Algorithm improvements in a haptic system

Information

  • Patent Grant
  • 11830351
  • Patent Number
    11,830,351
  • Date Filed
    Friday, March 11, 2022
    2 years ago
  • Date Issued
    Tuesday, November 28, 2023
    a year ago
Abstract
A system providing various improved processing techniques for haptic feedback is described. An acoustic field is defined by one or more control points in a space within which the acoustic field may exist. Each control point is assigned an amplitude value equating to a desired amplitude of the acoustic field at the control point. Transducers are then controlled to create an acoustic field exhibiting the desired amplitude at each of the control points. When human skin interacts with the acoustic field, vibrations of the skin are interpreted by mechanoreceptors being excited and sending signals to the brain via the nervous system. Improved processing techniques allow for more efficient real-world operation.
Description
FIELD OF THE DISCLOSURE

The present disclosure relates generally to an improved algorithm processing techniques in haptic-based systems.


BACKGROUND

It is known to use a continuous distribution of sound energy, which will be referred to herein as an “acoustic field”, for a range of applications, including haptic feedback.


It is known to control an acoustic field by defining one or more control points in a space within which the acoustic field may exist. Each control point is assigned an amplitude value equating to a desired amplitude of the acoustic field at the control point. Transducers are then controlled to create an acoustic field exhibiting the desired amplitude at each of the control points. When human skin interacts with the acoustic field, vibrations of the skin are interpreted by mechanoreceptors being excited and sending signals to the brain via the nervous system.


When used in mid-air, haptic technology works by focusing sound at an ultrasonic carrier frequency to a point or points in the space above the transducers. Then this is modulated by a low frequency wave that generates the haptic sensation.


Nonetheless, real-world implementation of haptic feedback systems may require processing improvements in order to better simulate desired haptic feedback characteristics in real time. Known systems suffer from limitations, in that it is difficult to account for many control points at once while achieving fast update rates for the state of the transducers, acoustic field and therefore control points. Fast and efficient updates are required for a commercially viable system.


Accordingly, a system that provides various improved processing techniques for haptic feedback is desirable.





BRIEF DESCRIPTION OF THE FIGURES

The accompanying figures, where like reference numerals refer to identical or functionally similar elements throughout the separate views, together with the detailed description below, are incorporated in and form part of the specification, and serve to further illustrate embodiments of concepts that include the claimed invention, and explain various principles and advantages of those embodiments.



FIG. 1 is a snapshot of a series of devices producing a single carrier frequency.



FIG. 2 is a snapshot of a series of devices illustrating the disruptive effect on the focus shown in FIG. 1.



FIG. 3 is a snapshot of a series of devices showing the creation of a focal area where the modulation frequency is focused.



FIG. 4 is a montage of rows of the same shapes produced by taking slices of a simulation of the acoustic field.



FIG. 5 shows the amplitude of a star shape used to demonstrate haptic feedback in an acoustic field.



FIG. 6 shows the phase of a star shape used to demonstrate haptic feedback in an acoustic field.



FIG. 7 shows the amplitude of the star shape used to demonstrate haptic feedback in an acoustic field after the disclosed method has been applied.



FIG. 8 shows the phase of the star shape used to demonstrate haptic feedback in an acoustic field after the disclosed method has been applied.



FIG. 9 is a diagram of the output of a single transducer from the perspective of a single focus point.



FIGS. 10 and 11 show the interpolation for a single transducer between two states.





Skilled artisans will appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions of some of the elements in the figures may be exaggerated relative to other elements to help to improve understanding of embodiments of the present invention.


The apparatus and method components have been represented where appropriate by conventional symbols in the drawings, showing only those specific details that are pertinent to understanding the embodiments of the present invention so as not to obscure the disclosure with details that will be readily apparent to those of ordinary skill in the art having the benefit of the description herein.


DETAILED DESCRIPTION
I. Focusing with Multiple Frequencies in a Haptic System

A simple example with a single focus can be obtained by calculating the distance from the point where the focus is to be created to each transducer. Then this distance is divided by the wavelength and the fractional part multiplied by the period to find the delay such that all the waves arrive together. For small devices, the ultrasonic carrier frequency implies a wavelength that is small compared to the variation in transducer to desired focus point distances. Focusing is thus required to ensure a strong signal at a point. For small devices, this is not the case for the wavelength of the modulation frequency. The wavelength of the modulation frequency is large compared to the variation in transducer to desired focus point distance, so the modulation frequency can be simply synchronized.


For some larger form factors, such as, for example, a TV sound bar, this is not the case. The modulation frequency will fall out of phase in the haptic region, mixing the acoustic field states and weakening the feedback. The problem can be solved by applying a multipoint focusing scheme to both the carrier and modulated wave allows multiple sets of strong feedback points are produced at large separations at a large distance from the device.


The first step is to segment the system of focal points in the carrier frequency into regions, which can fit within the focal areas of the modulation frequency. These are necessarily in the order of half a wavelength of the modulation frequency in diameter. Since the aim is to ensure that the modulation frequency is in-phase in the feedback area, both phase and anti-phase two-sided modulations must fit inside the modulation frequency focal area.


Next, the system is applied to produce modulation frequency phase offsets for all modulation frequency focal areas. It is now possible to solve for the ultrasonic phase offsets for the multi-point focus system at the carrier frequency as normal. Because the modulation is in phase, the modulation will behave normally just as in a smaller array.


In the accompanying FIGS. 1-3, simulation snapshots of acoustic fields have been chosen to comparably evaluate the strength of three focusing approaches. The small filled black circles along the edge of each figure represent transducer elements that have been configured to reproduce a control point. The diameter of the inset circle in each snapshot is the wavelength of the modulation frequency.



FIG. 1 illustrates a snapshot of a device producing a single carrier frequency, focusing to a point (shown in the inset circle). The device has been configured to produce a focus at the center of the circle using the simple example above.



FIG. 2 is a snapshot that illustrates the disruptive effect on the focus (shown in the inset circle) based on FIG. 1 when a lower frequency modulation is applied synchronously to all transducers. This is the usual approach for small constellations of transducers. In this case however, the modulation frequency wavelength is similar to or smaller than the difference in line of sight length from a control point to each emitting device. This results in reduced contrast in the wave at the focus, revealing a weaker haptic response.



FIG. 3 shows the proposed solution: a snapshot showing the creation of a focal area (shown in the inset circle) where the modulation frequency is focused. This is accomplished by applying both the proposed modulation focusing and the focusing of the carrier frequency to the device in parallel, which restores strength to the control point at the focus.


The technique as shown in FIG. 3 is not limited to ensuring that the carrier and modulated frequencies behave correctly. An input audible sound can be filtered to make it suitable for ultrasonic projection before being split into its component frequencies such as when a Fourier transform is employed. These individual frequencies can be focused at a point to generate a non-linear breakdown causing sound to be generated at the point. If the component frequencies are shared, they may be generated in different configurations in different places allowing multiple sounds to be created in different and discrete positions. As the human ear is not sensitive to phase, the phase solver can be applied and the relative phase randomized without degradation of the system. There may be a discrimination condition between frequencies containing phase information that encodes structure that should not be modified and phase information that can be modified.


II. Amplitude Multiplexing with Dominant Eigenvectors in a Haptic System

It is useful to provide a system and method for providing improved haptic feedback using amplitude multiplexing with a dominant eigenvector.


A. Optimal Single Control Point Solution


The optimal solution for a single control point can be derived from first principles by algebraically solving a linear system Ax=b, where A is the 1×n linear system of wave function superpositions (essentially a row vector). This system reflects a system with a single control point at the position χc with the intended behavior of the acoustic field (amplitude and phase) at that point represented by the complex coefficient Yc:











[



Z
1



(

χ
c

)















Z
n



(

χ
c

)



]



[




Y
1











Y
n




]


=

Y
c





[

Equation





1

]








where Z1 c) . . . Zn c) are the acoustic field wave functions created by single frequency sound emissions from emitters 1, . . . , n and Y1, . . . , Yn (the vector x) are the complex activation coefficients that solve the linear system. Yc (the vector b) is the intended wave function behavior (amplitude and phase) at the control point.


The minimum norm solution to a linear system, in this case the solution with the lowest required activation amplitudes, can be found by pre-multiplying the matrix with the Moore-Penrose pseudoinverse. The complex linear system Ax=b then has a solution with lowest activation amplitudes given by x=AH (AAH)−1b. The activation coefficient for a given emitter q can then be written as:










Y
q

=





Z
q



(

χ
c

)


_



Y
c






Z
1



(

χ
c

)






Z
1



(

χ
c

)


_


+

+



Z
n



(

χ
c

)






Z
n



(

χ
c

)


_








[

Equation





2

]








where the overline denotes complex conjugation.


B. Generic Emitter to Specific Transducer


Rather than using a separate function for each emitter, if the transducers are emitting into free space a single template wave function can be created to represent each transducer by using a 4×4 matrix transform Tq into the space of the template transducer (denoted *). The transducer function for a zero phase offset and unit amplitude may be written as:











Ψ
q



(
χ
)


=


Z
*



(


T
q


χ

)






[

Equation





3

]








so that changes to the amplitudes and phases of the transducers can be represented by multiplying this wave function by a complex constant.


C. Finding Localized Effects


A control point has both amplitude and phase. For haptic applications, the phase is immaterial, and so it can be used to find the best way to create the desired amplitudes at the control points in space.


The control point activation Yc is represented as a complex value Aceiϕc. To find the effect that the activation of a control point has on its neighbors, the amplitude and phase offset must be set to a reference point, such as a unit amplitude on the real line. As the control point has unit amplitude and zero phase offset, this control point will be denoted C0. Defining αC0=[ψ1c), . . . , ψnc)] the vector of transducer activation coefficients Y for the control point C0 can be written as:










Y

C

0


=



α

C

0


_



a

C

0


·


α

C

0


_







[

Equation





4

]







Given an activation coefficient for a transducer Yq the effect that activating transducer q with the coefficient calculated from control point C0 has on another given point χO, may be found as {acute over (Ψ)}q;C0O)=Yq;C0ΨqO). Using this, the total effect that ‘activating’ a control point of amplitude AC has on any other control point, as the summed effect at the point χO would then be:












Ψ



Ω
;

C

0





(

χ
O

)


=




α

C

0


_




A
c

·

α
O





α

C

0


·


α

C

0


_







[

Equation





5

]







D. Control Point Relations Matrix


To create many control points at the same time, it must be considered how they impact each other and find a solution in which they cause beneficial and not unwanted, detrimental interference.


