NZ790308A - Compliant mounting arm - Google Patents
Compliant mounting arm Download PDFInfo
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- NZ790308A NZ790308A NZ790308A NZ79030817A NZ790308A NZ 790308 A NZ790308 A NZ 790308A NZ 790308 A NZ790308 A NZ 790308A NZ 79030817 A NZ79030817 A NZ 79030817A NZ 790308 A NZ790308 A NZ 790308A
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- Prior art keywords
- wall
- compliant
- rib
- ribs
- arm
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- 210000000614 Ribs Anatomy 0.000 claims abstract 43
- 238000007906 compression Methods 0.000 claims 3
- 239000000463 material Substances 0.000 claims 3
- 230000000875 corresponding Effects 0.000 claims 2
- 229920001169 thermoplastic Polymers 0.000 claims 1
- 239000004416 thermosoftening plastic Substances 0.000 claims 1
Abstract
Disclosed is a compliant arm, comprising an outer wall, an inner wall, a wall bridge connecting the inner wall and the outer wall, and a plurality of ribs connecting at least the outer wall and the inner wall. A rib of the plurality of ribs comprises a straight segment along a longitudinal direction and a thickness that is normal to a plane on which the longitudinal direction is located. The outer wall, the inner wall, and the wall bridge are arranged to form a loop structure having one or more openings. The straight segment of the rib and the loop structure are connected together to form a planar structure. The planar structure corresponds to the plane and further corresponds to a deformation profile upon which at least a size or a shape of the loop structure or the rib is determined for accommodating multiple head sizes or head shapes. The outer wall, the inner wall, the wall bridge, and the plurality of ribs selectively distribute, based at least in part upon the deformation profile, a load by a deformation of at least one of the inner wall, the outer wall, or the straight segment of the rib of the plurality of ribs with respect to the plane due to a load along the longitudinal direction of the straight segment. and a thickness that is normal to a plane on which the longitudinal direction is located. The outer wall, the inner wall, and the wall bridge are arranged to form a loop structure having one or more openings. The straight segment of the rib and the loop structure are connected together to form a planar structure. The planar structure corresponds to the plane and further corresponds to a deformation profile upon which at least a size or a shape of the loop structure or the rib is determined for accommodating multiple head sizes or head shapes. The outer wall, the inner wall, the wall bridge, and the plurality of ribs selectively distribute, based at least in part upon the deformation profile, a load by a deformation of at least one of the inner wall, the outer wall, or the straight segment of the rib of the plurality of ribs with respect to the plane due to a load along the longitudinal direction of the straight segment.
Description
COMPLIANT MOUNTING ARM
FIELD OF DISCLOSURE
The present application generally relates to headset designs for interactive virtual and
augmented reality devices.
BACKGROUND
Modern computing and y technologies have facilitated the pment of
systems for so called “virtual y” or “augmented y” experiences, wherein digitally
reproduced images or portions thereof are presented to a user in a manner wherein they seem to
be, or may be perceived as, real. A virtual reality, or “VR”, scenario typically involves
presentation of digital or virtual image information without transparency to other actual real-
world visual input; an augmented y, or “AR”, scenario typically involves presentation of
l or virtual image information as an augmentation to visualization of the actual world
around the user.
VR or AR systems lly use headsets as the structure to mount components that
provide a user with the visual and sometimes auditory ns of the VR/AR experience. These
components may include, for example: one or more cameras to capture pictures and videos of the
user’s surrounding; one or more devices to project images and videos inward towards the user
(e.g., lenses, video projectors, etc.); one or more sensors for sensing motion and direction; and
one or more electronic computing devices to capture, render and display images and/or videos.
While these additional components may be small and light weight individually, the combination
of the components will add considerable additional weight to the headset. Even worse, the
additional weight is usually towards the front of the headset and this additional weight is
generally supported by the nose bridge of the wearer.
ed or even short use of the headset can be uncomfortable on a wearer’s nose
bridge since the headset is heavy with all of the additional components affixed to the headset and
coupled with the fact that most of the onal weight tend to be forward facing. Additionally,
the headset must be securely ed to the wearer’s head to operate effectively (e.g., for sensor
positioning purposes, video captures, etc.)
Legacy headset designs typically employ one or more straps to securely attach the
headset to the head of a wearer. The straps are generally adjustable and elastic. The adjustability
of the straps allows for varying head sizes and shapes of different wearers. The elasticity of the
straps s the headset to a wearer’s head and may also ct some of the weight of the
headset from a wearer’s nose bridge to the wearer’s head. However, the use of straps provides its
own challenges: it is cumbersome to adjust, it is cumbersome to put on and take off the headset,
the straps may need to be tightened in order to maintain a secure fit between the headset and a
wearer’s head, and finally, depending on the weight of the headset itself, the strap may need to
be r tightened to ensure the headset does not provide too much weight to a wearer’s nose
bridge.
ore, there is a need for an improved headset that selectively redistributes the
weight of the t from the wearer’s nose bridge to the wearer’s head while securely
ering the headset to the wearer’s head.
The subject matter sed in the background section should not be assumed to be
prior art merely as a result of its mention in the background section. rly, a problem and the
understanding of the causes of a problem mentioned in the background section or associated with
the t matter of the ound section should not be d to have been previously
recognized in the prior art. The subject matter in the background section may merely represent
different ches, which in and of themselves may also be disclosures.
SUMMARY
Embodiments of the disclosure provide an improved apparatus to provide a retaining
force to keep a headset secured comfortably on the wearer’s head. The headset comprises one or
more ant mounting arms to allow for secure attachment of the headset to a wearer’s head
without the need for straps or levers. The compliant mounting arms provide a normalizing force
to selectively distribute the load from the wearer’s nose bridge to the forehead and other areas of
the wearer’s head. The compliant mounting arms may selectively distribute the load along the
strongest structural portions of the skull. Comfort may be achieved by selective distribution of
the load in various forms such as a uniform or near m distribution of the load (i.e. no point
loads) and/or a non-uniform distribution of the load near and around certain points of the
ant mounting arm.
In one embodiment, a headset includes one or more compliant arms, and a frame,
wherein the one or more compliant arms are coupled to the frame, and wherein the ant
arms selectively distribute a weight of the headset.
In one or more embodiments, the one or more compliant arms may uniformly
distribute a weight of the headset. The one or more compliant arms may also non-uniformly
distribute a weight of the headset. The one or more compliant arms may also be the same size
and shape. The one or more compliant arms may also be adjustable on a multi-axis. The one or
more compliant arms may also be adjustable along a variety of angles along a horizontal plane.
The one or more compliant arms and the frame may be ucted as one single body, wherein
the one or more ant arms may be adjustable on a multi-axis.
In one or more embodiments, the headset may include two upper compliant arms, two
compliant arms, and one frame, n the two upper compliant arms and the two ant
arms are adjustable on a multi-axis. The one or more complaint arms may be joined by a
connector comprising a spool type . The one or more compliant arms may include an
upward bend. The headset may be a virtual reality or augmented reality headset.
