Patent Description:
This section is intended to provide background or context for the specific embodiments of the present disclosure stated in the claims. The description here is not admitted as the prior art just because it is included in this section.

Laser phosphor light source technology is a technology that uses a first color laser light to excite phosphor powder to generate excited light. Usually blue laser light is used as the first color laser light. The phosphor powder may be yellow phosphor, green phosphor, or red phosphor, and so on. The blue laser light is relatively low in cost and high in electro-optical conversion efficiency, and achieves high excitation efficiency of the phosphor powder. However, fluorescent light has a wide spectrum and low color purity, and thus cannot directly meet the requirements of a wide color gamut. To improve the color purity, a filter is usually used to filter the light, but this method will cause a great light loss.

On this basis, a hybrid light source using fluorescent light and laser light can not only achieve better color purity, but also can maintain an acceptable cost by using decoherence of the mixed light thereof. At the same time, it brings some problems to the optical design. As the fluorescence spectrum and the laser light spectrum have overlapping wavelength bands, combining the fluorescence spectrum with the laser light spectrum will cause a large loss of light efficiency.

<CIT> relates to an illumination device. The illumination device (<NUM>) includes an excitation light source(<NUM>) which emits excitation light, a wavelength converter(<NUM>) which generates fluorescent light having a wavelength different from that of the excitation light through the excitation of the excitation light and a light path-splitting member(<NUM>) including a first filter and a second filter arranged to alternately come across a light path of the excitation light, wherein the first filter reflects one of the excitation light and the fluorescent light and transmits the other of the excitation light and the fluorescent light, the second filter transmits light reflected by the first filter and reflects light transmitted through the first filter, and the wavelength converter(<NUM>) is disposed in a reflection light path or a transmission light path of the excitation light.

<CIT> relates to a light source system and a projection device. The light source system includes an excitation light source (<NUM>) for generating a excitation light (<NUM>), a wavelength conversion device (<NUM>), a supplemental light source for generating a supplemental light, a light guiding device for directing the supplemental light to the wavelength conversion device, a light collection device for collecting the supplemental light that scattered and reflected by the wavelength conversion device.

<CIT> relates to a light source device and a projector. The light source device includes a light source section (<NUM>) which generates any one of blue light, red light, and green light; a phosphor (<NUM>) which generates a fluorescence including the two colors other than the color of the light emitted from the light source section (<NUM>); a color-changing section (<NUM>) which changes one of the two colors of the fluorescence emitted from the phosphor (<NUM>) to another color regularly and irradiates it to the image-forming element (<NUM>); and a light path-switching section (<NUM>) which switches a light path in which a fluorescence excited by the color light emitted from the light source section (<NUM>) passes towards the color-changing section (<NUM>) and a light path in which the color light emitted from the light source section (<NUM>) passes towards the image-forming element (<NUM>) regularly.

<CIT> relates to a light source device. The light source device has a first monochromatic light source group, a second monochromatic light source group, a polarization selection and wavelength selection element, a first phosphor layer, and a second phosphor layer. The first monochromatic light source group outputs first polarized light having a fixed polarization direction. The second monochromatic light source group outputs second polarized light having a fixed polarization direction. The first phosphor layer emits light in a first wavelength band. The second phosphor layer emits light in a second wavelength band. The polarization and wavelength selection element directs the first polarized light onto the first phosphor layer by transmitting the first polarized light and directs the second polarized light onto the second phosphor layer by reflecting the second polarized light, reflects the light in the first wavelength band and transmits the light in the second wavelength band.

To solve the technical problem of a large loss of light efficiency of a laser phosphor light source in the prior art, the present disclosure provides a laser phosphor light source system capable of effectively reducing the light efficiency loss, and the present disclosure further provides a projection device and an illumination device.

Further, the optical path selecting portion includes an undulating surface composed of surfaces of a first reflective portion and a second reflective portion, the first reflective portion is configured to guide the first color laser light to the first optical path, and the second reflective portion is configured to guide the first color laser light to the second optical path.