Sets of simple unit amplitude and zero offset activation coefficients for each of the m control points under consideration were established. They are written αC01, . . . , αC0m. The amplitude for the individual control points is defined as Ac1, . . . , Acm. If a vector k is defined as







k
=

[


1


α

C


0
1



·


α

C


0
1



_



,





,

1


α

C


0
m



·


α

C


0
m



_




]


,





the control point relations matrix is:









R
=

[




A

c
1









A

c
r





k
r



(



α

C






0
r



_

·

α

C






0
1




)










A

c
m





k
m



(



α

C






0
m



_

·

α

C






0
1




)


























A

c
1





k
1



(



α

C






0
1



_

·

α

C






0
r




)









A

c
r









A

c
m





k
m



(



α

C






0
m



_

·

α

C






0
r




)


























A

c
1





k
1



(



α

C






0
1



_

·

α

C






0
m




)










A

c
r





k
r



(



α

C






0
r



_

·

α

C






0
m




)









A

c
m





]





[

Equation





6

]







This matrix is a very small square matrix which has m×m entries when m control points are considered, so the eigensystem evaluation does not involve many computations. Then the eigensystem Rx=λx has eigenvectors x. Eigenvectors of this matrix represent control point activation coefficients that result in interference such that the set of control points activation coefficients remain steady and do not effect relative changes in the acoustic field. When the eigenvalue λ is large, this represents a set of points with increased gain, and when it is small, the strength of these control points is reduced.


A simple algorithm for determining eigenvalues is the power iteration, wherein an arbitrary non-zero sample vector is multiplied and then normalized iteratively. As there is a primary interest in the eigenvector with the largest eigenvalue, the most simple iteration available suffices:










x
=


x
^

big


,


x
big

=


lim

s







R
s



x
random








[

Equation





7

]







Having achieved this x by normalizing and multiplying by the matrix R many times, each complex number is normalized so that the eigenvector weights do not affect the control point strength unnecessarily. This generates:











x


r

=


x
r




x
r




x
r

_








[

Equation





8

]







E. Amplitude Multiplexing with the Dominant Eigenvector


The activation coefficients for each transducer q can be expressed by linearly multiplexing in amplitude the control power activation coefficients:










Y

q
,

Ω





C




α





r
=
1

m





α

C






0

r
,
q




_



A

c
r





x


r



k
r







[

Equation





9

]







To achieve real transducer activation coefficients, the power levels must be normalized to those producible by real hardware. This can be achieved by dividing through by the maximum intensity to produce correctly weighted control points:











Y
^


q
;

Ω





C



=





r
=
1

m





α

C






0

r
,
q




_



A

c
r





x


r



k
r





max

q
=
1

n








r
=
1

m





α

C






0

r
,

q






_



A

c
r




k
r











[

Equation





10

]







Or, if it is acceptable to accept some error in the relative strengths of control points the transducer coefficients may be normalized more simply as:











Y
^


q
;

Ω





C



=





r
=
1

m





α

C






0

r
,
q




_



A

c
r





x


r



k
r









r
=
1

m





α

C






0

r
,
q




_



A

c
r




k
r










[

Equation





11

]








Using these solutions, the physical transducers can be actuated such that the desired control points exist in the field at the desired amplitude.


These solutions for the effect of a single control point on another are optimal for the situation in which the control point contributions are summed and normalized. Even though the plain linear combination of control points does not perform well when the set of control points is large, by solving the eigensystem and using the combinations of complex coefficients large sets of control points may generate many hundreds of times faster than before. Further, the eigensystem solution eliminates the drawbacks to the linear combination that prevented these solutions being useful previously.


F. Testing


To ascertain the differences in speed and effectiveness for complex shapes, the following provides runtime analysis and simulated acoustic fields.


The computational speed tests given in Table 1 were produced using a stress testing application that runs control point solutions for a set of points randomly generated in a plane above the array.


The left column of Table 1 shows the number of control points used for the computational speed tests.


The center column of Table 1 labeled “new” shows the number of milliseconds it took to find a set of complex transducer inputs to generate an acoustic field containing the given number of control points using the linear control point amplitude multiplexing with the dominant eigenvector as described herein. This computation took place using a 2.5 GHz Intel Core i7-4870HQ CPU in a single-threaded mode.


The right column of Table 1 labeled “old” shows the number of milliseconds it took find a set of complex transducer inputs to generate an acoustic field containing the given number of control points using the older full linear system with the dominant eigenvector. This computation took place using a 2.5 GHz Intel Core i7-4870HQ CPU using the whole CPU.











TABLE 1





Control points
New (ms)
Old (ms)

















1
0.00822
4.30


2
0.0110
6.28


3
0.0136
9.27


4
0.0159
10.9


5
0.0195
12.5


6
0.0226
13.7


7
0.0254
15.4


8
0.0286
16.2


9
0.0337
17.7


10
0.0372
18.6


11
0.0407
20.1


13
0.0607
22.0


14
0.0536
23.1


16
0.0766
25.9


18
0.0850
28.3


20
0.0886
30.6


22
0.106
33.4


25
0.135
36.8


28
0.146
42.0


32
0.179
47.1


35
0.211
52.4


40
0.263
59.9


45
0.343
70.1


50
0.507
79.6









Further testing is shown at FIG. 4, which is a montage of rows 10, 20, 30, 40, 50, 60, 70 of the same shapes produced by taking slices of a simulation of the acoustic field. The level of gray corresponds to the amplitude. High points in amplitude are highlighted in white instead of gray. Column A 80 shows the result of the linear system solution “old” method that produces accurate shapes. Column B 90 shows the result of the amplitude multiplexing “old” method without weighting by the dominant eigenvector. As can be seen, this produces bad quality results in many cases. Column C 100 shows the result of the amplitude multiplexing method with weighting by the dominant eigenvector (the new method disclosed herein).


G. Resource Constrained Scenarios


The algorithm discussed above may be split into three stages. The first stage (the “single point stage”) computes the optimal unit amplitude and zero phase offset control points for the given control point locations and stores the appropriate optimal transducer activation vectors for each single point. The second stage (the “eigensystem stage”) uses dot products to generate the eigensystem matrix and multiplies it with an arbitrary non-zero vector until an approximation to the eigenvector is obtained. The third stage (the “combination stage”) sums up the dominant eigenvector weighted contributions from each of the single points into the final transducer activation coefficient vector needed to create the desired acoustic field with the physical transducers.


The computational operations required must be understood before the algorithm can be moved to low cost devices. The first stage requires many square root, sine and cosine evaluations to build a model of the acoustic waves emitted from the transducers. The second stage requires many matrix multiplications, but also many small but resource-costly vector normalizations. The third stage also requires normalization.


Transducer inputs calculated in the first stage can be precomputed in some instances to remove the computational cost of building the acoustic model for each control point. Particular combinations of control points can be precomputed so that their dominant eigenvectors are already available to the later combination stage. Either precomputation or caching can be done at determined or designed “hotspots.” This can be achieved for pair or groups, depending on the design of the interactions involved. When the final contributions of the transducers inputs are cached, they can be made close enough together that an interpolation in the space of transducer activation coefficients can be perceived as a spatial linear motion of the control points from one precomputed setting to another.


III. Reducing Requirements for Machines Solving for Control Points in Haptic Systems

In order to create a commercially viable system, the methods for calculating the transducer output to produce many control points must be streamlined so that they may be implementable on smaller microcontrollers and are able achieve a more responsive update rate to enhance interactivity and the user experience.


A. Merged Eigensystem Calculation


It is known that an eigensystem that encodes the influence of control points on each other can be used to determine control point phase configurations that reinforce each other, relatively boosting their output and increasing the efficiency of the transducer array.


It has been previously shown that this eigensystem can be described by the matrix:









R
=

[




A

c
1









A

c
r





k
r



(



α

C






0
r



_

·

α

C






0
1




)










A

c
m





k
m



(



α

C






0
m



_

·

α

C






0
1




)


























A

c
1





k
1



(



α

C






0
1



_

·

α

C






0
r




)









A

c
r









A

c
m





k
m



(



α

C






0
m



_

·

α

C






0
r




)


























A

c
1





k
1



(



α

C






0
1



_

·

α

C






0
m




)










A

c
r





k
r



(



α

C






0
r



_

·

α

C






0
m




)









A

c
m





]





[

Equation





12

]








where αC01, . . . , αC0m are zero offset activation coefficients, Ac1, . . . , Acm are amplitudes for the individual control points and a vector k is shorthand for







[


1


α

C






0
1



·


α

C






0
1



_



,





,

1


α

C






0
m



·


α

C






0
m



_




]

.




The linear system algorithm can be used as a subsequent calculation step as a method to solve a system of linear equations that describe the vector of transducer activation coefficients of least norm (lowest power requirements) that produce a set of control points with a given amplitude and phase offset. This phase offset may have been previously computed by the eigensystem.


A known method of achieving this linear system solution is via a Cholesky decomposition of a matrix. But to transform the matrix into the appropriate form for a Cholesky decomposition, it must be multiplied by its conjugate transpose to put it into a positive semi-definite form prior to taking the decomposition.


For the matrix of individual transducer output samples to calculate the final transducer activation coefficients, the result of taking it to this form can be described by:










C


[





α

C






0
1



·


α

C






0
1



_









α

C






0
1



·


α

C






0
r



_









α

C






0
1



·


α

C






0
m



_

























α

C






0
r



·


α

C






0
1



_









α

C






0
r



·


α

C






0
r



_









α

C






0
r



·


α

C






0
m



_

























α

C






0
m



·


α

C






0
1



_









α

C






0
m



·


α

C






0
r



_









α

C






0
m



·


α

C






0
m



_





]


.




[

Equation





13

]







It can be recognized that the previous eigensystem matrix R can be easily derived from this matrix C by post-multiplying by a diagonal matrix with trace [Ac1k1, . . . , Acmkm]. Since this is a small matrix compared to the length of the zero offset activation coefficients vectors αC01, . . . , αC0m, computing this only once results in a large speed improvement to the linear system based technique that once again makes it competitive with amplitude multiplexing for systems in which the matrix C is small.


B. Computation Sharing for Reduced Bandwidth and Latency.


In the known amplitude multiplexing technique, the final step is to reconstitute the eigenvector length outputs into transducer activation coefficients by multiplying each coefficient by the optimal solution, which is a reweighting of the conjugated evaluation of the wave function representing the output of all individual transducers at that point in space. By considering the least norm solution of the transducer activation coefficients via the Cholesky decomposition, all possible optimal solutions lie within a readily predictable and linear m-dimensional space. Further, this shows a method to use this fact to broadcast low bandwidth and thus low latency solutions to a set of devices that control known transducer constellations. As direct information regarding the transducer constellations does not need to be transmitted, this can result in multiple orders of magnitude increase in available bandwidth. In this way, large sets of synchronized devices are created that do not need to communicate but can co-operate to produce an acoustic field that can update at high frequency. If the update rate frequency is greater than an audible frequency, this presents an alternative mechanism to producing reduced audible output, which is desirable in a commercial system.


This can be achieved because the production of the focal points is by virtue of being soluble by a linear system linearly related to the output of the transducer elements. This means that the sinusoidal transducer input signal approach to making an array exhibit reduced noise can also be implemented by creating sinusoid-modulated control points and updating them at a rate faster than twice the frequency. This method has the advantage that multiple frequencies can be used together but has the drawback that it requires a much faster solving speed, tighter timing requirements and more available bandwidth than the other approach. This technique makes this approach viable on embedded systems.


