Patent Description:
A head mounted display or head mounted device (HMD) is worn by a user to view the mixed imagery of virtual and real objects. An HMD uses a combination of optics and stereopsis to focus virtual imagery in the user's field of view. Industrial design and manufacturing challenges continue to impact HMDs, particularly as devices shrink and yet become more functional and complex. Device appearance also influences considerations.

<CIT> describes a proximity sensor packaging structure and a manufacturing method thereof.

<CIT> discloses a distance detecting sensor, comprising: a housing, a focusing lens, a circuit board provided with several electronic elements, as well as a transmitter device for transmitting infrared light rays and a receiver device for receiving and sensing the reflected infrared light rays.

<CIT> describes an apparatus and a method for detection of foreign substances in a depth sensing system.

<CIT> describes that a head-mounted display (HMD) device with a chassis, a display assembly, and various sensors and electronics, where the display assembly, sensors and electronics are mounted to the chassis and enclosed within a sealed protective visor, and where the display assembly is mounted to the chassis only through a central location that is aligned with a center-point between the user's eyes, thereby decoupling the display assembly from most mechanical and thermal stresses.

<CIT> describes a radiation sensor of the type having a packaged radiation source and detector, which includes an isolator that blocks propagation within the package of radiation from the source to the detector, in order to improve signal to noise ratio of the sensor.

<NPL> describes that polymeric microlens arrays, with a diameter of <NUM>-<NUM>, a radius of curvature of <NUM>-<NUM> and a pitch of <NUM>, were fabricated using micro-compression molding with electroformed mold inserts.

<CIT> describes that a package structure of an optical module includes: a substrate defined with a light-emitting region and a light-admitting region; a light-emitting chip disposed at the light-emitting region of the substrate; a light-admitting chip disposed at the light-admitting region of the substrate; two encapsulants for enclosing the light-emitting chip and the light-admitting chip, respectively; and a shielding layer formed on the substrate and the encapsulants and having a light-emitting hole and a light-admitting hole, wherein the light-emitting hole and the light-admitting hole are positioned above the light-emitting chip and the light-admitting chip, respectively.

The described technology addresses such limitations by providing a head-mounted display or head mounted device (HMD).

A depth sensor window lens for an HMD can be made, in one implementation, by: injecting an optically clear polymeric material into a first mold to form a sensor lens and an illuminator lens; injecting an opaque polymeric material into a second mold subsequent to the operation of injecting an optically clear polymeric material, the second mold defining a dam between the sensor lens and the illuminator lens and forming an as-molded part; and extracting the as-molded part from the second mold, the as-molded part having a front surface of the dam within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens, wherein the depth sensor window lens further comprising a frame in contact with a periphery of the sensor lens and a periphery of the illuminator lens, the frame including the dam.

A head mounted display or head mounted device (HMD) for augmented reality (AR) and/or mixed reality (MR) uses a combination of optics and stereopsis to focus virtual imagery in the user's field of view. The depth sensor window lens, made by the methods disclosed herein, provides an enhanced user experience for the user using the HMD due to the depth sensor window lens and the manner in which it is constructed. The methods presented herein provide a precise, optical-quality lens that enhances the user's experience. This disclosure addresses both design and manufacturing sides for the HMD, as described below.

Particularly, described herein is a method of making a depth sensor window lens for an AR HMD or MR HMD, although the method can be used for other visual displays needing the same degree of optical preciseness.

Described herein is a method of making an optical-grade lens using two-shot injection molding. One particular method described herein includes using dual-shot or two-shot injection molding (e.g., rotational injection molding) to form the lens.

In one particular implementation, this disclosure provides a method that includes injecting an optically clear polymeric material (e.g., optically transparent and/or translucent) into a first mold to form a sensor lens and an illuminator lens; injecting an opaque polymeric material into a second mold subsequent to the operation of injecting an optically clear polymeric material, the second mold defining a dam between the sensor lens and the illuminator lens and forming an as-molded part; and extracting the as-molded part from the second mold, the as-molded part having a front surface of the dam within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens.

