms are contemplated for controlling the movement of optical switch 128 and the amount of time optical switch 128 spends in each discrete resting position. Examples of such control mechanisms will be discussed in connection with
Light source 304, projectors 308, and optical switch 328 are connected to, and controlled by, a computing device 350. Computing device 350 can be based on any suitable server or personal computer environment, or can be provided as a card within any suitable server or personal computer. In the present example, computing device 350 is a desktop computer housing various components, including a central processing unit, or processor, 354. Processor 354 is interconnected with a non-transitory computer readable storage medium such as a memory 358. Memory 358 can be any suitable combination of volatile memory (e.g. Random Access Memory (RAM)) and non-volatile memory (e.g. flash memory, magnetic discs and the like). Processor 354 is also interconnected with any suitable combination of input and output devices 362, such as a keyboard, a mouse, and a display. Processor 354 is further interconnected with a communications interface 366. Interface 366 allows computing device 350 to communicate with other devices (such as optical switch 128), and can be based on a wide variety of communications technologies. For example, interface 366 can include the necessary hardware to connect to other devices over one or more of a Universal Serial Bus (USB) connection, an Ethernet connection, or a wireless connection (e.g. Wi-Fi).
Processor 354 is configured to perform various functions via the execution of computer readable instructions (also referred to as applications) stored in memory 358. In the discussion below, when processor 354 or computing device 350 is said to perform an action, or to be configured to perform an action, it will be understood that such actions are performed as a result of processor 354 executing instructions stored in memory 358.
Memory 358 also stores light distribution settings 372, for use in controlling optical switch 328. Memory 358 can also store settings, applications and other data (e.g. image and video files) for use in controlling light source 304 and projectors 308. The control of light source 304 and projectors 308, however, will not be discussed in detail herein, as such control is performed according to conventional techniques. The control of optical switch 328 will be set out in detail below.
As discussed earlier, optical switch 328 can be used to control how much of the output of light source 304 is directed to each projector 308 during a given time period by spending specific portions of that time period in the discrete resting positions corresponding to each projector 308. Computing device 350 is configured to determine the length of time that optical switch 328 spends in each resting position, and to communicate the required resting times to optical switch 328. The determination of resting times at computing device 350 is based on light distribution settings 372.
Turning to
Settings 372 can be received at computing device 350 in a variety of ways. For example, computing device 350 can control input/output devices 362 to present a user interface with fillable fields or other elements, and receive input data comprising values each representing a fraction of light source 304's output to be directed to each projector 308. Having received such input, processor 354 can save the values in settings 372.
The format shown in
In order to control optical switch 328, processor 354 retrieves settings 372 from memory, and based on the values therein, determines operational parameters for optical switch 328. Optical switch 328 can be controlled using techniques similar to pulse width modulation (PWM). For example, optical switch 328 may be capable of switching between resting positions at a frequency of 120 Hz. Thus, the shortest period of time that optical switch 328 can spend in any one position is 1/120s (in practice, this will be somewhat shorter to account for the settling time between positions). Computing device 350 can therefore instruct optical switch 328 to divide the one hundred and twenty available periods in each second between the resting positions according to settings 372. In the present example, therefore, computing device 350 can instruct optical switch 328 to spend 48 available periods each second in the resting position corresponding to projector 308-1, 48 available periods in the resting position corresponding to projector 308-2, 12 available periods in the resting position corresponding to projector 308-3, and 12 available periods in the resting position corresponding to projector 308-4. A wide variety of other control schemes are also possible (for example, computing device 350 can send switching frequencies, or exact switching times, to optical switch 328), and optical switch 328 is not limited to a switching frequency of 120 Hz. Indeed, in many applications significantly higher frequencies may be desirable. DMDs, for example, can be capable of switching at frequencies of greater than 10 kHz.
Turning to
Returning to
Referring to
It is also contemplated that in some embodiments, computing device 350 can automatically determine settings 372. For example, if a video or image file indicates that image data is to be projected by one of projectors 308, while no image data is to be projected by the other projectors 308 (for example, some frames of a video may be black except for a small portion in one corner of the frame), computing device 350 can automatically adjust settings 372 to direct more light to the one projector 308 and less light to the others.
Further examples of optical switch 128 are also contemplated. For example optical switch 128 can be an acousto-optic modulator, in which acoustic waves are generated in a crystal for directing light passing through the crystal. The state of optical switch 128 can therefore be switched by modifying the characteristics of the acoustic waves. In contrast to the examples provided in
In additional variations, as mentioned earlier, optical switch 128 can be configured to direct light from light source 104 to more than one projector conduit 136 simultaneously. In other words, optical switch 128 can be in more than one resting state at the same time. Such functionality can be achieved, for example, by the use of a DMD, in which different portions of the micromirrors can be aimed different projector conduits 136.
Those skilled in the art will appreciate that in some embodiments, the functionality of computing device may be implemented using pre-programmed hardware or firmware elements (e.g., application specific integrated circuits (ASICs), electrically erasable programmable read-only memories (EEPROMs), etc.), or other related components.
Persons skilled in the art will appreciate that there are yet more alternative implementations and modifications possible for implementing the embodiments, and that the above implementations and examples are only illustrations of one or more embodiments. The scope, therefore, is only to be limited by the claims appended hereto.
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