The linear system solution of minimum norm is a method to obtain the lowest power transducer activation coefficient vector that reproduces a set of control points within the acoustic field. Using the least norm Cholesky decomposition method, to solve a linear system Ax=b, the substitution AHz=x is applied to produce the equation AAHz=b which is amenable to solution. This new solution vector z is a complex vector in an m-dimensional space is far smaller, and yet fully describes the solution. It is known that the rows of the matrix AH correspond to transducer activation vectors proportional to the optimal single control point solutions and so the output from the eigensystem and amplitude multiplexing technique can be also interpreted as a vector belonging to this vector space. The result vector from any solution system can also be projected into this smaller vector space and benefit from this solution.


This smaller vector is more suitable for transmission across a bandwidth-constrained link. On the far end of the link, a further less-flexible pipeline can decompress this reduced vector into the relevant portion of the x solution, then convert and output it to the transducer elements.


This can be achieved by, for example, transmitting the co-ordinates of the control point in order to recreate on the inflexible part of the pipeline the appropriate block of the matrix AH. This could then imply a transmission of a 3D co-ordinate followed by a real and imaginary component for the corresponding element of the solution vector z. From this, the block of the matrix AH could be reconstructed and the complex activation coefficient for each transducer computed and output.


C. Reduced Dimensionality of Transducer Vectors.


As described in the previous sections the number of transducers and thus the length of the zero offset activation coefficients vectors αC01, . . . , αC0m can be large. Both the eigensystem and the semi-positive definite C matrix described above are the result of vastly reducing the number of dimensions from the transducer count to m.


As the Cholesky decomposition takes the equation Ax=b and produces a solution z where AAHz=b, followed by a reconstruction of the x vector as x=AHz due to the dimensionality, the first step to compute z can be constructed assuming a decimated or simplified transducer set. The two steps would then be (A′)(A′)Hz=b followed by x=AHz using the full A matrix. This simplified A′ can, for example, contain information about every second transducer or can be computed to model transducers grouped together and actuated as a single unit.


Thus, the number of transducers can be lowered in order to provide a speed up in exchange for some small degradation in performance. The full count of transducers can be calculated and added back in later in the solution procedure, after the coefficient data has been moved onto the parallel disparate processing on the less flexible pipeline closer to the transducer output.


IV. Modulated Pattern Focusing and Grouped Transducers in Haptic Systems

The optimal conditions for producing an acoustic field of a single frequency may be realized by assigning activation coefficients to represent the initial state of each transducer. As the field is monochromatic, these complex-valued activation coefficients uniquely define the acoustic field of the carrier frequency for “all time”. However, in order to create haptic feedback, the field must be modulated with a signal of a potentially lower frequency. For example, an acoustic field of 40 kHz may be modulated with a 200 Hz frequency in order to achieve a 200 Hz vibrotactile effect. This complicates the model, as the assumptions that the patterns of transducer activations will hold for “all time” is violated. The result is that when the path length between each transducer and a given control point sufficiently differs, the waves will not coincide correctly at the control point; they will instead reach the control point at different times and not interfere as intended. This is not a serious problem when the change in path length is small or the modulation wave is of very low frequency. But this results in spatial-temporal aliasing that will reduce the power and definition of the control points as they are felt haptically.


It is known that to remedy this, a second focusing solution can be used to create a double focusing of both the carrier and the modulated wave. However, there is no simple way to apply the second focusing to the field that does not cause discontinuities in the form of audible clicks and pops. This also does not easily extend to the situation in which the modulated wave has no discernable frequency.


The second focusing ‘activation coefficient’ for the modulation frequency can be used to compute an offset in time from the resulting complex value. This offset can be smoothly interpolated for each transducer, resulting in an output that can take advantage of the second focusing and be free from audible artefacts.


Due to relatively low frequency nature of the modulated content, using groupings of transducers that have small differences in path length can lead to a useful trade-off, reducing both the computation and implementation complexity of the second focusing. If these transducers are mounted on separate devices that share a common base clock for producing the carrier frequency, a pattern clock for outputting the modulation wave can be produced. The time offset that is computed for each group can be added as a smooth warping function to the pattern clock for each grouping.


Since there are per-control point position data in the device on a per-pattern basis as has been previously disclosed (the “reduced representation”), this position information can be used to compute simple time of flight to each individual control point in real time. The result is that the interpolation nodes of the transducer activation patterns implied by each reduced control point representation are flexibly rescheduled in time slots on the device in order to arrive at the control points at the right time. This rescheduling can be achieved either per transducer or per grouping.


Each control point then has the capacity to float backwards and forward along the time line to find the position that is most suitable. Therefore, patterns that contain many control points can become split in time as different control points in the same pattern are emitted at slightly different times. The control points are then combined again in this new arrangement, resulting in sets of carrier frequency transducer activation coefficients that differ from those originally solved for. Counter-intuitively, this better preserves the “all time” assumption required by the solution for the initial transducer activation coefficients as the effects of the time coordinate for spatially localized groupings of control points has been removed. It is known that presenting spatially localized control point groupings is beneficial in that it generates a solution which provides more self-reinforcing gain than groupings that are spread out, so the validity of the control point compatibility calculations is both more important and better preserved in this case.


An important consequence of this approach is that it is then possible to employ any modulating envelope and have smooth second focusing. A pure frequency is no longer required. This may be used to create more defined parametric audio with multiple spatial targets, as well as provide clearer and more textured haptic cues with less distortion.


V. Pre-Processing of Fourier Domain Solutions in Haptic Systems

As an alternative to defining one or more control points in space, a shape defined in a 2-dimensional (2D) slice may instead be constructed in the acoustic field. This is accomplished by treating the transducer array as a holographic plate. The standard model of a holographic plate may be made to behave as an equivalent to an infinite plane of infinitesimally sized transducers. There is then a known simple solution for any given 2D complex pressure distribution that lies in a plane parallel to the plate. Building such a shape defined by complex pressure values, and convolving it with the inverted transducer diffraction integral at the given plane distance achieves this. This solution can be obtained efficiently with a 2D fast Fourier transform (FFT). Finally, using the complex-valued solution for the infinite plane, the closest real transducers in each case can be activated with a similar complex coefficient that strives to produce the same result. In this way, a physical set of transducers can then be controlled to create an acoustic field exhibiting the shape at the given distance.


One large drawback of this approach is that producing a shape instead of a set of points produces weak output and requires an infinite array. Being able to modify this technique to produce stronger output and use more realistic constraints allows this approach to bring acoustic activation of whole shapes closer to commercial viability.


A. Control Regions Relations Matrix


Prior to generating shapes using the Fourier method, a given shape nay be divided into regions. The optimal method to create “regions” of feedback is to determine when activated mutually enhance adjacent regions simultaneously can be pursued. To do so, it is imperative to consider how each region impacts the others and find a solution where they cause beneficial—and not unwanted—detrimental interference.


Similar to the control points, there are sets of simple-unit amplitude and zero-offset activation coefficients for each of the m control regions under consideration. An important difference between these activation coefficients and those involved in a discrete transducer model is that the transducers are now infinitesimal, and so the dot product sum becomes an integral.


Complex valued pressure within each region can be pre-defined to within an arbitrary reference to remove it from consideration in the solution. While there are many possible choices for this pre-definition of regions, it may be defined as real-valued or constant phase in order to function most effectively (although it may not and instead exhibit local phase variations). This pre-definition may involve defining each region as tessellating shapes, pixels, blobs, interpolation kernels or more complex shapes.


Having defined these regions (similar to control points), sets of simple unit amplitude and zero offset activation coefficients are established for each of the m control regions under consideration. To find the simple unit amplitude and zero offset activation coefficients, the next step is to solve the Fourier 2D plane shape problem for each of the m control regions. This yields a 2D function describing the holographic plate (an infinite plane of infinitesimal transducers), which in turn describes the similarities between the effects of activating each control region. The goal is then to find a configuration such that each region mutually reinforces those nearby. These “transducer activation coefficients” for each region with unit coefficient are now written as complex-valued functions:











α

C


0
1





(

x
,
y

)


,





,


α

C


0
m





(

x
,
y

)






[

Equation





14

]







The amplitude for the individual control regions are:










A

c
1


,





,

A

c
m






[

Equation





15

]







If vector k is defined as:










k
=

[





1




-



+








-



+








α

C






0
1





(

x
,
y

)


·



α

C






0
1





(

x
,
y

)


_



dy





dx




,





,






1




-



+








-



+








α

C






0
m





(

x
,
y

)


·



α

C






0
m





(

x
,
y

)


_



dydx







]


,




[

Equation





16

]







then, in a similar manner as the control point relations matrix, the control regions relations matrix may be written as:









R
=

[




A

c
1









A

c
r




k
r



F


(


α

C






0
r



,

α

C






0
1




)










A

c
m




k
m



F


(


α

C






0
m



,

α

C






0
1




)


























A

c
1




k
1



F


(


α

C






0
1



,

α

C






0
r




)









A

c
r









A

c
m




k
m



F


(


α

C






0
m



,

α

C






0
r




)


























A

c
1




k
1



F


(


α

C






0
1



,

α

C






0
m




)










A

c
r




k
r



F


(


α

C






0
r



,

α

C






0
m




)









A

c
m





]





[

Equation





17

]








where F(αC0pC0q)=∫−∞+∞−∞+∞αC0p(x,y)·αC0q(x,y)dy dx.


It may be necessary to approximate some of these integrals, by for example restricting their domain. These integrals may also be performed in the space of a real transducer grid, effectively reducing the definition of R to the usual eigensystem. This R then becomes the eigensystem for determining the optimal coefficients to pre-multiply each region with before attempting a Fourier solution of the full shape. This matrix is a square matrix having m x m entries when m control regions are considered, so the computational time of the eigensystem evaluation depends on how many regions have been defined. Eigenvectors of this matrix then represent control region activation coefficients that result in interference such that the point amplitudes within each control region remains steady and does not create relative changes in the acoustic field. When the eigenvalue A is large this represents a set of coefficients that promote increased gain. This is especially important when control regions are used with the Fourier solution technique.


B. Results


To evaluate this technique, a large star shape with each region occupying a pixel square was constructed by creating a bitmapped black and white image and converting white pixels into unit amplitude and phase regions. This star assumes the transducers are arranged in an infinite plane and are infinitesimal in size.


The amplitude of the star is shown in FIG. 5. The phase of the star is shown in FIG. 6. The known 2D FFT method has been used to produce this output with no preprocessing.


Next, taking into account the effects of focusing to one region has on focusing to another, the next step is to search the space using the eigensystem for a region arrangement for a more realistic candidate for reproduction in the acoustic field. After several iterations of the eigensystem and by virtue of being informed with the local effects of each regional solution, the 2D FFT solution looks quite different. The amplitude of the star using this solution is shown in FIG. 7. The phase of the star is shown in FIG. 8.