In another embodiment, a compliant arm may include an outer wall, an inner wall, a
wall bridge, and a plurality of ribs connecting the outer wall, the inner wall, and the wall bridge,
n the outer wall, the inner wall, the wall bridge and the plurality of ribs selectively
distribute a load by an elastic body ation.
In one or more embodiments, the compliant arm may be a single body. The compliant
arm may be constructed from a same material. The same material may be a thermoplastic. The
compliant arm may be adjustable on a multi-axis when coupled to a frame. The compliant arm
may be vertically adjustable when coupled to a frame. The compliant arm may be horizontally
adjustable when coupled to a frame.
In one or more embodiments, the plurality of ribs may be of varying lengths. Each rib
of the plurality of ribs may correspond to a ent slenderness ratio. Each rib of the plurality of
ribs may be a different thickness. A thickness of a rib from the plurality of ribs may be varying
throughout the rib. One or more ribs from the plurality of ribs may have varying widths.
In one or more embodiments, the outer wall and the plurality of ribs may be
constructed of different materials. The inner wall may be in compression, the outer wall may be
in tension, the wall bridge may be in compression and tension, and each of the plurality of ribs
may be in either tension or ssion when a load is applied to the compliant arm. An arm
width of the compliant arm may be a varying width at different points along the inner wall.
[0015A] In another embodiment there is provided a headset comprising: a ant arm
having a rib and a loop structure that comprises one or more openings, n the rib comprises
ht segment along a longitudinal direction and a thickness that is normal to a plane on which
the longitudinal direction is located, and the loop ure and the straight segment of the rib
form a planar structure that corresponds to the plane; and a frame to which the compliant arm is
adjustably attached, wherein the planar structure comprising the loop structure and the rib
corresponds to a deformation profile upon which at least a size or a shape of the loop structure or
the rib is determined for odating multiple head sizes or head shapes, the planar structure
of the compliant arm distributes at least a portion of a weight of the t with at least a
deformation of at least the rib or the loop structure based at least in part upon the deformation
profile, and the plane on which at least a portion of the planar structure is located, when the
headset is placed on a head of a user, is normal to a portion of a circumferential contour of the
head of the user in contact with the planar structure.
[0015B] In another embodiment there is provided a headset comprising: a first pair of upper
ant arms that, when the headset is placed on a head of a user, extends over a top of the
head of the user of the headset; a second pair of lower compliant arms that, when the headset is
placed on the head of the user, extends over a back of the head of the user, wherein a compliant
arm of the first and second pairs ses a rib and a loop structure that comprises one or more
openings, the rib comprises a straight segment along a longitudinal direction and a thickness that
is normal to a plane on which the longitudinal direction is located, the loop structure and at least
the straight segment of the rib are configured to form a planar structure, and the planar structure
corresponds to the plane and r corresponds to a deformation profile upon which at least a
size or a shape of the loop structure or the rib is ined for accommodating multiple head
sizes or head shapes; and a frame coupled to the first and second pairs, wherein the first and the
second pairs, when the headset is placed on the head of the user, bute, based at least in part
upon the deformation profile, a weight of the headset with at least a deformation of at least the
rib of the compliant arm, and the plane on which at least a portion of the planar structure is
located, when the headset is placed on the head of the user, is normal to a portion of a
ferential contour of the head of the user in contact with the planar structure.
[0015C] In another embodiment there is provided a compliant arm, comprising: an outer
wall; an inner wall; a wall bridge connecting the inner wall and the outer wall; and a plurality of
ribs connecting at least the outer wall and the inner wall, wherein a rib of the plurality of ribs
comprises a straight segment along a longitudinal ion and a thickness that is normal to a
plane on which the longitudinal ion is located, the outer wall, the inner wall, and the wall
bridge are arranged to form a loop structure having one or more openings, the straight segment
of the rib and the loop structure are ted together to form a planar structure, the planar
structure corresponds to the plane and further corresponds to a deformation profile upon which
at least a size or a shape of the loop structure or the rib is ined for accommodating
multiple head sizes or head shapes, and the outer wall, the inner wall, the wall bridge, and the
plurality of ribs selectively distribute, based at least in part upon the deformation profile, a load
by a deformation of at least one of the inner wall, the outer wall, or the straight segment of the
rib of the plurality of ribs with respect to the plane due to a load along the longitudinal direction
of the straight segment.
Each of the individual embodiments described and illustrated herein has discrete
ents and features that may be y separated from or combined with the components
and features of any of the other several embodiments.
Further details of features, objects, and advantages of the disclosure are described
below in the detailed description, drawings, and claims. Both the foregoing general ption
and the following detailed description are exemplary and explanatory, and are not intended to be
limiting as to the scope of the disclosure.
BRIEF DESCRIPTION OF THE DRAWINGS
The drawings illustrate the design and utility of various embodiments of the present
disclosure. It should be noted that the figures are not drawn to scale and that elements of similar
structures or functions are represented by like reference numerals throughout the s. In
order to better appreciate how to obtain the above-recited and other advantages and objects of
various embodiments of the sure, a more detailed description of the present disclosures
briefly described above will be rendered by reference to specific ments thereof, which are
illustrated in the accompanying drawings. Understanding that these drawings depict only typical
embodiments of the disclosure and are not therefore to be considered limiting of its scope, the
disclosure will be described and explained with additional icity and detail through the use
of the accompanying drawings in which:
Fig. 1A illustrates a perspective view of an e headset for selectively
distributing a load to a ’s head while securely ering the headset to the head ing
to some embodiments of the disclosure.
Fig. 1B illustrates a top view of an example t for selectively distributing a load
to a wearer’s head while securely registering the headset to the head according to some
ments of the sure.
Fig. 1C illustrates a side view of an example headset for selectively distributing a
load to a wearer’s head while securely registering the headset to the head according to some
ments of the disclosure.
Fig. 1D illustrates a front view of an example headset for selectively distributing a
load to a wearer’s head while securely registering the headset to the head according to some
embodiments of the disclosure.
Fig. 1E illustrates a perspective view of an alternative example headset for selectively
distributing a load to a wearer’s head while securely ering the headset to the head according
to some embodiments of the disclosure.
Fig. 1F illustrates a side view of an alternative example headset for selectively
distributing a load to a wearer’s head while securely registering the headset to the head according
to some embodiments of the disclosure.
Fig. 2A illustrates a ctive view of an example of a compliant arm according to
some embodiments of the disclosure.
Fig. 2B illustrates a top view of an example of a ant arm according to some
embodiments of the disclosure.
Fig. 2C illustrates a bottom view of an example of a compliant arm according to some
embodiments of the sure.
Fig. 2D illustrates a side view of an example of a compliant arm according to some
embodiments of the disclosure.
Fig. 3 illustrates an example of how a ant arm deforms and selectively
distribute a load according to some embodiments of the disclosure.
Fig. 4 illustrates an example of how the weight of a headset on a wearer’s head may
be redistributed by using a compliant mounting arm according to some embodiments of the
disclosure.
Fig. 5 illustrates an example of a virtual reality / augmented reality headset using a
compliant arm according to some embodiments of the disclosure.
Fig. 6 illustrates an example of a virtual reality / augmented reality headset according
to some embodiments of the disclosure.