Further, the undulating surface is provided with a first segment and a second segment, wherein the first reflective portion is arranged in the first segment, and the second reflective portion is arranged in the second segment.

Further, the first reflective portion and the second reflective portion are arranged to be staggered or adjacent to each other.

Further, the first reflective portion and the second reflective portion are planes or curved surfaces with different reflection paths.

Further, the light source system is provided with corresponding collection lens groups at positions adjacent to the first wavelength conversion device and the second wavelength conversion device respectively, each collection lens group is configured to converge light to the corresponding wavelength conversion device, and collimate the fluorescent light exiting from the corresponding wavelength conversion device and then allow the fluorescent light collimated to exit.

Further, the light source system further includes a light homogenizing device, and the second color fluorescent light, the third color fluorescent light, the supplemental light, and the first color laser light transmitted by the optical path selecting element are combined and then enter the light homogenizing device.

Further, the light source system further includes a first split filter configured to guide the second color fluorescent light exiting from the first wavelength conversion device and the third color fluorescent light exiting from the second wavelength conversion device to exit along a same optical path; and
the first split filter is provided with a first region and a second region, wherein the first region is configured to guide the first color laser light transmitted along the first optical path to the first wavelength conversion device, and the second region is configured to guide the first color laser light transmitted along the second optical path to the second wavelength conversion device.

Further, the light source system further includes a second split filter configured to guide the supplemental light, the second color fluorescent light and the third color fluorescent light exiting from the first split filter, and the first color laser light transmitted by the optical path selecting element to exit along a same optical path.

Further, the second color fluorescent light and the third color fluorescent light are irradiated to a surface of the second split filter after collimation, the second split filter includes a coated region and an edge region; the supplemental light and the first color laser light exiting from the optical path selecting element converge near the coated region; and the coated region is configured to reflect the supplemental light and the first color laser light transmitted by the optical path selecting element, and the edge region is configured to transmit the second color fluorescent light and the third color fluorescent light.

Further, the coated region is configured to reflect light within a preset wavelength range, and a wavelength range of the first color laser light and a wavelength range of the supplemental light are within the preset wavelength range.

Further, the first color laser light and the supplemental light are light in a first polarization state, and the coated region is configured to reflect the light in the first polarization state and transmit light in other polarization states.

Further, the light source system further includes a third split filter, and the supplemental light emitted by the supplemental light source and the first color laser light emitted by the excitation light source are combined by the third split filter and then enter the optical path selecting element, and the optical path selecting portion of the optical path selecting element is further configured to transmit the supplemental light.

Further, the transmitting portion is a scattering sheet.

Further, the optical path selecting portion is a dichroic sheet with a curved surface.

Further, the light source system further includes a third split filter, and the first color laser light transmitted by the optical path selecting element and the supplemental light emitted by the supplemental light source are combined by the third split filter and then enter the second split filter.

Further, a scattering element is further arranged between the second split filter and the third split filter.

A projection device includes any light source system described above.

An illumination device includes any light source system described above.

The first color laser light and the supplemental light exiting from the light source system provided by the present disclosure are not reflected or transmitted by the wavelength conversion devices, and the utilization rate of laser light is high, which is beneficial to reducing the light efficiency loss of the light source system and increasing the luminous intensity, thereby ensuring the quality of output light of the projection device and the illumination device, and having a very important practical value.

To more clearly describe technical solutions in embodiments/implementations of the present disclosure, drawings for use in description of the embodiments/implementations will be introduced briefly below. Obviously, the drawings in the following description illustrate some embodiments/implementations of the present disclosure, and for those of ordinary skill in the art, other drawings may also be obtained based on these drawings without creative work.

The following specific embodiments will be used in conjunction with the above-mentioned drawings to further describe the present disclosure.

To understand the above objectives, features and advantages of the present disclosure more clearly, the present disclosure will be described in detail below in conjunction with the accompanying drawings and specific embodiments. It is to be noted that embodiments in the present application and features in the embodiments may be combined with each other without conflicts.