While the star has lost definition at the edges, this solution takes into account the way adjacent regions affect each other. This solution will exhibit much higher fidelity when applied to a real transducer system than the constant phase solution or a solution that has not been chosen in this way. This is because the structure of the transducer array and the interactions between the acoustic fields produced by each individual transducer as well as the effect adjacent regions have on each other have all been accounted for in the matrix formulation.


VI. Dynamic Solution Space Sampling

In an acoustic field, one or more control points can be defined. These control points can be amplitude-modulated with a signal and as a result produce vibrotactile feedback in mid-air. An alternative method to produce feedback is to create control points that are not modulated in amplitude and instead move them around spatially to create spatio-temporal modulation that can be felt. In either event, the acoustic field changes in space and time must be smooth in order to prevent audible noise. Since this constrains the behavior of valid states of the system, high-resource direct calculation techniques can be replaced by perturbations from the previous state to drive down the resources need for calculations. This is especially important in embedded systems, where computer processing resources are a scarce resource.


A. Control Point Paths as Perturbed Solutions


Creating a point and moving it without modulating in amplitude may haptically actuate a path in the air. If moving this point is to be made quiet, the point has to change the acoustic field by a small delta each time. The implication is that to do so, the point must make small enough distance increments when it moves in order to make the apparent motion smooth. This means that the phase and amplitude from any one transducer must also approximate a smooth curve, which implies a number of possibilities regarding perturbative techniques.


B. Perturbed Distance, Amplitude and Sampling Calculations


When calculating the simple time-of-flight from a transducer midpoint at p, to a focus point at χt at sample time t, the distance must be calculated if the phase and amplitude will not be determined via look up table. Defining the vector between these as Δt=p−χt, there are two quantities to determine to obtain the phase and angle-dependent amplitude. The phase can be determined as a multiple of √{square root over (Δt·Δt)}, which contains a square root. Square roots are difficult to calculate in embedded hardware, as there is no direct approach for evaluation. As an alternative to using a more direct approach to obtain the solution such as polynomial evaluation, a Newton-Raphson or other iterative approach can be used instead. However, due to the perturbative nature of the solution, the result of the previous calculation √{square root over (Δt−δ·Δt−δ)}, can be used to seed the next square root approximation. Assuming that the movement is continuous in time, the quantity √{square root over (Δt·Δt)}−√{square root over (Δt−δ·Δt−δ)} will be small enough for it to converge quickly, needing only a small fraction of the iterations required by an unseeded calculation. This saves compute time, enabling the decompression of the reduced representation states to proceed much more quickly than before. Equivalently, similar methods can be used to avoid other instances of resource-consuming operations. Other such calculations can similarly benefit so long as these quantities are connected to the continuity of the phase space. This allows evaluations such as






1


Δ
t

·

Δ
t







required to determine amplitude or






1

s
t






required to describe sampling delta to be refined using other less resource-intensive arithmetic operations. In many of these cases, the full iterative procedure would have previously been uneconomical, involving more computing power than simply committing to the expensive but supported operation.


C. Dynamic Sampling,



FIG. 9 shows a diagram of the output of a single transducer (shown as a large dot on the bottom of the figure) from the perspective of a single focus point. Moving a focus point a fraction of a wavelength in any direction will only produce a known upper bound on distance change. This also implies a upper bound on phase change required to focus to the point.


Focus points which are moved in the air modify the activation coefficients at the transducers. If the focus point is moved away or towards the transducer by half a wavelength, roughly speaking π is added to or subtracted from the phase exhibited by that transducer. If the focus point stays at a constant distance or is moving parallel to the acoustic wave front, then that phase will barely change upon movement. When interpolating between known points in the solution space in the complex plane representing two stages in the temporal evolution of a focus point a small distance spatially apart (say t and t+δ), a worst-case focusing error can be estimated that reveals how far the interpolation is from the linear travel of the focus point. This error decreases quickly as the distance between the adjacent focal point snapshots shrinks to less than half a wavelength. Taking this further, if reduced representation samples of the solution space to the device are sent, an acoustic field CFL-like stability condition may be defined based on increments of the spatial distance a focus point has travelled and not on temporal behavior. (In mathematics, the Courant-Friedrichs-Lewy (CFL) condition is a necessary condition for convergence while solving certain partial differential equations (usually hyperbolic partial different equations) numerically by the method of finite differences.)


The CFL-condition essentially describes how fast the system can be moved: a hyperbolic PDE system cannot be moved in a single step faster than a speed defined by the grid spacing or the errors can propagate and become potentially infinite. Thus, if a control point is moving along a path, an error-bound condition that is similar to the CFL condition may be calculated representing the maximum distance (typically this will be less than a wavelength) that can be moved in a single step while keeping the worst-case error below a threshold. It is then possible to compute (any or all of) the solver results (z vector)/eigensystem result/transducer activations (x vector) for the control points at these step points along the trajectory and interpolate between the results for each step to get the control points at any points in between, safe in the knowledge from the outset that worst case error bound is known for any of the transducer coefficients that are produced at the end of the process.


Then, using the condition that states sent to the device must be focusing to points that are not more than a certain distance apart, it is ensured that the requirements for the perturbed solutions of the distance and other arithmetic quantities are met while reducing the necessity to sample the solution space periodically in time.


D. Polynomial Sampling,



FIGS. 10 and 11 show the interpolation for a single transducer (shown as a large dot on the bottom of each figure) between two states, where the dashed line is the linear interpolation in distance. The acoustic field lines from each transducer affect the dashed line. Curvature changes between transducers for the dashed line causes defocusing in intermediate interpolated states. Using a high order polynomial can make the state follow the solid line, which preserves the focusing effect.


This approach can be taken still further. The limiting part of the previously described stability condition is that the state interpolation is conducted in the complex space. If this were to be relocated to a distance/amplitude space, while less accessible due to space conversions, the amount of defocusing would be reduced. However, relocating to a distance/amplitude space can be further augmented by creating higher order polynomial curves that described the change of the amplitude and distance of the transducer as the focus point moves through the field on some linear or polynomial trajectory. As the distance value is readily translated into a phase, creating linear or polynomial segments between the states in reduced representation becomes possible with very little defocusing along the path. This in turn enables further reductions in the device state update rate required to describe complex shapes. This can be achieved by, for instance, calculating gradients or performing a series expansion that converges on the correct path in the limit. It may also be helpful to use a weighted blending of two functions, one that represents the starting point exactly and approximates the interval and one that represents the end point exactly and approximates the interval. In this way, a function that gives a good approximation for the central interval may be created while still being exact on the beginning and ending points.


VII. Conclusion

The various features of the foregoing embodiments may be selected and combined to produce numerous variations of improved haptic systems.


In the foregoing specification, specific embodiments have been described. However, one of ordinary skill in the art appreciates that various modifications and changes can be made without departing from the scope of the invention as set forth in the claims below. Accordingly, the specification and figures are to be regarded in an illustrative rather than a restrictive sense, and all such modifications are intended to be included within the scope of present teachings.


The benefits, advantages, solutions to problems, and any element(s) that may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as a critical, required, or essential features or elements of any or all the claims. The invention is defined solely by the appended claims including any amendments made during the pendency of this application and all equivalents of those claims as issued.


Moreover in this document, relational terms such as first and second, top and bottom, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. The terms “comprises,” “comprising,” “has”, “having,” “includes”, “including,” “contains”, “containing” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises, has, includes, contains a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. An element proceeded by “comprises . . . a”, “has . . . a”, “includes . . . a”, “contains . . . a” does not, without more constraints, preclude the existence of additional identical elements in the process, method, article, or apparatus that comprises, has, includes, contains the element. The terms “a” and “an” are defined as one or more unless explicitly stated otherwise herein. The terms “substantially”, “essentially”, “approximately”, “about” or any other version thereof, are defined as being close to as understood by one of ordinary skill in the art. The term “coupled” as used herein is defined as connected, although not necessarily directly and not necessarily mechanically. A device or structure that is “configured” in a certain way is configured in at least that way, but may also be configured in ways that are not listed.


The Abstract of the Disclosure is provided to allow the reader to quickly ascertain the nature of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. In addition, in the foregoing Detailed Description, it can be seen that various features are grouped together in various embodiments for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the claimed embodiments require more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive subject matter lies in less than all features of a single disclosed embodiment. Thus the following claims are hereby incorporated into the Detailed Description, with each claim standing on its own as a separately claimed subject matter.

Claims
  • 1. A method comprising: i) a mid-air haptic feedback system producing an acoustic field from a transducer array having known relative positions and orientations to each other;ii) the mid-air haptic feedback system defining a plurality of control points wherein each of the plurality of control points has a known spatial relationship relative to the transducer array and has a control point activation coefficient; andiii) the mid-air haptic feedback system calculating a lowest power transducer activation coefficient vector that reproduces the control points within the acoustic field.
  • 2. The method as in claim 1, wherein calculating a lowest power transducer activation coefficient vector uses a Cholesky decomposition method.
  • 3. The method as in claim 2, wherein when the Cholesky decomposition method solves linear system Ax=b, the substitution AHz=x is applied to produce the equation AAHz=b.
  • 4. The method as in claim 2, wherein rows of the matrix AH correspond to transducer activation vectors proportional to an optimal single control point solution.
  • 5. The method as in claim 4, further comprising: transmitting the transducer activation vector via a bandwidth-constrained link.
  • 6. The method as in claim 5, further comprising: a less-flexible pipeline attached to the bandwidth-constrained link for decompressing the transducer activation vector into a relevant portion of an x solution.
  • 7. The method as in claim 6, further comprising: converting a relevant portion of the x solution and outputting the relevant portion of the x solution to transducer elements.
  • 8. The method as in claim 5, wherein transmitting the transducer activation vectors are updated at a frequency.
  • 9. The method as in claim 8, wherein the frequency is greater than an audible frequency.
  • 10. The method as in claim 9, wherein reduced audio output is effectuated.
  • 11. The method as in claim 9, further comprising: iv) the mid-air haptic feedback system actuating at control point positions of an index preset amplitude and zero phase offset control points;v) the mid-air haptic feedback system calculating an eigenvector based on the complex wave field sample matrix; andvi) the mid-air haptic feedback system adjusting the eigenvector to represent a plurality of control point activation coefficients.
  • 12. The method as in claim 11, wherein the transducer array comprises a plurality of transducers and wherein the step of calculating an amplitude for each of the plurality of control points is made by the mid-air haptic feedback system with fewer than all of the plurality of transducers.
  • 13. A system comprising: a mid-air haptic feedback system for producing an acoustic field from a transducer array having known relative positions and orientations to each other;a plurality of control points wherein each of the plurality of control points has a known spatial relationship relative to the transducer array and has a control point activation coefficient;wherein the mid-air haptic feedback system calculates reproducing the control points within the acoustic field using a Cholesky decomposition method that solves a linear system Ax=b via substitution AHz=x to produce the equation AAHz=b.
  • 14. The system as in claim 13, further comprising: transmission of coordinates of at least one of the plurality of control point in order to recreate an appropriate block of the matrix AH.
  • 15. The system as in claim 14, wherein the transmission occurs via a bandwidth-constrained link.
  • 16. The system as in claim 14, wherein the transmission comprises a transfer of a 3D coordinate and a real and imaginary component for a corresponding element of the solution vector z.
  • 17. The system as in claim 14, wherein a power transducer activation coefficient vector is recreated.
  • 18. The system as in claim 14, wherein the transmission of coordinates are updated at a frequency.
  • 19. The system as in claim 18, wherein the frequency is greater than an audible frequency.
  • 20. The system as in claim 19, wherein reduced audio output is produced.
RELATED APPLICATION

This application claims the benefit of the following six U.S. Provisional Patent Applications, all of which are incorporated by reference in their entirety: 1. Ser. No. 62/118,543, filed on Feb. 20, 2015.2. Ser. No. 62/141,935, filed on Apr. 2, 2015.3. Ser. No. 62/193,125, filed on Jul. 16, 2015.4. Ser. No. 62/193,194, filed on Jul. 16, 2015.5. Ser. No. 62/268,573, filed on Dec. 17, 2015.6. Ser. No. 62/275,002, filed on Jan. 5, 2016.