Fig. 7 illustrates a side view of a virtual reality / augmented reality headset ing
to some embodiments of the disclosure.
DETAILED DESCRIPTION
Various ments will now be bed in detail with reference to the drawings,
which are provided as rative examples of the disclosure so as to enable those skilled in the
art to practice the disclosure. Notably, the figures and the examples be low are not meant to limit
the scope of the present disclosure. Where certain ts of the present disclosure may be
partially or fully implemented using known components (or methods or processes), only those
ns of such known components (or methods or processes) that are necessary for an
understanding of the present disclosure will be described, and the ed descriptions of other
portions of such known components (or s or processes) will be omitted so as not to
obscure the sure. Further, various embodiments encompass present and future known
equivalents to the components referred to herein by way of illustration.
The apparatuses sed herein address selectively distributing weight from a
headset while securely attaching the headset to the wearer’s head without the use of . This
is achievable by affixing one or more compliant mounting arms onto the headset, wherein the
headset comprises the components required to provide a wearer with a le computing
headset, for example, to interact with the VR or AR ence.
There are many different bases on how to selectively adjust the distribution of a load.
Therefore, there are many types of results that can be achieved by selectively distributing a load.
For example, one result that can be achieved is a m or near uniform bution of the
load. By no means is the prior example the only type of result for selectively distributing a load.
For example, another type of result may be dependent on the shape of a person’s head. In this
situation, it may be beneficial to distribute a load to certain point loads at certain locations along
the compliant arm, which may achieve certain types of non-uniform loading results by simply
pinpointing different points along the compliant mounting arm to distribute the load.
Figs. 1A- 1D illustrates multiple views of an example headset for ively
distributing a load to a wearer’s head while securely registering the headset to the head according
to some embodiments of the sure. Fig. 1A illustrates a perspective view, Fig. 1B illustrates
a top view, Fig. 1C a side view, and Fig. 1D rates a front view of the example headset for
selectively distributing a load to a ’s head while securely registering the headset to the
wearer’s head according to some embodiments of the disclosure.
Headset 100 is employed to selectively distribute a load onto a wearer’s head,
according to some embodiments. Headset 100 provides this ability to selectively distribute
weight while still ly registering the headset and its components to the wearer’s head.
Headset 100 comprises ant arms 110, frame 140, forehead pad 150, and nose
bridge 160. Compliant arms 110 are compliant mechanisms, wherein compliant arms 110
transfer an input force to another point through elastic body deformation. In some embodiments,
compliant arms 110 may be the same size and shape. In some ments, compliant arms 110
may be g size and shape between a left ant arm and a right compliant arm, based at
least in part on a deformation profile. In some embodiments, the compliant arms may be joined
by a connector having a spool type spring, wherein the spool type spring provides a compression
force for fitting adjustments for different head sizes instead of compression force for constricting
the compliant arms and headset to a user’s head. In such embodiments, the frame, ant
arms, and connector wrap around the user’s head. As an example for this application, compliant
arms 110 will be assumed to be the same shape and size for ease of explanation. However, one of
ordinary skill in the art appreciates the compliant arms 110 may not be the same shape and size
because of varying ation profiles.
Frame 140 is a structure that holds certain components affixed to the frame 140 in
front of a person’s eyes. Frame 140 may comprise VR / AR components, for example sensors,
cameras, electronic components, etc. Frame 140 also comprise forehead pad 150 and nose bridge
160. Frame 140 may include a temple that rests on the ears and allow the headset to transfer
some of the weight of the headset onto the ears. Frame 140 may also have elastic features, for
example, flexible points 130 to ly register the temple arms of frame 140 into the side of a
’s head to provide some transfer of the weight of the headset 100 onto the side of a
wearer’s head. Flexible points 130 may be of a pre-formed flexible member designed to bend
and unbend depending on an applied force, such as, for example, a pair of round
sunglasses with no hinges between its temple arm and its eyeglass frame. In some embodiments
(not shown in the figures), a compliant temple may be used to provide a uniform distribution of
the weight of the t along the side of a wearer’s head, in on to the compliant arms that
may be used to provide a ive distribution of the weight of the headset towards anchor
points/bones of the ’s head.
In some embodiments of the disclosure (as ed in Figs. 1A – 1D), there may be
two or more compliant arms 110 coupled to one frame 140. For es of this discussion, for
example, a headset 100 comprising two compliant arms 110 and one frame 140 will be further
described.
In some embodiments, there may be only one forehead pad 150. In other
embodiments (as shown in Fig. 1A – 1B), there may be one or more forehead pads 150.
Forehead pad 150 may take away some of the weight of headset 100 when there are ve
forces pulling the headset 100 towards the rear of the wearer’s head, e.g., when the compliant
arms 110 are creating a selectively distributed force on a wearer’s head, the counter force may be
on the forehead pad 150 to the wearer’s forehead.
Compliant arms 110 may be adjustable on a multi-axis (e.g., vertical plane and/or
horizontal plane) when coupled to the frame 140. For example, compliant arms 110 may be
adjustable along a variety of adjustable angles 180 along a horizontal plane (a plane relative to
how the arm is connected to the frame) to allow the compliant arms 110 to contact a wearer’s
head at a particular angle which may be suitable for most head sizes and shapes or which may be
required due to a particular deformation profile, as shown in Figs. 1A and 1B. The y to
adjust the lower compliant arms along adjustable angle 180 allows the wearer flexibility of
setting an initial fit. The setting of the adjustable angle 180 for the initial fit may be by snapping
the compliant arms 110 into place, spring-loaded detents, a screw in feature, other mechanism, or
a ary set of compliant mechanisms that adjusts the adjustable angle 180 of the compliant
arms 110. The compliant arms 110 may also be displaced or distorted along the same horizontal
plane once the headset 100 is applied onto a wearer’s head. This cement or distortion along
the horizontal plane allows the compliant arm to selectively distribute a point load along its
flexible structure to the wearer’s head, which in turn create reactive forces against forehead pad
150 to redistribute weight from the headset from a wearer’s nose bridge to other areas of the
wearer’s head.
In some ments, compliant arms 110 may be adjustable along another axis such
as a horizontal axis such that the compliant arms 110 may be adjustable in a al plane about
the horizontal axis. Compliant arms 110 may be adjustable along a variety of adjustable angle
190 along a vertical plane (a plane relative to how the arm is coupled to the frame) as shown in
Fig. 1C. The ability to adjust compliant arms 110 along a variety of adjustable angle 190 may be
important according to some embodiments. For example, the majority of the weight from headset
100 may need to be selectively distributed from the wearer’s nose bridge and ears to the
compliant arms 110 and forehead pad 150. In this situation, it may be cial to be able to
adjust the compliant arms 110 by a variety of angles along adjustable angle 190 along the
vertical plane to further allow compliant arms 110 to selectively distribute the weight from
headset 100. One of ordinary skill in the art appreciates although the t example discloses a
headset where most of the weight is towards the front of the headset, the same t can be
used to design compliant arms to selectively bute a load wherever the load concentration
may be on the headset, whether it is, for example, towards the front, the , or the rear of the
headset.