Many specific details are set forth in the following description to fully understand the present disclosure, and the described embodiments are only a part of the embodiments of the present disclosure, and not all the embodiments. All other embodiments obtained by those of ordinary skill in the art without creative work, based on the embodiments in the present disclosure, shall all fall into the protection scope of the present disclosure.

Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by those skilled in the technical field of the present disclosure. The terms used in the specification of the present disclosure are only for the purpose of describing the specific embodiments and are not intended to limit the present disclosure.

See <FIG> and <FIG>. <FIG> is a structural diagram of a light source system <NUM> according to a first embodiment of the present disclosure, and <FIG> is a top-view structural diagram of an optical path selecting element <NUM> shown in <FIG>. The light source system <NUM> has a high laser light utilization rate, which is beneficial to reducing the light efficiency loss of the light source system <NUM> and increasing the luminous intensity, and the light source system <NUM> can be applied to a projection device and an illumination device, and ensures the quality of output light of the projection device and the illumination device, and has a very important practical value.

The light source system <NUM> includes: an excitation light source <NUM>, a supplemental light source <NUM>, an optical path selecting element <NUM>, a first wavelength conversion device 150a, and a second wavelength conversion device 150b. Wherein, the excitation light source <NUM> is configured to emit a first color laser light; the supplemental light source <NUM> is configured to emit supplemental light of a different color from the first color laser light, the supplemental light is a laser light; and the optical path selecting element <NUM> includes a transmitting portion <NUM>, an optical path selecting portion <NUM>, and a driving portion <NUM>. The transmitting portion <NUM> is configured to transmit the first color laser light; the optical path selecting portion <NUM> is configured to reflect the first color laser light in time sequence to a first optical path or a second optical path; and the driving portion <NUM> is configured to drive the transmitting portion <NUM> and the optical path selecting portion <NUM> to be alternately located on an optical path of the first color laser light. The first wavelength conversion device 150a is configured to generate a second color fluorescent light under excitation of the first color laser light transmitted along the first optical path; and the second wavelength conversion device 150b is configured to generate a third color fluorescent light under excitation of the first color laser light transmitted along the second optical path. The second color fluorescent light, the third color fluorescent light, the supplemental light, and the first color laser light transmitted by the optical path selecting element are combined and then exit.

The first color laser light and the supplemental light exiting from the light source system <NUM> are not reflected and transmitted by the wavelength conversion devices, so the laser light utilization rate is high, which is beneficial to reducing the light efficiency loss of the light source system <NUM> and increasing the luminous intensity, thereby ensuring the quality of output light of the projection device and the illumination device, and having a very important practical value.

It should be understood that, the light source system <NUM> further includes a light homogenizing device <NUM>, and the second color fluorescent light, the third color fluorescent light, the supplemental light, and the first color laser light transmitted by the optical path selecting element <NUM> are combined and then enter the light homogenizing device <NUM>, and the light is homogenized by the light homogenizing device <NUM> and then exits. It should be understood that the light homogenizing device <NUM> may be a light homogenizing rod or a fly-eye lens. In an embodiment, the light homogenizing device <NUM> includes a scattering film for scattering light, so as to perform decoherence processing on the exiting light to reduce coherent speckles.

As shown in <FIG>, the excitation light source <NUM> and the supplemental light source <NUM> emit laser light of different colors. The excitation light source <NUM> includes a light emitting body configured to emit the first color laser light. In an embodiment, the excitation light source <NUM> further includes a light homogenizing device configured to homogenize the first color laser light.

Further, the excitation light source <NUM> may be a blue light source, which emits blue laser light. It should be understood that the excitation light source <NUM> is not limited to a blue light source, and the excitation light source <NUM> may also be a purple light source, a red light source, a green light source, or the like. In this embodiment, the light emitting body in the excitation light source <NUM> is a blue laser configured to emit blue laser light as the first color laser light. It should be understood that the light emitting body in the excitation light source <NUM> may include one or two lasers or laser arrays, and the specific number of the lasers may be selected according to actual needs.