US Referenced Citations (346)
Number Name Date Kind
4218921 Berge Aug 1980 A
4760525 Webb Jul 1988 A
4771205 Mequio Sep 1988 A
4881212 Takeuchi Nov 1989 A
5226000 Moses Jul 1993 A
5235986 Maslak Aug 1993 A
5243344 Koulopoulos Sep 1993 A
5329682 Thurn Jul 1994 A
5371834 Tawel Dec 1994 A
5422431 Ichiki Jun 1995 A
5426388 Flora Jun 1995 A
5477736 Lorraine Dec 1995 A
5511296 Dias Apr 1996 A
5729694 Holzrichter Mar 1998 A
5859915 Norris Jan 1999 A
6029518 Oeftering Feb 2000 A
6193936 Gardner Feb 2001 B1
6216538 Yasuda Apr 2001 B1
6436051 Morris Aug 2002 B1
6503204 Sumanaweera Jan 2003 B1
6647359 Verplank Nov 2003 B1
6771294 Pulli Aug 2004 B1
6772490 Toda Aug 2004 B2
6800987 Toda Oct 2004 B2
7107159 German Sep 2006 B2
7109789 Spencer Sep 2006 B2
7182726 Williams Feb 2007 B2
7225404 Zilles May 2007 B1
7284027 Jennings, III Oct 2007 B2
7345600 Fedigan Mar 2008 B1
7487662 Schabron Feb 2009 B2
7497662 Mollmann Mar 2009 B2
7577260 Hooley Aug 2009 B1
7692661 Cook Apr 2010 B2
RE42192 Schabron Mar 2011 E
7966134 German Jun 2011 B2
8000481 Nishikawa Aug 2011 B2
8123502 Blakey Feb 2012 B2
8269168 Axelrod Sep 2012 B1
8279193 Birnbaum Oct 2012 B1
8351646 Fujimura Jan 2013 B2
8369973 Risbo Feb 2013 B2
8594350 Hooley Nov 2013 B2
8607922 Werner Dec 2013 B1
8782109 Tsutsui Jul 2014 B2
8823674 Birnbaum Sep 2014 B2
8833510 Koh Sep 2014 B2
8884927 Cheatham, III Nov 2014 B1
9208664 Peters Dec 2015 B1
9267735 Funayama Feb 2016 B2
9421291 Robert Aug 2016 B2
9612658 Subramanian Apr 2017 B2
9662680 Yamamoto May 2017 B2
9667173 Kappus May 2017 B1
9816757 Zielinski Nov 2017 B1
9841819 Carter Dec 2017 B2
9863699 Corbin, III Jan 2018 B2
9898089 Subramanian Feb 2018 B2
9945818 Ganti Apr 2018 B2
9958943 Long May 2018 B2
9977120 Carter May 2018 B2
10101811 Carter Oct 2018 B2
10101814 Carter Oct 2018 B2
10133353 Eid Nov 2018 B2
10140776 Schwarz Nov 2018 B2
10146353 Smith Dec 2018 B1
10168782 Tchon Jan 2019 B1
10268275 Carter Apr 2019 B2
10281567 Carter May 2019 B2
10318008 Sinha Jun 2019 B2
10444842 Long Oct 2019 B2
10469973 Hayashi Nov 2019 B2
10496175 Long Dec 2019 B2
10497358 Tester Dec 2019 B2
10510357 Kovesi Dec 2019 B2
10520252 Momen Dec 2019 B2
10523159 Megretski Dec 2019 B2
10531212 Long Jan 2020 B2
10535174 Rigiroli Jan 2020 B1
10569300 Hoshi Feb 2020 B2
10593101 Han Mar 2020 B1
10657704 Han May 2020 B1
10685538 Carter Jun 2020 B2
10755538 Carter Aug 2020 B2
10818162 Carter Oct 2020 B2
10911861 Buckland Feb 2021 B2
10915177 Carter Feb 2021 B2
10921890 Subramanian Feb 2021 B2
10930123 Carter Feb 2021 B2
10943578 Long Mar 2021 B2
11048329 Lee Jun 2021 B1
11098951 Kappus Aug 2021 B2
11113860 Rigiroli Sep 2021 B2
11169610 Sarafianou Nov 2021 B2
11189140 Long Nov 2021 B2
11204644 Long Dec 2021 B2
11276281 Carter Mar 2022 B2
11531395 Kappus Dec 2022 B2
11543507 Carter Jan 2023 B2
11550395 Beattie Jan 2023 B2
11550432 Carter Jan 2023 B2
11553295 Kappus Jan 2023 B2
20010007591 Pompei Jul 2001 A1
20010033124 Norris Oct 2001 A1
20020149570 Knowles Oct 2002 A1
20030024317 Miller Feb 2003 A1
20030144032 Brunner Jul 2003 A1
20030182647 Radeskog Sep 2003 A1
20040005715 Schabron Jan 2004 A1
20040014434 Haardt Jan 2004 A1
20040052387 Norris Mar 2004 A1
20040091119 Duraiswami May 2004 A1
20040210158 Organ Oct 2004 A1
20040226378 Oda Nov 2004 A1
20040264707 Yang Dec 2004 A1
20050052714 Klug Mar 2005 A1
20050056851 Althaus Mar 2005 A1
20050212760 Marvit Sep 2005 A1
20050226437 Pellegrini Oct 2005 A1
20050267695 German Dec 2005 A1
20050273483 Dent Dec 2005 A1
20060085049 Cory Apr 2006 A1
20060090955 Cardas May 2006 A1
20060091301 Trisnadi May 2006 A1
20060164428 Cook Jul 2006 A1
20070036492 Lee Feb 2007 A1
20070094317 Wang Apr 2007 A1
20070177681 Choi Aug 2007 A1
20070214462 Boillot Sep 2007 A1
20070236450 Colgate Oct 2007 A1
20070263741 Erving Nov 2007 A1
20080012647 Risbo Jan 2008 A1
20080027686 Mollmann Jan 2008 A1
20080084789 Altman Apr 2008 A1
20080130906 Goldstein Jun 2008 A1
20080152191 Fujimura Jun 2008 A1
20080226088 Aarts Sep 2008 A1
20080273723 Hartung Nov 2008 A1
20080300055 Lutnick Dec 2008 A1
20090093724 Pernot Apr 2009 A1
20090116660 Croft, III May 2009 A1
20090232684 Hirata Sep 2009 A1
20090251421 Bloebaum Oct 2009 A1
20090319065 Risbo Dec 2009 A1
20100013613 Weston Jan 2010 A1
20100016727 Rosenberg Jan 2010 A1
20100030076 Vortman Feb 2010 A1
20100044120 Richter Feb 2010 A1
20100066512 Rank Mar 2010 A1
20100085168 Kyung Apr 2010 A1
20100103246 Schwerdtner Apr 2010 A1
20100109481 Buccafusca May 2010 A1
20100199232 Mistry Aug 2010 A1
20100231508 Cruz-Hernandez Sep 2010 A1
20100262008 Roundhill Oct 2010 A1
20100302015 Kipman Dec 2010 A1
20100321216 Jonsson Dec 2010 A1
20110006888 Bae Jan 2011 A1
20110010958 Clark Jan 2011 A1
20110051554 Varray Mar 2011 A1
20110066032 Vitek Mar 2011 A1
20110199342 Vartanian Aug 2011 A1
20110310028 Camp, Jr. Dec 2011 A1
20120057733 Morii Mar 2012 A1
20120063628 Rizzello Mar 2012 A1
20120066280 Tsutsui Mar 2012 A1
20120223880 Birnbaum Sep 2012 A1
20120229400 Birnbaum Sep 2012 A1
20120229401 Birnbaum Sep 2012 A1
20120236689 Brown Sep 2012 A1
20120243374 Dahl Sep 2012 A1
20120249409 Toney Oct 2012 A1
20120249474 Pratt Oct 2012 A1
20120299853 Dagar Nov 2012 A1
20120307649 Park Dec 2012 A1
20120315605 Cho Dec 2012 A1
20130035582 Radulescu Feb 2013 A1
20130079621 Shoham Mar 2013 A1
20130094678 Scholte Apr 2013 A1
20130100008 Marti Apr 2013 A1
20130101141 McElveen Apr 2013 A1
20130173658 Adelman Jul 2013 A1
20130331705 Fraser Dec 2013 A1
20140027201 Islam Jan 2014 A1
20140104274 Hilliges Apr 2014 A1
20140139071 Yamamoto May 2014 A1
20140168091 Jones Jun 2014 A1
20140201666 Bedikian Jul 2014 A1
20140204002 Bennet Jul 2014 A1
20140265572 Siedenburg Sep 2014 A1
20140267065 Vincent Sep 2014 A1
20140269207 Baym Sep 2014 A1
20140269208 Baym Sep 2014 A1
20140269214 Baym Sep 2014 A1
20140270305 Baym Sep 2014 A1
20140320436 Modarres Oct 2014 A1
20140361988 Katz Dec 2014 A1
20140369514 Baym Dec 2014 A1
20150002477 Cheatham, III Jan 2015 A1
20150005039 Liu Jan 2015 A1
20150006645 Oh Jan 2015 A1
20150007025 Sassi Jan 2015 A1
20150013023 Wang Jan 2015 A1
20150019299 Harvey Jan 2015 A1
20150022466 Levesque Jan 2015 A1
20150029155 Lee Jan 2015 A1
20150066445 Lin Mar 2015 A1
20150070147 Cruz-Hernandez Mar 2015 A1
20150070245 Han Mar 2015 A1
20150078136 Sun Mar 2015 A1
20150081110 Houston Mar 2015 A1
20150084929 Lee Mar 2015 A1
20150110310 Minnaar Apr 2015 A1
20150130323 Harris May 2015 A1
20150168205 Lee Jun 2015 A1
20150192995 Subramanian Jul 2015 A1
20150220199 Wang Aug 2015 A1
20150226537 Schorre Aug 2015 A1
20150226831 Nakamura Aug 2015 A1
20150241393 Ganti Aug 2015 A1
20150248787 Abovitz Sep 2015 A1
20150258431 Stafford Sep 2015 A1
20150277610 Kim Oct 2015 A1
20150293592 Cheong Oct 2015 A1
20150304789 Babayoff Oct 2015 A1
20150323667 Przybyla Nov 2015 A1
20150331576 Piya Nov 2015 A1
20150332075 Burch Nov 2015 A1
20160019762 Levesque Jan 2016 A1
20160019879 Daley Jan 2016 A1
20160026253 Bradski Jan 2016 A1
20160044417 Clemen, Jr. Feb 2016 A1
20160124080 Carter May 2016 A1
20160138986 Carlin May 2016 A1
20160175701 Froy Jun 2016 A1
20160175709 Idris Jun 2016 A1
20160189702 Blanc Jun 2016 A1
20160242724 Lavallee Aug 2016 A1
20160246374 Carter Aug 2016 A1
20160249150 Carter Aug 2016 A1
20160291716 Boser Oct 2016 A1
20160306423 Uttermann Oct 2016 A1
20160320843 Long Nov 2016 A1
20160339132 Cosman Nov 2016 A1
20160374562 Vertikov Dec 2016 A1
20170002839 Bukland Jan 2017 A1
20170004819 Ochiai Jan 2017 A1
20170018171 Carter Jan 2017 A1
20170024921 Beeler Jan 2017 A1
20170052148 Estevez Feb 2017 A1
20170123487 Hazra May 2017 A1
20170123499 Eid May 2017 A1
20170140552 Woo May 2017 A1
20170144190 Hoshi May 2017 A1
20170153707 Subramanian Jun 2017 A1
20170168586 Sinha Jun 2017 A1
20170181725 Han Jun 2017 A1
20170193768 Long Jul 2017 A1
20170193823 Jiang Jul 2017 A1
20170211022 Reinke Jul 2017 A1
20170236506 Przybyla Aug 2017 A1
20170270356 Sills Sep 2017 A1
20170279951 Hwang Sep 2017 A1
20170336860 Smoot Nov 2017 A1
20170366908 Long Dec 2017 A1
20180035891 Van Soest Feb 2018 A1
20180039333 Carter Feb 2018 A1
20180047259 Carter Feb 2018 A1
20180074580 Hardee Mar 2018 A1
20180081439 Daniels Mar 2018 A1
20180101234 Carter Apr 2018 A1