The disclosure also provides a depth sensor window lens comprising a sensor lens comprising an IR transparent polymer having an RMS surface finish of no more than <NUM>, an illuminator lens comprising an IR transparent polymer having an RMS surface finish of no more than <NUM>, and a dam between the sensor lens and the illuminator lens, the dam comprising an opaque polymer and having a front surface within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens. Such a depth sensor window lens may be integrated into a lens for an HMD.

This disclosure also provides an HMD having a visor; and a depth sensor window lens integrated into the visor, the depth sensor window lens including a sensor lens comprising an IR transparent polymer having an RMS surface finish of no more than <NUM>, an illuminator lens comprising an IR transparent polymer having an RMS surface finish of no more than <NUM>, and a dam between the sensor lens and the illuminator lens, the dam comprising an opaque polymer and having a front surface within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens.

<FIG> illustrates an example HMD <NUM> having a visor <NUM> that can be supported onto a user's head by a strap <NUM>, which may include a back support <NUM> to increase the user's comfort. The visor <NUM> has a viewing area or lens <NUM> essentially commensurate with the user's total field of view (TFOV) while wearing the HMD <NUM>.

In AR and/or MR applications, the HMD <NUM> provides a user interface to manage (e.g., activate, deactivate) applications in the HMD <NUM>. The visor <NUM> includes the circuitry, processor(s), modules, electronics, etc. for the HMD <NUM>; in some implementations, circuitry, processor(s), modules, etc., may be present in the back support <NUM>.

In the HMD <NUM>, the viewing area or lens <NUM> couples at least a portion of an optimized image to the user's focal region. Inertial, magnetic, mechanical and/or other sensors sense orientation information for the HMD and eye tracking sensors detect user eye position. A processing unit, in communication with the display, and inertial and/or other sensors and eye tracking sensors, automatically determine the total field of view (TFOV) of the user. The processing device then generates and displays a first menu including a list of one or more applications in the TFOV. The processing device receives a user selection to activate an application from the list. The processing device further generates a second menu including a list of one or more applications that are currently running in the HMD and displays the second menu in a second region of the TFOV. The second menu includes the application activated by the user. The HMD <NUM> of <FIG> satisfies the user's desire of small form factor size, a hidden sensor module, safety, working sensor angles, and industrial design needs.

For many of the applications of the HMD <NUM>, depth sensing is paramount. Because of this, the HMD <NUM> includes a time-of-flight (TOF) depth sensing sensor within the visor <NUM>. The TOF-based depth-sensing technology uses specific wavelength IR light to illuminate the surrounding mapping areas and uses an imaging sensor to capture the IR image for depth computing. The TOF depth sensor is integrated into the visor lens <NUM> and is shown in <FIG> behind a depth sensor window lens <NUM>. The depth sensor window lens <NUM> may be referred to as an integrated depth sensor window lens when present in, and part of, the visor lens <NUM>.

The integrated depth sensor window lens <NUM> has two parts or halves, one lens <NUM> for the sensor and the other lens <NUM> for the illuminator which together provide depth sensing. A sensor <NUM> is shown behind the lens <NUM> and two illuminators <NUM>, <NUM> are shown behind the lens <NUM>, the two illuminators <NUM>, <NUM> having opposite polarities. Although <FIG> has the sensor lens <NUM> and the sensor <NUM> on the right side, as viewed by a wearer of the HMD, and the illuminator lens <NUM> and the illuminators <NUM>, <NUM> on the left side, it is understood that these may be switched.

The sensor lens <NUM> and the illuminator lens <NUM> are held by a frame <NUM>, which in this implementation, provides a separation between the lenses <NUM>, <NUM> and also encompasses the lenses <NUM>, <NUM> around their periphery. The image sensing lens <NUM> and illuminator lens <NUM> are optically separated to prevent stray light caused by the illumination reflection inside the lens from disrupting proper depth sensing. In <FIG>, the sensor lens <NUM> and the illuminator lens <NUM> are separated by an opaque dam <NUM> that is part of the frame <NUM>. From an industrial design and device appearance standpoint, a seamless outline is desired. To provide a desirable product, the HMD <NUM> has a compact size depth sensor window lens <NUM>, with less than <NUM> distance between the lenses <NUM>, <NUM>, and thus a width of the dam <NUM> of less than <NUM>. In some implementations, this distance is less than <NUM>, in other implementations less than <NUM>.