Figs. 1E – 1F illustrate a perspective and side view, respectively, of an alternative
example headset for selectively distributing a load to a wearer’s head while securely registering
the headset to the head according to some embodiments of the disclosure.
As shown in Figs. 1E – 1F, headset 100a is a similar embodiment of headset 100
described in Figs. 1A – 1D. t 100a comprises upper ant arms 120. Upper compliant
arms 120 are compliant mechanisms such as compliant arms 110. Upper compliant arms 120
may provide additional selective distribution of the weight of the headset on a wearer’s head. In
some embodiments, headset 100a comprises one or more frame adapter 130.
Frame r 130 is an adapter that couples the compliant arms to the frame 140. In
some embodiments, only the compliant arms 110 are coupled to a frame adapter 130. In other
embodiments, both the compliant arms 110 and the upper compliant arms 120 are coupled to the
frame adapter 130. In other embodiments, a compliant arm 110 and a plurality of upper
compliant arms 120 are coupled to the frame r 130. Yet in other embodiments, the
compliant arm(s) and the frame adapter 130 may be constructed as a single body. In the
event the upper ant arms 120 and/or the compliant arm 110 is coupled to the frame
adapter 130, the compliant arms may be coupled to the frame adapter using different types of
attachments such as, for example, bolt-on arms, snap on arms, rotatable snap-fit arms, ting
features, and an ible arm-mount or central component to disclose just a few. One of
ordinary skill in the art appreciates there may be other types of attachments to couple a compliant
arm to the frame adapter 130.
Frame adapter 130 may be rigidly ed onto the frame 140 using various
techniques such as, for example, sliding or snapping the frame adapter 130 onto the temple arms
of the frame 140. In some embodiments, frame adapter 130 having the compliant arm(s) and the
frame 140 may be a single piece. In other embodiments, frame adapter 130 may be adjustable
along the frame 140 to allow varying head sizes and shapes of different wearers. One of ordinary
skill in the art appreciates there are many other ways to attach the frame adapter 130 to the frame
Upper compliant arms 120 may be adjustable on a multi-axis (e.g., vertical plane
and/or ntal plane with respect to how the arm is coupled to the frame) when coupled to
frame 140 or to frame adapter 130. Upper compliant arms 120 may be adjustable along a variety
of adjustable angle 170 along a horizontal plane (e.g., a plane ve to how the arm is coupled
to the frame) to allow the upper compliant arms to contact a wearer’s head at a particular angle
which may be suitable for most head sizes and shapes or which may be required due to a
particular deformation profile. The ability to adjust the upper compliant arms along adjustable
angle 170 allows the wearer flexibility of setting an initial fit. The setting of the able angle
170 for the initial fit may be by snapping the upper compliant arms 120 into place, spring-loaded
detents, a screw in feature, other mechanism, or a secondary set of compliant isms that
adjusts the adjustable angle 170 of the upper ant arms 120. The compliant arms may also
be displaced or distorted along the same vertical plane as adjustable angle 170 once the headset
100a is applied onto a wearer’s head. In some embodiments, it is this displacement or distortion
of force or weight along adjustable angle 170 that allows the compliant arm to ively
distribute a point load along its flexible structure to the wearer’s head.
In some embodiments, upper ant arms 120 may be adjustable on a multi-axis
(e.g., vertical plane and/or horizontal plane with respect to how the arm is coupled to the frame)
when coupled to frame 140 or frame r 130. For example, upper compliant arms 120 may
be adjustable along adjustable angle 195 along a vertical plane as shown in Fig. 1F. The ability
to adjust upper compliant arms 120 along adjustable angle 195 may be important if frame
adapter 130 is adjustable forward or rd with respect to the frame 140 in order to maintain
a particular angle of t between the upper compliant arm 120 and the wearer’s head to
avoid having n edges of the upper compliant arms 120 in direct contact with the wearer’s
head. Furthermore, the ability to adjust the upper compliant arms 120 along adjustable angle 195
may also help e the uniformity of the distribution of weight from the upper compliant
arms 120 to the wearer’s head.
Headset 100a in Figs. 1E – 1F contains two ions from headset 100 shown in
Figs 1A – 1D. The two variations are frame adapter 130 and upper compliant arms 120. The two
additional variants (e.g., frame adapter 130 and upper compliant arms 120) are independent
variations of headset 100. Headset 100 may operate independently of and do not need to have
frame adapter 130 and/or upper compliant arms 120. Headset 100a describes ative
examples of how a headset 100 may be configured.
Compliant mechanisms are flexible isms that transfer an input force or
displacement to another point through elastic body. ant mechanisms can be designed to
transfer an input force ively across predetermined portions of its elastic body through
deformation. Compliant mechanisms are elastic. Compliant mechanisms gain at least some of
their mobility from the deflection of flexible members rather than from movable joints. Since
compliant mechanisms rely on the deflection of flexible members, energy is stored in the form of
strain energy in the flexible members. This stored energy is similar to the potential energy in a
deflected spring, and the effects of springs may be integrated into a compliant mechanisms
design to distribute an applied load. This can be used to easily store and/or transform energy to
be released at a later time or in a different manner. A bow and arrow system is a simple example
of this. Energy is stored in the limbs as the archer draws the bow. This ial energy is then
transformed to kinetic energy of the arrow. These energy storage characteristics may also be
used to design for specific force-deflection properties, or to cause a mechanism to tend to
particular positions.
Compliant mechanisms are designed specifically to transfer an input force or
displacement at one point of the mechanism to another point through elastic body deformation. A
compliant mechanism may be designed based on a deformation e and a slenderness ratio.
A deformation profile is the geometry obtained by an object after a prescribed loading
is applied. For some embodiments, a deformation profile may be one that matches as closely as
possible to the e or geometry or contour of a wearer’s head. Additionally, a point load
d to a fixed position of a compliant mechanism may be ed to non-uniformly or
uniformly/near-uniformly bute the load across the compliant mechanism through elastic
body deformation based at least in part on a deformation profile. For example, the deformation
profile of a compliant ng arm may be designed to deform the compliant arm along the
contour of a wearer’s head while selectively distributing a normalizing load of the point load
across the arm and onto the wearer’s head.
In some embodiments (non-uniform distribution), the deformation of the compliant
arm may distribute point loads of the load to particular pinpoint locations on the compliant arm
to non-uniformly distribute the load as a point load to an anchor point/bone on a wearer’s head.
The anchor point/bone may be a strong bone structure that can withstand a load without
fort, for example, the occipital bone, al bone, mastoid/styloid process, and ridge
along the parietal bone.
In some embodiments, the deformation of the ant arm rm/near-uniform
distribution) may wrap around a wearer’s head to uniformly/near-uniformly distribute the
normalizing force onto the wearer’s head. For a compliant ism, the design of the
compliant mechanism may allow the transformation of the single point load via c body
deformation of the entire compliant mechanism. This may be desired so that a single point load
is not just erred as another single point load, but instead, distributed as uniformly as
possible across multiple points of the compliant mechanism body.