20180139557 Ochiai May 2018 A1
20180146306 Benattar May 2018 A1
20180151035 Maalouf May 2018 A1
20180166063 Long Jun 2018 A1
20180181203 Subramanian Jun 2018 A1
20180182372 Tester Jun 2018 A1
20180190007 Panteleev Jul 2018 A1
20180246576 Long Aug 2018 A1
20180253627 Baradel Sep 2018 A1
20180267156 Carter Sep 2018 A1
20180304310 Long Oct 2018 A1
20180309515 Murakowski Oct 2018 A1
20180310111 Kappus Oct 2018 A1
20180350339 Macours Dec 2018 A1
20180361174 Radulescu Dec 2018 A1
20190038496 Levesque Feb 2019 A1
20190091565 Nelson Mar 2019 A1
20190163275 Iodice May 2019 A1
20190175077 Zhang Jun 2019 A1
20190187244 Riccardi Jun 2019 A1
20190196578 Iodice Jun 2019 A1
20190196591 Long Jun 2019 A1
20190197840 Kappus Jun 2019 A1
20190197841 Carter Jun 2019 A1
20190197842 Long Jun 2019 A1
20190204925 Long Jul 2019 A1
20190206202 Carter Jul 2019 A1
20190235628 Lacroix Aug 2019 A1
20190257932 Carter Aug 2019 A1
20190310710 Deeley Oct 2019 A1
20190342654 Buckland Nov 2019 A1
20200042091 Long Feb 2020 A1
20200080776 Kappus Mar 2020 A1
20200082804 Kappus Mar 2020 A1
20200103974 Carter Apr 2020 A1
20200117229 Long Apr 2020 A1
20200193269 Park Jun 2020 A1
20200218354 Beattie Jul 2020 A1
20200257371 Sung Aug 2020 A1
20200294299 Rigiroli Sep 2020 A1
20200302760 Carter Sep 2020 A1
20200320347 Nikolenko Oct 2020 A1
20200327418 Lyons Oct 2020 A1
20200380832 Carter Dec 2020 A1
20210037332 Kappus Feb 2021 A1
20210043070 Carter Feb 2021 A1
20210109712 Long Apr 2021 A1
20210111731 Long Apr 2021 A1
20210112353 Kappus Apr 2021 A1
20210141458 Sarafianou May 2021 A1
20210165491 Sun Jun 2021 A1
20210170447 Buckland Jun 2021 A1
20210183215 Carter Jun 2021 A1
20210201884 Kappus Jul 2021 A1
20210225355 Long Jul 2021 A1
20210303072 Carter Sep 2021 A1
20210303758 Long Sep 2021 A1
20210334706 Yamaguchi Oct 2021 A1
20210381765 Kappus Dec 2021 A1
20210397261 Kappus Dec 2021 A1
20220035479 Lasater Feb 2022 A1
20220083142 Brown Mar 2022 A1
20220095068 Kappus Mar 2022 A1
20220113806 Long Apr 2022 A1
20220155949 Ring May 2022 A1
20220236806 Carter Jul 2022 A1
20220252550 Catsis Aug 2022 A1
20220300028 Long Sep 2022 A1
20220300070 Iodice Sep 2022 A1
20220329250 Long Oct 2022 A1
20220393095 Chilles Dec 2022 A1
20230036123 Long Feb 2023 A1
20230075917 Pittera Mar 2023 A1
20230117919 Iodice Apr 2023 A1
20230124704 Rorke Apr 2023 A1
Foreign Referenced Citations (70)
Number Date Country
2470115 Jun 2003 CA
2909804 Nov 2014 CA
101986787 Mar 2011 CN
102459900 May 2012 CN
102591512 Jul 2012 CN
103797379 May 2014 CN
103984414 Aug 2014 CN
107340871 Nov 2017 CN
107407969 Nov 2017 CN
107534810 Jan 2018 CN
0057594 Aug 1982 EP
309003 Mar 1989 EP
0696670 Feb 1996 EP
1875081 Jan 2008 EP
1911530 Apr 2008 EP
2271129 Jan 2011 EP
1461598 Apr 2014 EP
3207817 Aug 2017 EP
3216231 Aug 2019 EP
3916525 Dec 2021 EP
2464117 Apr 2010 GB
2513884 Nov 2014 GB
2513884 Nov 2014 GB
2530036 Mar 2016 GB
2008074075 Apr 2008 JP
2010109579 May 2010 JP
2011172074 Sep 2011 JP
2012048378 Mar 2012 JP
2012048378 Mar 2012 JP
5477736 Apr 2014 JP
2015035657 Feb 2015 JP
2016035646 Mar 2016 JP
2017168086 Sep 2017 JP
6239796 Nov 2017 JP
20120065779 Jun 2012 KR
20130055972 May 2013 KR
1020130055972 May 2013 KR
20160008280 Jan 2016 KR
20200082449 Jul 2020 KR
9118486 Nov 1991 WO
9639754 Dec 1996 WO
03050511 Jun 2003 WO
2005017965 Feb 2005 WO
2007144801 Dec 2007 WO
2009071746 Jun 2009 WO
2009112866 Sep 2009 WO
2010003836 Jan 2010 WO
2010139916 Dec 2010 WO
2011132012 Oct 2011 WO
2012023864 Feb 2012 WO
2012104648 Aug 2012 WO
2013179179 Dec 2013 WO
2014181084 Nov 2014 WO
2015006467 Jan 2015 WO
2015039622 Mar 2015 WO
2015127335 Aug 2015 WO
2015194510 Dec 2015 WO
2016007920 Jan 2016 WO
2016073936 May 2016 WO
2016095033 Jun 2016 WO
2016099279 Jun 2016 WO
2016132141 Aug 2016 WO
2016132144 Aug 2016 WO
2016137675 Sep 2016 WO
2016162058 Oct 2016 WO
2017172006 Oct 2017 WO
2018109466 Jun 2018 WO
2020049321 Mar 2020 WO
2021130505 Jul 2021 WO
2021260373 Dec 2021 WO
Non-Patent Literature Citations (338)
Entry
Communication Pursuant to Article 94(3) EPC for EP 19723179.8 (dated Feb. 15, 2022).
EPO ISR and WO for PCT/GB2022/050204 (dated Apr. 7, 2022) (15 pages).
IN 202047026493 Office Action dated Mar. 8, 2022.
ISR & WO For PCT/GB2021/052946.
Office Action (Non-Final Rejection) dated Apr. 1, 2022 for U.S. Appl. No. 16/229,091 (pp. 1-10).
Office Action (Non-Final Rejection) dated May 2, 2022 for U.S. Appl. No. 17/068,831 (pp. 1-10).
ISR & WO for PCT/GB2022/051388 (dated Aug. 30, 2022) (15 pages).
Office Action (Final Rejection) dated Sep. 16, 2022 for U.S. Appl. No. 16/404,660 (pp. 1-6).
Office Action (Non-Final Rejection) dated Aug. 29, 2022 for U.S. Appl. No. 16/995,819 (pp. 1-6).
Office Action (Non-Final Rejection) dated Sep. 21, 2022 for U.S. Appl. No. 17/721,315 (pp. 1-10).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Aug. 24, 2022 for U.S. Appl. No. 16/198,959 (pp. 1-6).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Aug. 31, 2022 for U.S. Appl. No. 16/198,959 (pp. 1-2).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Sep. 7, 2022 for U.S. Appl. No. 17/068,834 (pp. 1-8).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Sep. 8, 2022 for U.S. Appl. No. 17/176,899 (pp. 1-8).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Sep. 12, 2022 for U.S. Appl. No. 16/734,479 (pp. 1-7).
Almusawi et al., “A new artificial neural network approach in solving inverse kinematics of robotic arm (denso vp6242).” Computational intelligence and neuroscience 2016 (2016). (Year: 2016).
Azad et al., Deep domain adaptation under deep label scarcity. arXiv preprint arXiv:1809.08097 (2018) (Year: 2018).
Beranek, L., & Mellow, T. (2019). Acoustics: Sound Fields, Transducers and Vibration. Academic Press.
Boureau et al., “A theoretical analysis of feature pooling in visual recognition.” In Proceedings of the 27th international conference on machine learning (ICML-10), pp. 111-118. 2010. (Year: 2010).
Bybi, A., Grondel, S., Mzerd, A., Granger, C., Garoum, M., & Assaad, J. (2019). Investigation of cross-coupling in piezoelectric transducer arrays and correction. International Journal of Engineering and Technology Innovation, 9(4), 287.
Certon, D., Felix, N., Hue, P. T. H., Patat, F., & Lethiecq, M. (Oct. 1999). Evaluation of laser probe performances for measuring cross-coupling in 1-3 piezocomposite arrays. In 1999 IEEE Ultrasonics Symposium. Proceedings. International Symposium (Cat. No. 99CH37027) (vol. 2, pp. 1091-1094).
Certon, D., Felix, N., Lacaze, E., Teston, F., & Patat, F. (2001). Investigation of cross-coupling in 1-3 piezocomposite arrays. IEEE transactions on ultrasonics, ferroelectrics, and frequency control, 48(1), 85-92.
Chang Suk Lee et al., An electrically switchable visible to infra-red dual frequency cholesteric liquid crystal light shutter, J. Mater. Chem. C, 2018, 6, 4243 (7 pages).
Der et al., Inverse kinematics for reduced deformable models. ACM Transactions on graphics (TOG) 25, No. 3 (2006): 1174-1179. (Year: 2006).
DeSilets, C. S. (1978). Transducer arrays suitable for acoustic imaging (No. GL-2833). Stanford Univ CA Edward L Ginzton Lab of Physics.
Duka, “Neural network based inverse kinematics solution for trajectory tracking of a robotic arm.” Procedia Technology 12 (2014) 20-27. (Year: 2014).
Henneberg, J., Gerlach, A., Storck, H., Cebulla, H., & Marburg, S. (2018). Reducing mechanical cross-coupling in phased array transducers using stop band material as backing. Journal of Sound and Vibration, 424, 352-364.
https://radiopaedia.org/articles/physical-principles-of-ultrasound-1?lang=gb (Accessed May 29, 2022).
Office Action (Non-Final Rejection) dated May 25, 2022 for U.S. Appl. No. 16/843,281 (pp. 1-28).
Office Action (Non-Final Rejection) dated Jun. 9, 2022 for U.S. Appl. No. 17/080,840 (pp. 1-9).
Office Action (Non-Final Rejection) dated Jun. 27, 2022 for U.S. Appl. No. 16/198,959 (pp. 1-17).
Office Action (Non-Final Rejection) dated Jun. 27, 2022 for U.S. Appl. No. 16/734,479 (pp. 1-13).
Oikonomidis et al., “Efficient model-based 3D tracking of hand articulations using Kinect.” In BmVC, vol. 1, No. 2, p. 3. 2011. (Year: 2011).