The depth sensor window lens <NUM> is configured to allow for both illuminations to shine-through and the sensor to collect light without sacrificing optical performance and device aesthetics. In accordance with this disclosure, the window lens <NUM> is formed by a two-shot injection molding process, the first shot forming the illuminator lens <NUM> and the sensor lens <NUM> and the second shot forming the frame <NUM> including the dam <NUM> between the illuminator lens <NUM> and the sensor lens <NUM>).

<FIG> illustrates a depth sensor window lens <NUM> from a front perspective view, the window lens <NUM> having a sensor lens <NUM> and an illuminator lens <NUM> held in a frame <NUM>. The frame <NUM> includes a frame dam <NUM> that seats between the sensor lens <NUM> and the illuminator lens <NUM> and optically decouples the two lenses <NUM>, <NUM>. The dam <NUM> extends from the front surface of the lenses <NUM>, <NUM> to at least the back surface of the lenses <NUM>, <NUM>; in other words, the dam <NUM> has a thickness the same as or greater than the thickness of the lenses <NUM>, <NUM>.

In some implementations, the thickness of the sensor lens <NUM> and the illuminator lens <NUM> is <NUM> or less. In some implementations, the width of the dam <NUM> between the lenses <NUM>, <NUM> is less than <NUM>, e.g., less than <NUM>, about <NUM>, less than <NUM>, e.g., about <NUM> or about <NUM>.

In accordance with this disclosure, the depth sensor window lens <NUM> is an integral, single part, having the lenses <NUM>, <NUM> and the frame <NUM> formed via the same process. No adhesive, welding, bonding, mechanical fastener, or other mechanism is used to hold or retain the lenses <NUM>, <NUM> with the frame <NUM>; rather, the process of forming the lenses <NUM>, <NUM> and the frame <NUM> forms the depth sensor window lens <NUM> as one integral part.

<FIG> illustrates a depth sensor window lens <NUM> from a back perspective view, which is the orientation see by a user of an HMD when the window lens <NUM> is incorporated into the HMD. The window lens <NUM> has a sensor lens <NUM> and an illuminator lens <NUM> held in a frame <NUM>. The frame <NUM> includes a frame dam <NUM> that seats between the sensor lens <NUM> and the illuminator lens <NUM> and optically decouples the two lenses <NUM>, <NUM>. The dam <NUM> extends from the front surface of the lenses <NUM>, <NUM> past the back surface of the lenses <NUM>, <NUM>. The frame <NUM> also contacts the lens <NUM>, <NUM> at and around their periphery, including the back surfaces of the lenses <NUM>, <NUM> proximate their peripheries.

Various features of the depth sensor window lens <NUM> and its elements not detailed here may be the same as or similar to details provided for other implementations described herein.

<FIG> is a top view of a depth sensor window lens <NUM> having a sensor lens <NUM> and an illuminator lens <NUM> held in a frame <NUM>. The frame <NUM> includes a frame dam <NUM> that seats between the sensor lens <NUM> and the illuminator lens <NUM> and optically decouples the two lenses <NUM>, <NUM>. The dam <NUM> extends from a front surface <NUM> of the sensor lens <NUM> to and past a back surface <NUM>, and from a front surface <NUM> of the illuminator lens <NUM> to and past a back surface <NUM>. Although not readily apparent in <FIG>, the frame <NUM> engaged with the lens <NUM>, <NUM> at the dam <NUM> and around the periphery of the lenses <NUM>, <NUM> on the back surfaces <NUM>, <NUM>.