One of ordinary skill in the art appreciates a compliant mechanism can be designed to
either uniformly or non-uniformly distribute a load. In some embodiments, a compliant
mechanism may be designed to achieve both types of load distribution results, wherein certain
portions of the compliant arm may be designed to uniformly distribute a portion of the load while
other portions of the compliant arm may be ed to non-uniformly distribute a portion of the
load to an anchor point/bone.
An embodiment of a compliant arm will be discussed vis-à-vis Figs. 2A - 2D.
Figs. 2A - 2D illustrates multiple views of an example of a ant arm according
to some embodiments of the disclosure. Fig. 2A illustrates a perspective view, Fig. 2B illustrates
a top view, Fig. 2C illustrates a bottom view, and Fig. 2D illustrates a side view on a compliant
Compliant arm 200 is a compliant mechanism designed to selectively distribute a
point load to other points of the compliant arm 200 through elastic body deformation. As
sed in Figs. 1A-1D, compliant arm 200 may be a compliant arm 110.
Outer wall 210 is the outer wall of the compliant arm 200 that does not come in direct
contact with the wearer’s head. The outer wall 210 is a flexible member with structural strength.
Outer wall 210 may be in compression or tension, depending on the force that is introduced to
the compliant arm 200. Inner wall 220 is the portion of compliant arm 200 that comes in direct
contact with the wearer’s head. Inner wall 220 is a flexible member with some structural
th. Inner wall 220 may be in compression or tension, depending on the force that is
introduced to the ant arm 200.
In some ments, rib 230 is flexible member with structural rigidity. In some
embodiments, rib 230 is anchored to outer wall 210 and inner wall 220 at either end of rib 230.
As a load is applied to a compliant arm 200 with flexible rib 230, the flexible rib 230 deforms
ing to its particular slenderness ratio and modulus, thereby distributing amount of the load
incident to a given rib 230 location in compliant arm 200.
In some embodiments, rib 230 is rigid and does not deform under application of loads
to compliant arm 200, that is, inner wall 220 and outer wall 220 deform but rib 230 does not
deform and instead shifts its orientation by solid body rotation in response to an applied load. In
such embodiments, rib 230 adjusts orientation between outer wall 210 and inner wall 220
through hinges (not depicted) coupling either end of rib 230 to outer wall 210 and inner wall 220.
Loads are thus distributed along ant arm 200 in the direction and in proportion to the
vector orientation of a rigid rib 230 under such solid body rotation.
A compliant arm 200 may have one or more rib 230 to achieve a desired deformation
profile. Rib thickness 290 is the thickness of a particular rib 230. Rib length 295 is the length of
a particular rib 230. Rib 230 may be of varying length and/or thickness depending on a desired
slenderness ratio.
A rness ratio is the ratio of the length of a column and the least radius of
on of its cross section. It is used extensively for finding out the design load as well as in
fying s columns in short / intermediate / long. In some embodiments, each rib may
have its own slenderness ratio to produce a non-uniform distribution of a load. In some
embodiments, there may be a constant slenderness ratio applied to a plurality of the ribs to
produce a more mly/near-uniformly distribution of a load. Therefore, the rness ratio
is a quantifiable metric for the relative amount of flex to rib 230 given an input load to the
compliant arm 200.
The longer the rib, the more flexibility it will have over a r shorter rib. In some
embodiments, a rib may have varying thickness 290 throughout its length 295 to achieve a
desired deformation profile. For example, the base of a rib 230 (the connection to the inner wall)
may have a thickness greater or less than the top of the rib 230 (the connection to the outer wall).
In some embodiments, the base of a rib 230 and the top of the rib 230 may have a greater rib
thickness 290 than rest of the length of the rib to avoid stress concentration where the ribs meet
the walls. In such an embodiment, this is d because the ribs are meant to flex such that they
create a relative deformation between the inner wall 220 and the outer wall 210. Rib 230 may
also be variably spaced between another rib 230 depending on the targeted deformation profile to
achieve as much of a uniform distribution of load along the inner wall 220 and a wearer’s head.
During application of a load on the compliant arm 200, one or more of the rib 230 may be in
compression or in tension. In some embodiments one or more rib 230 may be in compression
while one or more other rib 230 within the same compliant arm 200 may be in n. The one
or more rib 230 may be perpendicularly connected to inner wall 220 to maintain a contour line to
match of a wearer’s head. The length of a rib 230, the spacing between the ribs, and the rib
thickness 290 of a rib 230 are les that can be modified to achieve a desired deformation
profile to selectively distribute a load.
Wall bridge 240 is the last rib most opposite from mounting hole 250. In some
embodiments, wall bridge 240 may be more rigid than ribs 230 to provide added strength
nt to an anchor bone on a wearer’s head. The anchor point being strong bones, for
example, the occipital bone, temporal bone, d/styloid process, and ridge along the parietal
bone. Higher relative rigidity of wall bridge 240 ensures outer wall 210 and inner wall 220 have
mentary tension and compression at a given point when subject to an input force.
Mounting hole 250 is an arbitrary mounting hole to attach the compliant arm 200 to a frame (see
Figs. 1A-1D).
In some embodiments a mounting hole 250 may not exist, such as, for example, when
the ant arm 200 and the frame 140 may be a single piece. In other embodiments, the
ng hole 250 may not be a mounting hole, but instead an alternate mounting structure such
as, for example, a ball and socket, a snap on attachment, etc. In some embodiments, mounting
hole 250 may not be a mounting hole altogether, but a mounting structure instead. For example,
a mounting structure may be a ball and socket structure, where mounting hole 250 may be a ball
in a ball and socket attachment structure.
Thus, mounting hole 250 is an arbitrary mounting hole for the purpose of explanation
of the compliant arm 200.
In some embodiments, the first rib 230, the rib that is directly above the mounting
hole 250 per Fig. 2B, may be the thickest, longest and least le of all of the ribs in a
compliant arm 200. This first rib 230 provides varying counteracting force against the rest of the
compliant arm 200 structure. If the first rib 230 is thin and very flexible and there is an upward
force applied to the wall bridge, the entire compliant arm 200 may rotate over the point of the
mounting hole 250 and the first rib will be completely compressed and thus creating a potential
rotation of the compliant arm 200 over the mounting hole and deform the structure such that the
compliant arm 200 does not deform to the contours of a wearer’s head. However, if the first rib is
somewhat rigid, then the entire arm would not rotate over the mounting hole, but instead, create
a counter force on the rest of the compliant arm 200 to redistribute the load across the compliant
arm ure to deform the other ents such as, for example, the other ribs, outer wall,
inner wall and the wall bridge to achieve a desired deformation profile of wrapping the
compliant arm 200 around the rs of the wearer’s head while distributing a counter acting
force against a single point load across the inner wall and evenly onto the wearer’s head.