Patricio Rodrigues, E., Francisco de Oliveira, T., Yassunori Matuda, M., & Buiochi, F. (Sep. 2019). Design and Construction of a 2-D Phased Array Ultrasonic Transducer for Coupling in Water. In INTER-NOISE and NOISE-CON Congress and Conference Proceedings (vol. 259, No. 4, pp. 5720-5731). Institute of Noise Control Engineering.
Seo et al., “Improved numerical inverse kinematics for human pose estimation,” Opt. Eng. 50(3 037001 (Mar. 1, 2011) https:// doi.org/10.1117/1.3549255 (Year: 2011).
Walter, S., Nieweglowski, K., Rebenklau, L., Wolter, K. J., Lamek, B., Schubert, F., . . . & Meyendorf, N. (May 2008). Manufacturing and electrical interconnection of piezoelectric 1-3 composite materials for phased array ultrasonic transducers. In 2008 31st International Spring Seminar on Electronics Technology (pp. 255-260).
Wang et al., Few-shot adaptive faster r-cnn. In Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition, pp. 7173-7182. 2019. (Year: 2019).
Aksel Sveier et al.,Pose Estimation with Dual Quaternions and Iterative Closest Point, 2018 Annual American Control Conference (ACC) (8 pages).
JP Office Action for JP 2020-534355 (dated Dec. 6, 2022) (8 pages).
Ken Wada, Ring Buffer Basics (2013) 6 pages.
Notice of Allowance dated Feb. 23, 2023 for U.S. Appl. No. 18/060,556 (pp. 1-10).
Office Action (Final Rejection) dated Mar. 21, 2023 for U.S. Appl. No. 16/995,819 (pp. 1-7).
Office Action (Non-Final Rejection) dated Mar. 1, 2023 for U.S. Appl. No. 16/564,016 (pp. 1-10).
Office Action (Non-Final Rejection) dated Mar. 22, 2023 for U.S. Appl. No. 17/354,636 (pp. 1-5).
Office Action (Non-Final Rejection) dated Apr. 19, 2023 for U.S. Appl. No. 18/066,267 (pp. 1-11).
Office Action (Non-Final Rejection) dated Apr. 27, 2023 for U.S. Appl. No. 16/229,091 (pp. 1-5).
Office Action (Non-Final Rejection) dated May 8, 2023 for U.S. Appl. No. 18/065,603 (pp. 1-17).
Office Action (Non-Final Rejection) dated May 10, 2023 for U.S. Appl. No. 17/477,536 (pp. 1-13).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Mar. 8, 2023 for U.S. Appl. No. 17/721,315 (pp. 1-8).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Mar. 15, 2023 for U.S. Appl. No. 17/134,505 (pp. 1-5).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Mar. 24, 2023 for U.S. Appl. No. 17/080,840 (pp. 1-8).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Apr. 4, 2023 for U.S. Appl. No. 17/409,783 (pp. 1-5).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Apr. 6, 2023 for U.S. Appl. No. 17/807,730 (pp. 1-7).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Apr. 28, 2023 for U.S. Appl. No. 17/195,795 (pp. 1-7).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated May 12, 2023 for U.S. Appl. No. 16/229,091 (pp. 1-8).
Office Action dated Feb. 9, 2023 for U.S. Appl. No. 18/060,556 (pp. 1-5).
Office Action dated Mar. 3, 2023 for U.S. Appl. No. 18/060,525 (pp. 1-12).
Office Action dated Apr. 19, 2023 for U.S. Appl. No. 18/066,267 (pp. 1-11).
Partial ISR for PCT/GB2023/050001 (dated Mar. 31, 2023) 13 pages.
Rakkolainen et al., A Survey of Mid-Air Ultrasound Haptics and Its Applications (IEEE Transactions on Haptics), vol. 14, No. 1, 2021, 18 pages.
Al-Mashhadany, “Inverse Kinematics Problem (IKP) of 6-DOF Manipulator By Locally Recurrent Neural Networks (LRNNs),” Management and Service Science (MASS), International Conference on Management and Service Science., IEEE, Aug. 24, 2010, 5 pages. (Year: 2010).
Guez, “Solution to the inverse kinematic problem in robotics by neural networks.” In Proceedings of the 2nd International Conference on Neural Networks, 1988. San Diego, California. (Year: 1988) 8 pages.
Invitation to Pay Additional Fees for PCT/GB2022/051821 (dated Oct. 20, 2022), 15 pages.
Mahboob, “Artificial neural networks for learning inverse kinematics of humanoid robot arms.” MS Thesis, 2015. (Year: 2015) 95 pages.
Office Action (Ex Parte Quayle Action) dated Jan. 6, 2023 for U.S. Appl. No. 17/195,795 (pp. 1-6).
Office Action (Final Rejection) dated Jan. 9, 2023 for U.S. Appl. No. 16/144,474 (pp. 1-16).
Office Action (Final Rejection) dated Nov. 18, 2022 for U.S. Appl. No. 16/228,767 (pp. 1-27).
Office Action (Final Rejection) dated Nov. 18, 2022 for U.S. Appl. No. 17/068,831 (pp. 1-9).
Office Action (Final Rejection) dated Dec. 8, 2022 for U.S. Appl. No. 16/229,091 (pp. 1-9).
Office Action (Final Rejection) dated Dec. 15, 2022 for U.S. Appl. No. 16/843,281 (pp. 1-25).
Office Action (Non-Final Rejection) dated Oct. 17, 2022 for U.S. Appl. No. 17/807,730 (pp. 1-8).
Office Action (Non-Final Rejection) dated Nov. 9, 2022 for U.S. Appl. No. 17/454,823 (pp. 1-16).
Office Action (Non-Final Rejection) dated Nov. 16, 2022 for U.S. Appl. No. 17/134,505 (pp. 1-7).
Office Action (Non-Final Rejection) dated Dec. 6, 2022 for U.S. Appl. No. 17/409,783 (pp. 1-7).
Office Action (Non-Final Rejection) dated Dec. 22, 2022 for U.S. Appl. No. 17/457,663 (pp. 1-20).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Oct. 31, 2022 for U.S. Appl. No. 17/068,834 (pp. 1-2).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Oct. 31, 2022 for U.S. Appl. No. 17/176,899 (pp. 1-2).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Nov. 1, 2022 for U.S. Appl. No. 16/404,660 (pp. 1-5).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Nov. 2, 2022 for U.S. Appl. No. 16/734,479 (pp. 1-2).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Nov. 10, 2022 for U.S. Appl. No. 16/198,959 (pp. 1-2).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Nov. 16, 2022 for U.S. Appl. No. 16/404,660 (pp. 1-2).
“Welcome to Project Soli” video, https://atap.google.com/#project-soli Accessed Nov. 30, 2018, 2 pages.
A. B. Vallbo, Receptive field characteristics of tactile units with myelinated afferents in hairy skin of human subjects, Journal of Physiology (1995), 483.3, pp. 783-795.
A. Sand, Head-Mounted Display with Mid-Air Tactile Feedback, Proceedings of the 21st ACM Symposium on Virtual Reality Software and Technology, Nov. 13-15, 2015 (8 pages).
Alexander, J. et al. (2011), Adding Haptic Feedback to Mobile TV (6 pages).
Amanda Zimmerman, The gentle touch receptors of mammalian skin, Science, Nov. 21, 2014, vol. 346 Issue 6212, p. 950.
Anonymous: “How does Ultrahaptics technology work?—Ultrahaptics Developer Information”, Jul. 31, 2018 (Jul. 31, 2018), XP055839320, Retrieved from the Internet: URL:https://developer.ultrahaptics.com/knowledgebase/haptics-overview/ [retrieved on Sep. 8, 2021].
Aoki et al., Sound location of stero reproduction with parametric loudspeakers, Applied Acoustics 73 (2012) 1289-1295 (7 pages).
Ashish Shrivastava et al., Learning from Simulated and Unsupervised Images through Adversarial Training, Jul. 19, 2017, pp. 1-16.
Bajard et al., BKM: A New Hardware Algorithm for Complex Elementary Functions, 8092 IEEE Transactions on Computers 43 (1994) (9 pages).
Bajard et al., Evaluation of Complex Elementary Functions / A New Version of BKM, SPIE Conference on Advanced Signal Processing, Jul. 1999 (8 pages).
Benjamin Long et al, “Rendering volumetric haptic shapes in mid-air using ultrasound”, ACM Transactions on Graphics (TOG), ACM, US, (Nov. 19, 2014), vol. 33, No. 6, ISSN 0730-0301, pp. 1-10.
Bortoff et al., Pseudolinearization of the Acrobot using Spline Functions, IEEE Proceedings of the 31st Conference on Decision and Control, Sep. 10, 1992 (6 pages).
Bożena Smagowska & Małgorzata Pawlaczyk-Łuszczyńska (2013) Effects of Ultrasonic Noise on the Human Body—A Bibliographic Review, International Journal of Occupational Safety and Ergonomics, 19:2, 195-202.
Brian Kappus and Ben Long, Spatiotemporal Modulation for Mid-Air Haptic Feedback from an Ultrasonic Phased Array, ICSV25, Hiroshima, Jul. 8-12, 2018, 6 pages.
Canada Application 2,909,804 Office Action dated Oct. 18, 2019, 4 pages.
Casper et al., Realtime Control of Multiple-focus Phased Array Heating Patterns Based on Noninvasive Ultrasound Thermography, IEEE Trans Biomed Eng. Jan. 2012; 59(1): 95-105.
Christoper M. Bishop, Pattern Recognition and Machine Learning, 2006, pp. 1-758.
Colgan, A., “How Does the Leap Motion Controller Work?” Leap Motion, Aug. 9, 2014, 10 pages.
Corrected Notice of Allowability dated Aug. 9, 2021 for U.S. Appl. No. 15/396,851 (pp. 1-6).