The dam <NUM> is substantially flush with the front surfaces <NUM>, <NUM> of the lenses <NUM>, <NUM>, within no more than <NUM>, in some implementations, no more than <NUM>, or <NUM>. In <FIG>, the front surface <NUM> of the lens <NUM> meets the dam <NUM> at a valley <NUM>, and the front surface <NUM> of the lens <NUM> meets the dam <NUM> at a valley <NUM>. These valleys <NUM>, <NUM> are no than <NUM> deep, <NUM> deep, or <NUM> deep, and are no than <NUM> wide, <NUM> wide, or <NUM> wide. In some implementations, the width of the dam <NUM>, measured between the lenses <NUM>, <NUM>, is less than <NUM>, e.g., less than <NUM>, about <NUM>, less than <NUM>, e.g., about <NUM> or about <NUM>.

In some implementations, the thickness of the lenses <NUM>, <NUM>, from the front surface <NUM>, <NUM> to the back surface <NUM>, <NUM> is <NUM> or less.

Various features of the depth sensor window lens <NUM> and its elements not detailed here may be the same as or similar to details provided for other implementations described herein. It is noted that the particular configuration of the back side of the frame <NUM> is for attaching or installing the depth sensor window lens <NUM> in an HMD visor, such as visor <NUM> of <FIG>.

<FIG> is an exploded view of a depth sensor window lens, with a sensor lens <NUM> and an illuminator lens <NUM> removed from and separated from a frame <NUM>, which has a dam <NUM> shaped and sized to seat between the lenses <NUM>, <NUM> when the frame <NUM> and lenses <NUM>, <NUM> are combined. Additionally, the frame <NUM> contacts the lenses <NUM>, <NUM> at their respectively peripheries <NUM>, <NUM> and on their back surfaces proximate the peripheries <NUM>, <NUM>.

Various features of the depth sensor window lens, the sensor lens <NUM>, the illuminator lens <NUM> and their elements not detailed here may be the same as or similar to details provided for other implementations described herein.

As indicated above, this disclosure addresses both the design and manufacturing perspectives for the depth sensor window lens, e.g., the integrated depth sensor window lens.

From the design perspective, while both the sensor and the illuminator have their own optically clear lens, they are joined together to form a single part with an optical isolated (e.g., opaque) barrier or dam between the two lenses to prevent the light from leaking and reflecting to the adjacent chamber. The lenses are optically clear, IR plastic (polymeric) lenses that can pass the specific wavelength light which the depth module operates. The opaque dam in the middle has high opaqueness (e.g., an optical density greater than <NUM>). The combination of the three individual pieces (two lenses and one frame) forms a single, integral part that has the desired characteristics: mirror polished surface finish for at least the lenses, the seamless joint line, the optically clear IR lenses and the opaque middle frame. In some implementations, both the lenses and the frame are visually black in color.

In the field of injection molding manufacturing, single operation double-shot injection molding has been used on many products, such as keyboard buttons. However, use of an optically graded, mirror polish surface finish on double-shot parts, to achieve a seamless appearance, has yet to be implemented in optical devices such as HMDs. One of the challenges is that the valley at a joint boundary or juncture during a double-shot process can be much deeper than an optical grade mirror polish (e.g., < <NUM> surface roughness (Ra)). Thus, the juncture is usually noticeable, which affects the aesthetic aspect of the product. If the process is not managed right, any deep valley at the juncture (e.g., greater than about <NUM>) can cause unexpected stray light from the ambient world to affect the depth measurement.

In accordance with this disclosure, to achieve a shallow, less noticeable valley (e.g., less than <NUM>, or less than <NUM>, or even less than <NUM> deep, and optionally less than <NUM>, or <NUM>, or <NUM> wide) between the lenses and the dam, the tooling tolerance for the first and second shot are extremely tight, e.g., within <NUM>, so that when the tool (mold) closes, material can flow through and fully fill the juncture where the second shot meets the first shot, thus inhibiting any valley. The injection process is also precisely controlled so the second shot molding material can fully fill the juncture region, from the front surfaces of the first shot to the back surfaces, while inhibiting the formation of voids and melting or softening of the first shot material.