In some embodiments, a constant slenderness ratio for each of ribs 230 may in
a relatively uniform force across compliant arm 200 through the controlled buckling/bending of
the ribs to drive the relative motion of the inner wall 220 and outer wall 210. For example, even
though the ribs may have varying s and thicknesses, they may be designed to support a
m distribution of load. In other embodiments, with a g slenderness ratio at any one
rib, the distribution of force may be non-uniform. For example, if an early rib has a higher
slenderness ratio than a later rib (an early rib being a rib closer to the front of the headset 100 and
a later rib being a rib closer to the rear of headset 100) then the early rib would deform more than
the later rib with a lower slenderness ratio and therefore would distribute more force, as an
example, on the end towards the wall bridge 240. Furthermore, the wall bridge 240 may apply
the non-uniformly distributed load as a point load to an anchor point/bone on a ’s head, in
which case, may be more advantageous than applying a uniformly distributed load along the
head of a wearer that is not an anchor point/bone. Therefore, in some embodiments, varying the
slenderness ratio relative to adjacent ribs could provide greater comfort than using a common
slenderness ratio across a plurality of ribs to produce a uniformly distribution of the load as an
applied force could be distributed to desired points on a user’s anatomy. For example, if an early
rib towards the front of a compliant arm had a higher slenderness ratio and each successive rib
toward the back of the compliant arm had a sing slenderness ratio relative to the previous
rib, an applied load would be more zed toward the back of the compliant arm. One of skill
in the art will appreciate many alternative configurations of ing ribs with various
slenderness ratios, such as high slenderness ratios in the central ribs with vely lower
slenderness ratios in the early and later ribs to distribute an applied load towards either end of a
compliant arm (for example in a headset use such distribution would direct the load towards the
temple or occipital bone respectively).
Fig. 2D illustrates a side view of compliant arm 200 according to some embodiments
of the disclosure. Arm width 260 is the width of the compliant arm 200. In some embodiments,
arm width 260 may be uniform in width as shown on Fig. 2D. In other embodiments, arm width
260 may be of varying width at various points along the inner wall 220 and/or outer wall 210 to
s various deformation profiles or different shaped ant arms. In such embodiments,
the width of rib 230 may be of varying width to correspond to the varying width of the inner wall
220 and/or the outer wall 210. In other embodiments, the width of rib 230 may be of varying
width along the length of rib 230. The variations of width sizes on the various ents
within a compliant arm 200 may be factors considered when designing a ant arm for a
particular deformation profile, wherein the variations of width sizes of ribs 230 may be variables
to consider in determining a slenderness ratio.
In some embodiments where an upper compliant arm 120 (See Figs. 1E - 1F) is
utilized, upper edge 270 is the edge of the compliant arm 200 closest to the front portion of a
wearer’s head. For a compliant arm 110, upper edge 270 is the edge of the compliant arm 200
that is towards the top of the head. For the upper ant arm 120, lower edge 280 is the edge
of the compliant arm 200 furthest from the front portion a person’s head, e.g., towards the
backside of the head. For the compliant arm 110, lower edge 280 is the edge of the compliant
arm 200 that is towards the bottom of the head.
The interaction between the outer wall 210, inner wall 220, rib(s) 230, and wall
bridge 240 based on an input force will produce redistribution of the input force throughout the
compliant arm 200 structure. The redistribution of the input force transferred on the compliant
arm and how it is selectively distributed to the wearer’s head is dependent on at least the
deformation e and rness ratios. Furthermore, based on the deformation e and
slenderness ratios, the materials of the components within compliant arm 200 may vary. In some
embodiments all of the components within compliant arm 200 are made from the same material,
for example, thermosets, plastics, metals and composites. In some embodiments, the
components within compliant arm 200 may be constructed from different materials, for example
thermosets, thermoplastics, metals and composites, just to name a few. In some embodiments,
the material of the outer wall 210 may be constructed from, for e, a very elastic plastic
material while the material of the wall bridge 240 may be ucted from a flexible metal while
the rib(s) 230 may be constructed from yet another plastic material with less ility than the
outer wall 210, but more flexibility than the wall bridge 240 with the inner wall 220 made from a
composite.
In some embodiments, one or more rib 230 may have varying length within the same
compliant arm 200 to achieve a particular deformation profile to selectively distribute the load.
Furthermore, the spacing between each rib 230 may also be varied to achieve a desired
deformation e to selectively distribute the load. The rib thickness 290 may also be a factor
to achieve a desired deformation profile to selectively distribute the load. Additionally, the rib
width may also be a factor to achieve a desired deformation profile. Similar to the other
components within compliant arm 200, rib 230 may be constructed from various materials
depending on the desired deformation profile to selectively distribute the load. One of ry
skill in the arts appreciates the shape and sizes of a compliant arm 200 may vary depending on
the al of the compliant arm 200, rib length 295, rib thickness 290, rib width, spacing of the
rib 230, number of ribs 230, material and ess of inner wall 220 and outer wall 210, arm
width 260 of the outer wall 210 and inner wall 220, and/or stiffness of wall bridge 240, just to
name a few.
The ant mounting arm is a e compliant mechanism having one or more
compliant arms to selectively redistribute the weight of the headset based at least in part on a
deformation profile and slenderness ratio. A passive mechanism is a mechanism that is not
deliberately actuating the system. Therefore, the compliant mechanism is actuated ic body
deformation) by the forces resulting when a person places a headset with the compliant arms on
his/her head.
Fig. 3 illustrates an example of how a compliant arm deforms and uniformly
distributes loads according to some ments of the disclosure. A resting state of a compliant
arm 200 is ed as compliant arm 310. Compliant arm 310 may be one arm of an upper
compliant arm 120 or a compliant arm 110. For purpose of this example, compliant arm 310 is
an upper ant arm 120 (from Figs. 1E-1F). In one embodiment, a deformed state of the
compliant arm 310 in response to a point load 320 (e.g., from the weight of the headset) is
depicted as dotted lines to illustrate a sample elastic body deformation as a result of a point load
320. Each of the components of the deformed state of the compliant arm 310 is further disclosed
and bed as reference numbers 340 and greater. Point load 320 may be generated as a result
of the weight of a headset, for example, a frame 140 loaded with VR/AR components. Reactive
forces 330 are the uniformly distributed forces generated as a result of the elastic body
deformation of the compliant arm 310. The smaller arrows depicting ve forces 330 are
similar in length to illustrate the uniformity / near-uniformity of the load of the inner wall 350
against the ’s head. In this particular e, inner wall 350 is in compression, outer wall
370 is in tension, rib 360, 362, and 364 are in compression as shown by the buckling shape of the
ribs. First rib 340 is in tension because it is still ht and in almost direct opposite direction as
the point load 320. Wall bridge 380 is in both compression and tension as it is deforming and
wrapping around wearer’s head. One of ordinary skill in the art appreciates the varying degree of
elastic ation in relations to a uniform distribution of force along the compliant arm 310
may vary by using different materials, having varying length ribs, having varying spacing of the
ribs, having varying thickness of the ribs, having varying widths of the ribs, upper wall, lower
wall, and wall bridge. One of ordinary skill in the art appreciates compliant arm 310 may be
designed to selectively distribute the weight through elastic body deformation by selectively
distributing load 320 towards wall bridge 380 to apply a non-uniformly distributed load to an
anchor point/bone (not shown in Fig. 3).