The light homogenizing device is configured to homogenize the first color laser light and then allow the homogenized light to exit. In this embodiment, the light homogenizing device may be a light homogenizing rod or a fly-eye lens. In an embodiment, the light homogenizing device in the excitation light source <NUM> includes a scattering film configured to scatter the first color laser light, so as to perform decoherence processing on the first color laser light.

In this embodiment, the supplemental light source <NUM> includes a light emitting body configured to emit red laser light. The light emitting body in the supplemental light source <NUM> is a red laser, and the supplemental light source <NUM> is configured to emit red laser light as the supplemental light. In this embodiment, it should be understood that the light emitting body in the supplemental light source <NUM> may include one or two lasers or laser arrays, and the specific number of the lasers may be selected according to actual needs. It should be understood that, in an embodiment, the supplemental light source <NUM> is configured to emit green laser light as the supplemental light, and accordingly, the light emitting body in the supplemental light source <NUM> includes a green laser. It should be understood that the supplemental light source <NUM> may also include a light emitting body configured to emit laser light of two colors. For example, the light emitting body in the supplemental light source <NUM> includes a red laser and a green laser, which emit red laser light and green laser light as the supplemental light.

As shown in <FIG>, the first wavelength conversion device 150a and the second wavelength conversion device 150b are fixed wavelength conversion devices, preferably fixed fluorescent plates, which is beneficial to reducing the space occupied by the wavelength conversion devices in the light source system <NUM>, and is favorable for a miniaturization design of the light source system <NUM>. The first wavelength conversion device 150a and the second wavelength conversion device 150b are configured to generate fluorescent light of corresponding colors under the excitation of the first color laser light. In this embodiment, a surface of the first wavelength conversion device 150a is provided with red phosphor powder to generate red fluorescent light, and a surface of the second wavelength conversion device 150b is provided with green phosphor powder to generate green fluorescent light. It should be understood that the first wavelength conversion device 150a and the second wavelength conversion device 150b may also be provided with wavelength conversion materials of other colors.

The light source system <NUM> is provided with corresponding collection lens groups at positions adjacent to the first wavelength conversion device 150a and the second wavelength conversion device 150b respectively, each collection lens group is configured to converge light to the corresponding wavelength conversion device, and collimate the fluorescent light exiting from the corresponding wavelength conversion device and then allow the fluorescent light collimated to exit.

The light source system <NUM> further includes a control device (not shown in the figure). When the transmitting portion <NUM> is located on the optical path of the first color laser light, the control device controls the supplemental light source <NUM> not to emit light; and when the optical path selecting portion <NUM> is located on the optical path of the first color laser light, the control device controls, according to the color of the generated fluorescent light, the supplemental light source <NUM> to emit supplemental light of the corresponding color. In this embodiment, when the first wavelength conversion device 150a generates red fluorescent light, the control device controls the supplemental light source <NUM> to generate red supplemental light. When the second wavelength conversion device 150b generates green fluorescent light, the control device controls the supplemental light source <NUM> to generate green supplemental light. It should be understood that in embodiments in which the supplemental light source <NUM> can emit red supplemental light and green supplemental light, the control device controls the supplemental light source <NUM> to emit supplemental light corresponding to the current fluorescent color, that is, the control device controls the supplemental light source <NUM> to generate red supplemental light when red fluorescent light is generated, and the control device controls the supplemental light source <NUM> to generate green supplemental light when green fluorescent light is generated.

The light source system <NUM> further includes a third split filter <NUM>, and the supplemental light emitted by the supplemental light source <NUM> and the first color laser light emitted by the excitation light source <NUM> are combined by the third split filter <NUM> and then enter the optical path selecting element <NUM>. In this embodiment, the third light splitting filter <NUM> is a dichroic sheet for transmitting blue light and reflecting red light. Correspondingly, the transmitting portion <NUM> is a scattering sheet to reduce a speckle phenomenon of the first color laser light and expand its etendue. It should be understood that, in an embodiment, the transmitting portion <NUM> is provided with an anti-reflection film, and a scattering element is further provided between the optical path selecting element <NUM> and the light homogenizing device <NUM>.