An example overall processes for producing a depth sensor window lens (which includes the two optically clear lenses having a mirror finish - for the sensor and the illuminator - and the frame that includes an optically opaque dam separating the sensor lens and the illuminator lens) includes the following steps. First, appropriate tooling (mold) is obtained for the two lenses (first shot) and the frame (second shot). The tooling is shaped and sized to tight tolerance in order to obtain the eventual product. The tooling may be formed, e.g., of nickel, stainless steel (e.g., Stavex™ stainless steel) or a combination thereof; the tooling may be, e.g., stainless steel with a nickel coating. In some implementations, the tooling may have a mirror polish surface finish. The tooling is used in a double-shot injection molding process, which may be done in a cleanroom (e.g., <NUM> class cleanroom). The resulting piece has an RMS surface roughness of less than <NUM>. The piece is quality checked, and then coated with at least one protective coating (e.g., <NUM> class cleanroom) to provide a coated piece with a UV/VIS transmission of Tmax < <NUM>% and Tavg < <NUM>% and an NIR transmission of: Tavg > <NUM>% at <NUM> degree angle of incidence, Tavg > <NUM>% at <NUM> degree angle of incidence, Tavg > <NUM>% at a <NUM> degree angle of incidence, Tmin > <NUM>% at a <NUM> degree angle of incidence, Tmin > <NUM>% at a <NUM> degree angle of incidence, and Tmin > <NUM>% at a <NUM> degree angle of incidence, as determined by a subsequent quality check. Upon approval, the piece is machined (e.g., using a Beijing Carver CNC machine, and/or in a <NUM> class cleanroom) to a tolerance of ± <NUM>. After another quality check, which may be or include a visual cosmetic inspection, the piece is packaged (e.g., in a plastic turnover tray) for eventual installation into an HMD, e.g., at the same facility or by another party.

As indicated above, the process utilizes a double-shot, two-shot or dual-shot injection molding process. <FIG> shows a stepwise process <NUM> for forming a depth sensor window lens using a double-shot injection molding method.

The process <NUM> includes a first injection operation <NUM> where the first shot is molded in a first mold; the first mold may have a mirror quality surface finish. The injection operation <NUM> includes injecting a first polymeric material, e.g., IR transparent, into the first mold to form the lenses for the illuminator and the sensor. At an opening operation <NUM>, the first mold is opened, and at least a part of the mold is removed from the formed lenses. At a rotating operation <NUM>, the molded part is rotated, e.g., on a rotary table, to the location of a second mold. A second injection operation <NUM>, the second mold is used for molding a second shot of polymeric material, e.g., opaque material, for forming the frame around the lenses; the second mold may have a mirror quality surface finish. This second shot may occur within, e.g., <NUM> seconds, <NUM> seconds, <NUM> seconds, or even <NUM> seconds after the first shot. This second shot inherently adheres to the first part (lenses) during the process, so that no additional fastening or connecting mechanism is added between the parts. The first shot may or may not be completely cured or polymerized when the second shot is injected. In another opening operation <NUM>, the second mold is opened, and the twice-molded part is removed from the second mold in a picking operation <NUM>, e.g., by a mechanical hand. At this stage, the twice-molded part, particularly the lenses formed by the first shot, have a mirror-quality finish, and/or an RMS surface roughness of less than <NUM>.

It is noted that the process <NUM>, in one implementation, includes two different cavities (molds) that utilize the same cores on a rotary table. This allows a process where both the first shot and the second shot are working simultaneously; that is, while the first shot is injecting into the first mold, the second shot is injecting into the second mold. After these processes, the rotary table rotates, moving the cores in position for the next shots.

<FIG> illustrates an example rotary injection molding machine <NUM> suitable for implementing the process <NUM>. The injection molding machine <NUM> has a rotary table <NUM> and a first mold <NUM> and a second mold <NUM>, the first mold <NUM> including a first cavity <NUM> and a first core <NUM> and the second mold <NUM> including a second cavity <NUM> and a second core <NUM>. The first mold <NUM> receives the first shot of material (to form the lenses) and the second mold <NUM> receives the second shot of material (to form the frame). Each or either of the molds <NUM>, <NUM> may have a mirror finish. In <FIG>, two sets of lenses are formed via the first mold <NUM>, and two frames are formed via the second mold <NUM>, one frame for each set of lenses.