In some embodiments, compliant arm 310 may comprise 4 ribs, as shown in Figs 2A
– 2C. In other embodiments, compliant arm 310 may comprise two or more ribs. The number of
ribs in a compliant arm 310 is ent upon a desired deformation profile. More ribs may
allow a more evenly buted force along the compliant arm; whereas fewer ribs may allow for
more selective zation of force along the compliant arm. However, the number of ribs may
also be dependent on a length of the outer wall and inner wall as well.
Fig. 4 illustrates an example of how the weight of a t on a wearer’s head may
be selectively buted by using a compliant mounting arm according to some ments of
the disclosure. The arrows in Fig. 4 illustrate the general direction of the weight of the headset
400 and the direction of the force distribution using the compliant mounting arms according to
some embodiments. In some embodiments, the majority of the weight 410 of the t is
located towards the front of the headset because of the additional components required as
discussed above to provide the wearer of the headset a virtual y / AR experience.
The weight 410 has a downward force placing most of the weight of the headset onto
the nose bridge of a wearer. The weight 410 of the headset is heavy because of the weight of the
additional VR / AR ents (not shown in Fig. 4). However, countering forces created by
the compliant arms offset much of the force from the nose bridge of the wearer to other areas on
the wearer’s head, for example, the forehead and anchor points/bones on the head, for example,
occipital bone, temporal bone, mastoid/styloid process, and the ridge along the parietal bone.
Active force 420 is generated from compliant arms 110. Compliant arms 110 are
deformed into the Parietal or Occipital bones of the wearer’s head because of the downward
force generated by the weight 410. The deformation of compliant arms 110 generate an active
force 420, which in turn produces reactive force 430 and reactive force 450 against the forehead
pad 150. Reactive force 430 and reactive force 450 also secure the headset to the wearer’s
forehead and reduce the weight 410 from the headset onto the wearer’s nose bridge.
In some embodiments, headset 400 may comprise upper compliant arms 120. Upper
compliant arms 120 are compliant arms that are more vertically aligned with the frame 140.
Although compliant arms 110 and ad pad 150 may selectively distribute the ty of
the weight 410, some embodiments of the disclosure may e upper compliant arms 120 for
further selective distribution of load. Active force 440 is generated from upper compliant arms
120. Upper compliant arms 120 are ed into the al bone of the wearer’s head because
of the downward force generated by the weight 410. The deformation of upper compliant arms
120 generate an active force 440, which in turn produces reactive force 450 and reactive force
430 t the forehead pad 150. Reactive force 450 is not dependent on the presence of upper
ant arms 120. In some embodiments, reactive force 450 may be produced by having only
compliant arms 110 without upper compliant arms 120. This is possible by active force 420 and
reactive force 430 coupled with weight 410.
Reactive force 450 may also secure the headset to the wearer’s forehead with an
upward force and further reduce the weight 410 from the headset onto the wearer’s nose .
Reactive force 430 and reactive force 450 may also provide enough upward force to prevent the
headset from slipping / g down the face of the wearer and to keep the headset securely
registered to the wearer’s forehead via the forehead pad 150. Since active force 420 and reactive
force 430 may reduce the weight 410 on a wearer’s nose bridge, active force 440 and reactive
force 450 may further reduce the weight 410 on a wearer’s nose bridge. In some embodiments,
the active and reactive forces may be enough to completely remove any load bearing on a
wearer’s nose bridge.
In some embodiments, upper compliant arms 120 may not be required because the
compliant arms 110 may be designed to generate active force 420 which in turn generate reactive
force 430 and ve force 450 to counter act the weight 410 against forehead pad 150. In other
embodiments, there may be four or six upper compliant arms 120 to r distribute the weight
410 across more portions of the wearer’s head to provide even more of a distributed force for
more comfort for the wearer and more stability of the t onto the wearer’s head.
One of ordinary skill in the art appreciates in other embodiments; the weight of a
headset may be trated in other areas of the headset and not just towards the front. In such
ments, compliant arms may also be deployed to selectively bute the weight of the
headset.
Fig. 5 illustrates an example of a virtual reality / augmented reality headset using a
compliant mounting arm according to some ments of the disclosure. Headset 500
includes components that add extra weight to frame 140 from Fig. 1. Lens 510 is the lens a
wearer of headset 500 would be looking into or through with the wearer’s eyes. In some
embodiments, lens 510 may be an LCD screen that may include, for example, additional
electronic components within the LCD screen to operate the LCD screen. In some embodiments
there may be only one lens 510. In other embodiments there may be two or more lens 510. In
other embodiments, lens 510 may be clear as sses in some portions of the lenses and nonopaque
in other portions. In other embodiments, lens 510 may be used as a projection screen for
projector 540 to t images / videos onto the lens 510.
In some embodiments, projector 540 may t images and/or videos onto the lens
510 for the wearer to see and interact with the VR / AR system. In some embodiments, there may
be one or more projector 540. In some embodiments, projector 540 may not be present
depending on the configuration of headset 500.
Camera 530 is used for capturing images or videos of the surrounding environment of
the wearer. In some embodiments, Camera 530 is outward facing with respect to the wearer. The
images and videos captured by the one or more camera 530 may be fed to electronic component
520 for processing, rendering, and/or sending to an external system (not shown in the figures) to
the headset.
Electronic component 520 may be used to process y on headset 500 certain
software programs for example image and video capturing, rendering and processing. Electronic
component 520 may also provide the computational power to receive images and videos from an
external system and display and project the images and videos onto the lens 510 via the one or
more projector 540. rmore, electronic component 520 may process input data received
from one or more sensor 550.
Sensor 550 may track location of the wearer, the movement of the wearer to
determine a pose of the wearer’s line of sight, etc. Sensor 550 may also sense the surrounding
temperature. Data that is tracked by sensor may be sent to electronic component 520 for
processing or for relay to an external system.
In some embodiments there may be one or more electronic components located on the
frame 140. In some embodiments there may be one or more sensor 550. One of ordinary skilled
in the art appreciates the collection of the multiple components on the frame 140 add additional
weight to the frame 140. rmore, the majority of the additional weight is generally toward
to front portion of frame 140 (e.g., the portion towards the lens 510) and thus, the additional
, if undistributed would most likely rest upon the nose bridge of a .
Fig. 6 illustrates an example of a virtual reality / ted y headset according
to some embodiments of the disclosure. Headset 600 includes AR / VR components similar to
Fig. 5 attached to a frame 140. Compliant arms 610 may be attached to frame 140 such that the
compliant arms 610 (depicted as being within the frame of the headset) wrap around the whole
head of a user. The compliant arms 610 may be joined er by a connector 620. The
connector 620 may include a spool type spring that provides a compression force to join the
compliant arms, wherein the spool type spring provides a compression force that joins the
compliant arms together for fitting adjustments to accommodate different head sizes instead of a
compression force for icting the compliant arms and headset to a user’s head.