As shown in <FIG>, the optical path selecting portion <NUM> in the optical path selecting element <NUM> includes an undulating surface composed of surfaces of a first reflective portion and a second reflective portion, the first reflective portion is configured to guide the first color laser light to the first optical path, and the second reflective portion is configured to guide the first color laser light to the second optical path. The first reflective portion and the second reflective portion have different surface curvatures. In an embodiment, the first reflective portion and the second reflective portion are a combination of a concave portion and a convex portion. For example, the first reflective portion is a concave portion, which extends in a direction close to the driving portion <NUM> in a concave manner relative to a surface of the transmitting portion <NUM>; and the second reflective portion is a convex portion, which extends in a direction away from the driving portion <NUM> in a convex manner relative to the surface of the transmitting portion <NUM>. It should be understood that the first reflective portion may also be a combination of a concave portion and a plane, a combination of a convex portion and a plane, or a combination of a concave portion and a concave portion with different curvatures, a combination of a convex portion and a convex portion with different curvatures, or a combination of a plane and a plane with different reflection directions. In an embodiment, the second reflective portion is configured to guide the first color laser light to the first optical path, and the first reflective portion is configured to guide the first color laser light to the second optical path.

In this embodiment, the undulating surface is provided with a first segment 135a and a second segment 135b, and the first reflective portion is provided in the first segment 135a, and the second reflective portion is provided in the second segment 135b. In an embodiment, adjacent first reflective portions, and/or an adjacent first reflective portion and second reflective portion, and/or adjacent second reflective portions are connected. In an embodiment, adjacent first reflective portions, and/or a first reflective portion and a second reflective portion, and/or second reflective portions are spaced apart from each other.

In an embodiment, the corresponding first reflective portion and second reflective portion of the undulating surface are staggered. In embodiments in which the first reflective portion and the second reflective portion are a combination of a concave portion and a convex portion, the undulating surface is corrugated. Further, the first reflective portion and the second reflective portion are arranged adjacently with a preset spacing therebetween.

The optical path selecting portion <NUM> is further configured to transmit the supplemental light. In this embodiment, the optical path selecting portion <NUM> is a curved dichroic sheet, which is configured to reflect blue light and transmit red light or reflect blue light and transmit yellow light.

See <FIG> which is a top-view structural diagram of a first light splitting filter <NUM> shown in <FIG>. The light source system <NUM> further includes the first light splitting filter <NUM> arranged between the optical path selecting element <NUM>, the first wavelength conversion device 150a, and the second wavelength conversion device 150b. The first light splitting filter <NUM> is configured to guide the second color fluorescent light exiting from the first wavelength conversion device 150a and the third color fluorescent light exiting from the second wavelength conversion device 150b to exit along a same optical path. A dichroic film is provided on a side, facing the second wavelength conversion device 150b, of the first light splitting filter <NUM>. In this embodiment, the dichroic film is configured to reflect green light and transmit red light.

The first light splitting filter <NUM> is provided with a first region <NUM> and a second region <NUM>, wherein the first region <NUM> is configured to guide the first color laser light transmitted along the first optical path to the first wavelength conversion device 150a, and the second region <NUM> is configured to guide the first color laser light transmitted along the second optical path to the second wavelength conversion device 150b. Further, the first region <NUM> corresponds to the first reflective portion and is configured to receive the light emitted by the first reflective portion; and the second region <NUM> corresponds to the second reflective portion and is configured to receive the light emitted by the second reflective portion. It should be understood that the first region <NUM> and the second region <NUM> may be arranged adjacently or spaced apart, and a spacing distance between the first region <NUM> and the second region <NUM> may be determined according to parameters of the first optical path and the second optical path, thereby ensuring that the first color laser light exiting from the first reflective portion and transmitted along the first optical path is guided to the first wavelength conversion device 150a by the first region <NUM>, and that the first color laser light exiting from the second reflective portion and transmitted by the second optical path is guided to the second wavelength conversion device 150b by the second region <NUM>.