A first screw <NUM>, operably connected to an extruder, provides the material to the first mold <NUM> and a second screw <NUM>, operably connected to an extruder, provides the material to the second mold <NUM>.

The injection molding machine <NUM> is configured to have both the first mold <NUM> and the second mold <NUM> to operate simultaneously; that is, both the first shot of material and the second shot of material are injected at the same time.

In one particular implementation of the molding processes, the parameters are as follows:.

For both the first shot and the second shot of the polymeric material, the viscosity of the polymeric material during the injection molding is dependent on the polymeric material itself, the molding temperature, and the mold configuration. For example, for the first shot (lenses), at a molding temperature of <NUM> the viscosity is about <NUM> Pa-s, at about <NUM> the viscosity is about <NUM> Pa-s, at about <NUM> the viscosity is about <NUM> Pa-s, and at about <NUM> the viscosity is less than <NUM> Pa-s. As another example, for the second shot (frame), at a molding temperature of <NUM> the viscosity is about <NUM> Pa-s, at about <NUM> the viscosity is about <NUM> Pa-s, at about <NUM> the viscosity is about <NUM> Pa-s, and at about <NUM> the viscosity is about <NUM> Pa-s.

It is noted that polymeric materials other than polycarbonate may be used for the lens and/or the frame. The material selection should be made taking into consideration molding capabilities, optical properties, and compatibility between the materials of the two shots.

Typically, the material for the lenses (for the sensor and illuminator) is IR transparent and optionally optically clear polycarbonate, although other IR transparent and optionally optically clear polymeric materials could be used. The lens material can be any amorphous thermoplastic material that is IR transparent and/or translucent, at least at wavelengths of <NUM>-<NUM>. Examples of suitable materials include polycarbonate (PC), acrylonitrile butadiene styrene (ABS), polystyrene (PS), polyethylene (PE), polylactic acid (PLA), polymethyl methacrylate (PMMA), any of various acrylics or polyamides (e.g., "Nylon"), and any mixtures and/or blends thereof. The polymeric material may be <NUM>% solids or may include a solvent. It is understood that adjuvants such as fillers, initiators, processing aids, pigments, etc. could be present in the polymeric material.

The material for the frame should have good opaque properties (e.g., OD4+), particularly for IR radiation. Because the frame is the second shot in the molding process, the material should have an equivalent or lower molding temperature than the lens material (first shot). The material also should have good bonding strength with the first shot material, so that no adhesives or other fastening or bonding mechanisms are used to retain the frame to the lenses. Similar to the lenses, examples of suitable materials for the frame include polycarbonate (PC), acrylonitrile butadiene styrene (ABS), polystyrene (PS), polyethylene (PE), polylactic acid (PLA), polymethyl methacrylate (PMMA), any of various acrylics or polyamides (e.g., "Nylon"), and any mixtures and/or blends thereof. The frame material may be colored any color. The polymeric material may be <NUM>% solids or may include a solvent. It is understood that adjuvants such as fillers, initiators, processing aids, pigments, etc. could be present in the polymeric material.

<FIG> show an example depth sensor window lens at various stages in the manufacturing process. In <FIG>, the result of the first shot is shown as a part <NUM>, in front view (<FIG>) and back view (<FIG>); this part <NUM> will eventually be the lenses, and in some implementations is formed by two discrete, unconnected parts. <FIG> shows the second shot, alone, as an as-molded frame <NUM>. However, according to the method described herein, the second shot is injected directed onto and around the first part <NUM>, forming the resulting as-molded part <NUM> of <FIG>, having both the part <NUM> and the as-molded frame <NUM>. The as-molded part <NUM> can be coated with a protective hardcoat on either or both the front and back side. After machining, trimming or other post-processing of the as-molded part <NUM> to remove extraneous material (e.g., with a CNC machine), either before or after any protecting hardcoat, the final product is shown in <FIG> as a depth sensor window lens <NUM>. This depth sensor window lens <NUM> can then be installed in an HMD, forming an integrated depth sensor window lens.

An example summary of the optical requirements for the finished part (lens + frame) are provided in Table <NUM> and in Table <NUM>. Table <NUM> provides properties for when polycarbonate is used for the lenses (first shot).