Connector 620 may maintain a continuous force via the spool type spring so that the
user does not have to manually adjust the compliant arms or the connector 620 once the headset
600 is adjusted to fit the user’s head. For example, a user may adjust a ference of the wrap
around configuration (e.g., expand) of headset 600 by separating the compliant arms 610 such
that the spool type spring of tor 620 may maintain a ssion force to hold the
compliant arms 610 in a shape that provides an appropriate circumference to maintain a
table fit for different sized heads. Headset 600 may rest on the parietal bone located just
above the occipital bone of a user to prevent interference with the user’s ears while maintaining a
counterweight to the front viewing optics assembly. Headset 600 may t the frame 140
having the front viewing optics assembly from slipping down the nose bridge by transferring the
weight of the t 600 from a user’s nose bridge to other areas of a user’s head (e.g., parietal
bone / crown, occipital bone, and forehead).
Fig. 7 illustrates a side view of a virtual reality / augmented reality headset according
to some embodiments of the disclosure. Headset 700 may include AR / VR components,
compliant arms 610, connector 620 and frame 140 similar to Fig. 6 that further includes a wrap
around configuration. Compliant arms 610 may include an upward bend 710 that allows the
compliant arms 610 to rest and/or hang on a top portion of the occipital bone and/or the parietal
bone of a user’s head d of requiring a constricting force to securely wrap the headset 700
around a user’s head.
The upward bend of the ant arms is in relation to the frame 140 comprising the
AR / VR components such that the backside of headset 700 having the joined compliant arms
may rest above the occipital bone and/or on the parietal crown. Additionally, the upward bend
may be a compound or multi-directional/multi-axial curve or contour about the calvaria region of
the head. Such multi-directional/multi-axial curve or r occurs at least about an axis that
generally is vertical though a head, and about a horizontal axis onal to the vertical axis and
generally runs between the ears of a user. A multi-directional/multi-axial curve or contour of the
compliant arms, in combination with the connector between the two compliant arms having an
angle that approximates a slope of the posterior aspect of the parietal bones when viewed in the
al plane, allows the headset 700 to maintain contact interface with the head and rest on the
top portion of the tal bone and/or upon the parietal bone/crown of a user’s head. The
upward bend 710 may improve weight e of the headset 700 by hanging the headset 700
from the head rather than clamping down on or hugging the head, and minimize interference
with a user skeletal structure or hair otherwise. Furthermore, in some embodiments the multidirectional
/multi-axial curve or contour culminating at the upward bend 710 at the distal ends
may help to prevent headset 700 from sliding down and resting on a user’s ears by having a
geometry smaller than that of the occipital bone, which would serve as an anatomical obstruction
to such sliding motion. Additionally, the upward bend 710 may also allow a more universal fit
for different head shapes and/or sizes. Yet even further, the upward bend 710 may allow t
700 to rest and/or hang from the occipital bun and/or the parietal rown to prevent
interference with the user’s ears while maintaining a counterweight to the front viewing optics
assembly. The upward bend 710 may also prevent the front viewing optics assembly from
slipping down the nose bridge by erring the pressure and force of the weight of the headset
700 from a user’s nose bridge to other areas of a user’s head (e.g., occipital bun, crown, etc…).
In the foregoing ication, the disclosure has been bed with reference to
specific embodiments thereof. It will, however, be evident that various modifications and
changes may be made thereto without departing from the r spirit and scope of the
disclosure. For example, the above -described process flows are described with reference to a
particular ng of process actions. However, the ordering of many of the described process
actions may be changed without affecting the scope or operation of the disclosure. The
specification and drawings are, accordingly, to be regarded in an illustrative rather than
restrictive sense.
Claims (16)
1. A compliant arm, comprising: an outer wall; an inner wall; a wall bridge connecting the inner wall and the outer wall; and a plurality of ribs connecting at least the outer wall and the inner wall, wherein a rib of the plurality of ribs comprises a straight segment along a longitudinal direction and a thickness that is normal to a plane on which the longitudinal direction is located, the outer wall, the inner wall, and the wall bridge are arranged to form a loop structure having one or more openings, the straight t of the rib and the loop structure are ted together to form a planar structure, the planar structure ponds to the plane and further corresponds to a deformation profile upon which at least a size or a shape of the loop structure or the rib is determined for accommodating multiple head sizes or head shapes, and the outer wall, the inner wall, the wall bridge, and the ity of ribs selectively bute, based at least in part upon the deformation profile, a load by a deformation of at least one of the inner wall, the outer wall, or the straight segment of the rib of the plurality of ribs with respect to the plane due to a load along the longitudinal direction of the straight segment.
2. The compliant arm of claim 1, n the planar structure is a single body of a same material.
3. The compliant arm of claim 1 or 2, wherein the plane on which at least a portion of the planar ure of the compliant arm is located, when placed on a head of a user, is normal to a portion of a contour of the head of the user in contact with the planar structure.
4. The compliant arm of any one of claims 1 to 3, wherein the same material comprises a thermoplastic material.
5. The compliant arm of any one of claims 1 to 4, wherein the compliant arm is adjustable on one or more axes when coupled to a frame.
6. The compliant arm of any one of claims 1 to 5, wherein the compliant arm comprises a plurality of ribs, and the plurality of ribs have le spacing values or multiple thicknesses.
7. The compliant arm of any one of claims 1 to 6, wherein the deformation occurs under a load in the inner wall or the outer wall of the planar structure of the compliant arm but not within the rib.
8. The compliant arm of claim 7, wherein at least one end of both ends of the rib of the plurality of ribs is attached to the inner wall or the outer wall with a hinge, wherein the longitudinal direction changes orientation relative to the inner wall or the outer wall under the load.
9. The ant arm of any one of claims 1 to 8, wherein the rib of the plurality of ribs corresponds to a rness ratio for a deformation profile of the planar structure.
10. The compliant arm of any one of claims 1 to 8, wherein the rib of the plurality of ribs comprises a iform cross-sectional area that is determined based at least in part upon loading along the rib.
11. The compliant arm of any one of claims 1 to 10, wherein the plurality of ribs further comprises a separate rib which, when under a loading condition, is in a compressive state, while the rib is in a tensile state.
12. The compliant arm of any one of claims 1 to 11, wherein the planar structure corresponds to a deformation profile that is to approximately match at least a portion of a contour of at least a part of a user’s body when the compliant arm under load is in contact with the at least the part of the user’s body.
13. The compliant arm of any one of claims 1 to 12, wherein the outer wall and the plurality of ribs are constructed of different als.
14. The compliant arm of any one of claims 1 to 13, wherein the inner wall is in compression, the outer wall is in tension, the wall bridge is in compression and n, and each of the plurality of ribs is in either tension or compression when a load is applied to the ant
15. The compliant arm of any one of claims 1 to 14, wherein a first rib located on one end of the plurality of ribs is configured to t least flexibility than one or more remaining ribs of the plurality of ribs of the compliant arm.
16. The compliant arm of any one of claims 1 to 15, wherein the plurality of ribs defines a corresponding plurality of spaces, wherein each space of the corresponding ity of spaces is adjacent to at least one rib of the plurality of ribs. 100 O 130 110
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US62/362,920 | 2016-07-15 |
Publications (1)
Publication Number | Publication Date |
---|---|
NZ790308A true NZ790308A (en) | 2022-07-29 |
Family
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