The optical path selecting element <NUM> allows the first color laser light transmitted along the first optical path and the second optical path to exit alternately in a time sequence, such that the first light splitting filter <NUM> allows the first color laser light to exit alternately to the first wavelength conversion device 150a and the second wavelength conversion device 150b in a time sequence. In this embodiment, the first region <NUM> is configured to reflect the first color laser light, and the second region <NUM> is configured to transmit the first color laser light, and the first color laser light is blue laser light. On a side, facing the first wavelength conversion device 150a, of the first light splitting filter <NUM>, the first region <NUM> may be provided with a dichroic film or a reflective film configured to reflect blue light, and the second region <NUM> may be provided with an anti-reflection film.

In conjunction with <FIG>, further refer to <FIG> which is a top-view structural diagram of a second light splitting filter <NUM> shown in <FIG>. The light source system <NUM> further includes the second light splitting filter <NUM> arranged between the first light splitting filter <NUM> and the light homogenizing device <NUM>, the second light splitting filter <NUM> is configured to guide the supplemental light, the second color fluorescent light and the third color fluorescent light exiting from the first light splitting filter <NUM>, and the first color laser light transmitted by the optical path selecting element <NUM> to exit along a same optical path to the light homogenizing device <NUM>.

The second color fluorescent light and third color fluorescent light after collimation are irradiated to a surface of the second light splitting filter <NUM>, the second light splitting filter <NUM> including a coated region <NUM> and an edge region <NUM>; the supplemental light and the first color laser light exiting from the optical path selecting element <NUM> converge near the coated region <NUM> through a converging lens <NUM>; and the coated region <NUM> is configured to reflect the supplemental light and the first color laser light transmitted by the optical path selecting element <NUM>, and the edge region <NUM> is configured to transmit the second color fluorescent light and the third color fluorescent light.

Specifically, the coated region <NUM> is coated with a reflective film or a filter film, or the coated region <NUM> is provided with a reflector or a filter, and the edge region <NUM> is coated with an anti-reflection film. In an embodiment, the coated region <NUM> is coated with a bandpass filter film configured to reflect light within a preset wavelength range, and a wavelength range of the first color laser light and a wavelength range of the supplemental light are within the preset wavelength range. The bandpass filter film reflects light within the preset wavelength range and reflects light outside the preset wavelength range. In an embodiment, the preset wavelength range is: <NUM>-<NUM>, <NUM>-<NUM>, and <NUM>-<NUM>, and the above three wavelength bands are wavelength bands of the first color laser light and the supplemental light to reduce the loss of the fluorescent light in the coated region <NUM> and increase the utilization rate of fluorescent light.

In an embodiment, the first color laser light and the supplemental light are light in a first polarization state, and the coated region <NUM> is configured to reflect the light in the first polarization state and transmit light in other polarization states. As the fluorescent light is unpolarized light, the fluorescent light loses <NUM>/<NUM> of light efficiency in the coated region <NUM>, which is beneficial to improving the utilization rate of the fluorescent light.

Further, both the supplemental light and the first color laser light exiting from the optical path selecting element <NUM> are laser light in a Gaussian distribution with a small etendue, and form a very small spot on the coated region <NUM> after convergence, a size of the coated region <NUM> matches that of the spot formed by the laser light. The fluorescent light in a Lambertian distribution has a large etendue, and an area of a spot irradiated to the surface of the second light splitting filter <NUM> is much larger than that of the spot formed by the laser light, and most of the fluorescent light is irradiated to the edge region <NUM>. The light source system <NUM> can achieve the combination of the fluorescent light and the laser light with a small amount of the fluorescent light being lost, according to the principle of etendue-based light combination.