<FIG> are photomicrographs under a high resolution microscope of an example depth sensor window lens formed by a double-shot injection molding technique according to this disclosure using polycarbonate. <FIG> show the two-shot boundary on the back side of the part near the dam. Particularly, in <FIG>, two different views of a juncture of a lens <NUM> with a dam <NUM> are seen, this juncture being on the back surface of the lens <NUM>, proximate the periphery of the lens <NUM>. The region labeled <NUM> is not a feature of the depth sensor window lens but is the microscope support surface.

<FIG> shows the double-shot boundary on the front side. Particularly, in <FIG> the juncture of a first lens 910A and a second lens 910B with the dam <NUM> is seen as a "top-down" view along the front of the lenses 910A, 910B and the dam <NUM>, similar to the view of <FIG>. The juncture of the first lens 910A and the dam <NUM> forms a first valley 950A and the juncture of the second lens 910B, and the dam <NUM> forms a second valley 950B. The region labeled <NUM> is not a feature of the depth sensor window lens but is the microscope support surface.

As seen in <FIG>, even though using the two shot injection molding method of this disclosure, an identifiable, very shallow valley or valleys may exist at the juncture of the lenses and the dam. However, with an anti-reflection coating applied to the lenses and optionally to the dam, the junctures are not noticeable by naked eyes in the final product. Further, a black color to the dam and the lenses further masks the juncture valleys.

An example method includes injecting an optically clear polymeric material into a first mold to form a sensor lens and an illuminator lens, and injecting an opaque polymeric material into a second mold subsequent to the operation of injecting an optically clear polymeric material, the second mold defining a dam between the sensor lens and the illuminator lens and forming an as-molded part. The method also includes extracting the as-molded part from the second mold, the as-molded part having a front surface of the dam within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens.

Another example method, of any preceding method, uses a two-shot injection molding process.

Another example method, of any preceding method, is provided wherein the optically clear polymeric material includes IR transparent polycarbonate.

Another example method, of any preceding method, is provided wherein the opaque polymeric material includes polycarbonate. The opaque polymeric material may include polycarbonate having an optical density greater than <NUM>.

Another example method, of any preceding method, is provided wherein the opaque polymeric material includes polycarbonate and a second polymer.

Another example method, of any preceding method, is provided wherein the opaque polymeric material is black.

Another example method, of any preceding method, is provided wherein the optically clear polymeric material is translucent black.

Another example method, of any preceding method, is provided wherein the front surface of the sensor lens and the front surface of the illuminator lens have an RMS surface finish of no more than <NUM>.

Another example method, of any preceding method, is provided wherein each of the first mold and the second mold have a mirror surface finish.

Another example method, of any preceding method, further includes applying a hard coat coating to the sensor lens and the illuminator lens.

Another example method, of any preceding method, further includes trimming the as-molded part to form a depth sensor window lens.

An example depth sensor window lens includes a sensor lens including an IR transparent polymer having an RMS surface finish of no more than <NUM>, an illuminator lens including an IR transparent polymer having an RMS surface finish of no more than <NUM>, and a dam between the sensor lens and the illuminator lens. The dam includes an opaque polymer and has a front surface within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens.

Another example depth sensor window lens, of any preceding window lens, is provided wherein the dam has a width between the lenses of <NUM> or less.

Another example depth sensor window lens, of any preceding window lens, is provided wherein the front surface of the dam is within <NUM> of the front surface of the sensor lens and the front surface of the illuminator lens.

Another example depth sensor window lens, of any preceding window lens, is provided wherein the sensor lens and the illuminator lens include IR transparent polycarbonate, and the dam includes polycarbonate having an optical density greater than <NUM>.

Another example depth sensor window lens, of any preceding window lens, further includes a frame in contact with a periphery of the sensor lens and a periphery of the illuminator lens, the frame including the dam. The frame may contact a back surface of the sensor lens proximate the periphery and a back surface of the illuminator lens proximate the periphery.

An example head mounted device (HMD) for augmented reality (AR) or mixed reality (MR) includes a visor lens and a depth sensor window lens integrated into the visor lens. The depth sensor window lens includes a sensor lens including an IR transparent polymer having an RMS surface finish of no more than <NUM>. The depth sensor window lens also includes an illuminator lens comprising an IR transparent polymer having an RMS surface finish of no more than <NUM>. A dam is between the sensor lens and the illuminator lens, the dam including an opaque polymer and having a front surface within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens.

Another example depth sensor window lens, of any preceding window lens, further includes a frame in contact with a periphery of the sensor lens and a periphery of the illuminator lens, the frame including the dam.

An example system includes means for injecting an optically clear polymeric material into a first mold to form a sensor lens and an illuminator lens, and means for injecting an opaque polymeric material into a second mold subsequent to the operation of injecting an optically clear polymeric material, the second mold defining a dam between the sensor lens and the illuminator lens and forming an as-molded part. The system also includes means for extracting the as-molded part from the second mold, the as-molded part having a front surface of the dam within <NUM> of a front surface of the sensor lens and a front surface of the illuminator lens.

Another example system, of any preceding system, uses a two-shot injection molding process.

Another example system, of any preceding system, is provided wherein the optically clear polymeric material includes IR transparent polycarbonate.

Another example system, of any preceding method, is provided wherein the opaque polymeric material includes polycarbonate. The opaque polymeric material may include polycarbonate having an optical density greater than <NUM>.

Another example system, of any preceding system, is provided wherein the opaque polymeric material includes polycarbonate and a second polymer.

Another example system, of any preceding system, is provided wherein the opaque polymeric material is black.

Another example system, of any preceding system, is provided wherein the optically clear polymeric material is translucent black.

Another example system, of any preceding system, is provided wherein the front surface of the sensor lens and the front surface of the illuminator lens have an RMS surface finish of no more than <NUM>.

Another example system, of any preceding system, is provided wherein each of the first mold and the second mold have a mirror surface finish.

Another example system, of any preceding system, further includes a means of applying a hard coat coating to the sensor lens and the illuminator lens.

Another example system, of any preceding system, further includes a means of trimming the as-molded part to form a depth sensor window lens.

The above specification and examples provide a complete description of the process and use of example implementations of the invention. The above description provides specific implementations. It is to be understood that other implementations are contemplated and may be made without departing from the scope as set out in the appended set of claims.

Unless otherwise indicated, all numbers expressing feature sizes, amounts, and physical properties are to be understood as being modified by the term "about. " Accordingly, unless indicated to the contrary, the numerical parameters set forth are approximations that can vary depending upon the desired properties sought to be obtained by those skilled in the art utilizing the teachings disclosed herein.

As used herein, the singular forms "a," "an," and "the" encompass implementations having plural referents, unless the content clearly dictates otherwise.

Spatially related terms, including but not limited to, "lower," "upper," "beneath," "below," "above," "on top," etc., if used herein, are utilized for ease of description to describe spatial relationships of an element(s) to another. Such spatially related terms encompass different orientations of the device in addition to the particular orientations depicted in the figures and described herein. For example, if a structure depicted in the figures is turned over or flipped over, portions previously described as below or beneath other elements would then be above or over those other elements.

Claim 1:
A method for making a depth sensor window lens, the method comprising:
injecting an optically clear polymeric material into a first mold (<NUM>) to form a sensor lens (<NUM>) and an illuminator lens (<NUM>) of the depth sensor window lens;
injecting an opaque polymeric material into a second mold (<NUM>) subsequent to the operation of injecting an optically clear polymeric material, the second mold (<NUM>) defining a dam (<NUM>) between the sensor lens (<NUM>) and the illuminator lens (<NUM>) and forming an as-molded part (<NUM>); characterized in that the method further comprises
extracting the as-molded part (<NUM>) from the second mold (<NUM>), the as-molded part (<NUM>) having a front surface of the dam (<NUM>) within <NUM> of a front surface of the sensor lens (<NUM>) and a front surface of the illuminator lens (<NUM>),
wherein the depth sensor window lens further comprising a frame (<NUM>) in contact with a periphery of the sensor lens and a periphery of the illuminator lens, the frame including the dam.