In the process of combining the laser light and the fluorescent light, by optimizing the focal length of the converging lens <NUM> and the scattering degree of the transmitting portion <NUM> in the optical path selecting element <NUM>, the laser angle can be matched with the fluorescence angle, so that the combined light is continuous in angular distribution after the fluorescent light and the laser light are combined, which ensures the angular uniformity of the combined light, and avoids the degradation of the image quality of a projected picture or the quality of illumination light.

In addition, the light source system <NUM> in embodiments of the present disclosure further includes guide components known in the art, such as a relay lens and a reflector, which are not listed one by one here.

Referring to <FIG>, the former is a structural diagram of a light source system <NUM> according to a second embodiment of the present disclosure, and <FIG> is a top-view structural diagram of an optical path selecting element <NUM> shown in <FIG>. The light source system <NUM> differs from the light source system <NUM> mainly in that supplemental light does not pass through the optical path selecting element <NUM>, which is beneficial to improving the utilization rate of laser light. Specifically, first color laser light transmitted by the optical path selecting element <NUM> and supplemental light emitted by a supplemental light source <NUM> are combined by a third light splitting filter <NUM> and then enter a second light splitting filter <NUM>. Correspondingly, the optical path selecting element <NUM> has a transmitting region <NUM> configured to transmit the first color laser light, and an optical path selecting portion <NUM> configured to reflect the first color laser light. A scattering element <NUM> is further arranged between the second light splitting filter <NUM> and the third light splitting filter <NUM> to reduce the speckle phenomenon of the laser light and expand its etendue.

It is to be noted that, within the scope of the spirit or basic features of the present disclosure, the specific solutions applicable to the first embodiment may also be correspondingly applied to the second embodiment and will not be detailed here to save space and avoid repetition.

To those skilled in the art, obviously, the present disclosure is not limited to the details of the foregoing exemplary embodiments, and the present disclosure can be implemented in other specific forms without departing from the spirit or basic features of the present disclosure. Therefore, from any point of view, the embodiments should be regarded as exemplary and non-restrictive, and the scope of the present disclosure is defined by the appended claims rather than the above description, and thus, all changes that fall within the meanings and scopes of equivalent elements of the claims are intended to be encompassed within the present disclosure. No reference signs in the claims should be construed as limiting the claims involved. In addition, obviously the word "comprise/include" does not exclude other units or steps, and the singular does not exclude the plural. Multiple devices stated in the device claims may also be implemented by the same device or system through software or hardware. Words such as first and second are used to denote names, but do not denote any specific order.

Claim 1:
A light source system (<NUM>, <NUM>), comprising:
an excitation light source (<NUM>) configured to emit first color laser light;
a supplemental light source (<NUM>, <NUM>) configured to emit supplemental light of a different color from that of the first color laser light, the supplemental light being laser light;
an optical path selecting element (<NUM>, <NUM>) comprising:
a transmitting portion (<NUM>, <NUM>) configured to transmit the first color laser light;
an optical path selecting portion (<NUM>, <NUM>) configured to reflect the first color laser light in time sequence to a first optical path or a second optical path; and
a driving portion (<NUM>) configured to drive the transmitting portion (<NUM>, <NUM>) and the optical path selecting portion (<NUM>, <NUM>) to be alternately located on an optical path of the first color laser light;
a first wavelength conversion device (150a) configured to generate a second color fluorescent light under excitation of the first color laser light transmitted along the first optical path; and
a second wavelength conversion device (150b) configured to generate a third color fluorescent light under excitation of the first color laser light transmitted along the second optical path;
characterized in that the light source system (<NUM>, <NUM>) further comprises a control device, wherein when the transmitting portion (<NUM>, <NUM>) is located on the optical path of the first color laser light, the control device controls the supplemental light source (<NUM>, <NUM>) not to emit light; and when the optical path selecting portion (<NUM>, <NUM>) is located on the optical path of the first color laser light, the control device controls the supplemental light source (<NUM>, <NUM>) to emit light;
wherein the second color fluorescent light, the third color fluorescent light, the supplemental light, and the first color laser light transmitted by the optical path selecting element (<NUM>, <NUM>) are combined and then exit.