Corrected Notice of Allowability dated Jan. 14, 2021 for U.S. Appl. No. 15/897,804 (pp. 1-2).
Corrected Notice of Allowability dated Jun. 21, 2019 for U.S. Appl. No. 15/966,213 (2 pages).
Corrected Notice of Allowability dated Nov. 24, 2021 for U.S. Appl. No. 16/600,500 (pp. 1-5).
Corrected Notice of Allowability dated Oct. 31, 2019 for U.S. Appl. No. 15/623,516 (pp. 1-2).
Damn Geeky, “Virtual projection keyboard technology with haptic feedback on palm of your hand,” May 30, 2013, 4 pages.
David Joseph Tan et al., Fits like a Glove: Rapid and Reliable Hand Shape Personalization, 2016 IEEE Conference on Computer Vision and Pattern Recognition, pp. 5610-5619.
Definition of “Interferometry” according to Wikipedia, 25 pages., Retrieved Nov. 2018.
Definition of “Multilateration” according to Wikipedia, 7 pages., Retrieved Nov. 2018.
Definition of “Trilateration” according to Wikipedia, 2 pages., Retrieved Nov. 2018.
Diederik P. Kingma et al., Adam: A Method for Stochastic Optimization, Jan. 30, 2017, pp. 1-15.
E. Bok, Metasurface for Water-to-Air Sound Transmission, Physical Review Letters 120, 044302 (2018) (6 pages).
E.S. Ebbini et al. (1991), A spherical-section ultrasound phased array applicator for deep localized hyperthermia, Biomedical Engineering, IEEE Transactions on (vol. 38 Issue: 7), pp. 634-643.
EPO 21186570.4 Extended Search Report dated Oct. 29, 2021.
EPO Application 18 725 358.8 Examination Report dated Sep. 22, 2021.
EPO Communication for Application 18 811 906.9 (dated Nov. 29, 2021) (15 pages).
EPO Examination Report 17 748 4656.4 (dated Jan. 12, 2021) (16 pages).
EPO Examination Search Report 17 702 910.5 (dated Jun. 23, 2021).
EPO Office Action for EP16708440.9 dated Sep. 12, 2018 (7 pages).
EPSRC Grant summary EP/J004448/1 (2011) (1 page).
Eric Tzeng et al., Adversarial Discriminative Domain Adaptation, Feb. 17, 2017, pp. 1-10.
European Office Action for Application No. EP16750992.6, dated Oct. 2, 2019, 3 pages.
Ex Parte Quayle Action dated Dec. 28, 2018 for U.S. Appl. No. 15/966,213 (pp. 1-7).
Extended European Search Report for Application No. EP19169929.7, dated Aug. 6, 2019, 7 pages.
Freeman et al., Tactile Feedback for Above-Device Gesture Interfaces: Adding Touch to Touchless Interactions ICMI'14, Nov. 12-16, 2014, Istanbul, Turkey (8 pages).
Gareth Young et al.. Designing Mid-Air Haptic Gesture Controlled User Interfaces for Cars, PACM on Human-Computer Interactions, Jun. 2020 (24 pages).
Gavrilov L R et al (2000) “A theoretical assessment of the relative performance of spherical phased arrays for ultrasound surgery” Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on (vol. 47, Issue: 1), pp. 125-139.
Gavrilov, L.R. (2008) “The Possibility of Generating Focal Regions of Complex Configurations in Application to the Problems of Stimulation of Human Receptor Structures by Focused Ultrasound” Acoustical Physics, vol. 54, No. 2, pp. 269-278.
Georgiou et al., Haptic In-Vehicle Gesture Controls, Adjunct Proceedings of the 9th International ACM Conference on Automotive User Interfaces and Interactive Vehicular Applications (AutomotiveUI '17), Sep. 24-27, 2017 (6 pages).
GitHub—danfis/libccd: Library for collision detection between two convex shapes, Mar. 26, 2020, pp. 1-6.
GitHub—IntelRealSense/hand_tracking_samples: researc codebase for depth-based hand pose estimation using dynamics based tracking and CNNs, Mar. 26, 2020, 3 pages.
Gokturk, et al., “A Time-of-Flight Depth Sensor-System Description, Issues and Solutions,” Published in: 2004 Conference on Computer Vision and Pattern Recognition Workshop, Date of Conference: Jun. 27-Jul. 2, 2004, 9 pages.
Hasegawa, K. and Shinoda, H. (2013) “Aerial Display of Vibrotactile Sensation with High Spatial-Temporal Resolution using Large Aperture Airbourne Ultrasound Phased Array”, University of Tokyo (6 pages).
Henrik Bruus, Acoustofluidics 2: Perturbation theory and ultrasound resonance modes, Lab Chip, 2012, 12, 20-28.
Hilleges et al. Interactions in the air: adding further depth to interactive tabletops, UIST '09: Proceedings of the 22nd annual ACM symposium on User interface software and technology Oct. 2009 pp. 139-148.
Hoshi et al., Tactile Presentation by Airborne Ultrasonic Oscillator Array, Proceedings of Robotics and Mechatronics Lecture 2009, Japan Society of Mechanical Engineers; May 24, 2009 (5 pages).
Hoshi T et al, “Noncontact Tactile Display Based on Radiation Pressure of Airborne Ultrasound”, IEEE Transactions on Haptics, IEEE, USA, (Jul. 1, 2010), vol. 3, No. 3, ISSN 1939-1412, pp. 155-165.
Hoshi, T., Development of Aerial-Input and Aerial-Tactile-Feedback System, IEEE World Haptics Conference 2011, p. 569-573.
Hoshi, T., Handwriting Transmission System Using Noncontact Tactile Display, IEEE Haptics Symposium 2012 pp. 399-401.
Hoshi, T., Non-contact Tactile Sensation Synthesized by Ultrasound Transducers, Third Joint Euro haptics Conference and Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems 2009 (5 pages).
Hoshi, T., Touchable Holography, SIGGRAPH 2009, New Orleans, Louisiana, Aug. 3-7, 2009. (1 page).
Hua J, Qin H., Haptics-based dynamic implicit solid modeling, IEEE Trans Vis Comput Graph. Sep.-Oct. 2004;10(5):574-86.
Hyunjae Gil, Whiskers: Exploring the Use of Ultrasonic Haptic Cues on the Face, CHI 2018, Apr. 21-26, 2018, Montréal, QC, Canada.
Iddan, et al., “3D Imaging in the Studio (And Elsewhwere . . . ” Apr. 2001, 3DV systems Ltd., Yokneam, Isreal, www.3dvsystems.com.il, 9 pages.
Imaginary Phone: Learning Imaginary Interfaces by Transferring Spatial Memory From a Familiar Device Sean Gustafson, Christian Holz and Patrick Baudisch. UIST 2011. (10 pages).
India Morrison, The skin as a social organ, Exp Brain Res (2010) 204:305-314.
International Preliminary Report on Patentability and Written Opinion issued in corresponding PCT/US2017/035009, dated Dec. 4, 2018, 8 pages.
International Preliminary Report on Patentability for Application No. PCT/EP2017/069569 dated Feb. 5, 2019, 11 pages.
International Search Report and Written Opinion for App. No. PCT/GB2021/051590, dated Nov. 11, 2021, 20 pages.
International Search Report and Written Opinion for Application No. PCT/GB2018/053738, dated Apr. 11, 2019, 14 pages.
International Search Report and Written Opinion for Application No. PCT/GB2018/053739, dated Jun. 4, 2019, 16 pages.
International Search Report and Written Opinion for Application No. PCT/GB2019/050969, dated Jun. 13, 2019, 15 pages.
International Search Report and Written Opinion for Application No. PCT/GB2019/051223, dated Aug. 8, 2019, 15 pages.
International Search Report and Written Opinion for Application No. PCT/GB2019/052510, dated Jan. 14, 2020, 25 pages.
ISR & WO for PCT/GB2020/052545 (dated Jan. 27, 2021) 14 pages.
ISR and WO for PCT/GB2020/050013 (dated Jul. 13, 2020) (20 pages).
ISR and WO for PCT/GB2020/050926 (dated Jun. 2, 2020) (16 pages).
ISR and WO for PCT/GB2020/052544 (dated Dec. 18, 2020) (14 pages).
ISR and WO for PCT/GB2020/052829 (dated Feb. 10, 2021) (15 pages).
ISR and WO for PCT/GB2021/052415 (dated Dec. 22, 2021) (16 pages).
ISR for PCT/GB2020/052546 (dated Feb. 23, 2021) (14 pages).
ISR for PCT/GB2020/053373 (dated Mar. 26, 2021) (16 pages).
Iwamoto et al. (2008), Non-contact Method for Producing Tactile Sensation Using Airborne Ultrasound, EuroHaptics, pp. 504-513.
Iwamoto et al., Airborne Ultrasound Tactile Display: Supplement, The University of Tokyo 2008 (2 pages).
Iwamoto T et al, “Two-dimensional Scanning Tactile Display using Ultrasound Radiation Pressure”, Haptic Interfaces for Virtual Environment and Teleoperator Systems, 2006 14th Symposium on Alexandria, VA, USA Mar. 25-26, 2006, Piscataway, NJ, USA,IEEE, (Mar. 25, 2006), ISBN 978-1-4244-0226-7, pp. 57-61.
Jager et al., “Air-Coupled 40-KHZ Ultrasonic 2D-Phased Array Based on a 3D-Printed Waveguide Structure”, 2017 IEEE, 4 pages.
Japanese Office Action (with English language translation) for Application No. 2017-514569, dated Mar. 31, 2019, 10 pages.
JonasChatel-Goldman, Touch increases autonomic coupling between romantic partners, Frontiers in Behavioral Neuroscience Mar. 2014, vol. 8, Article 95.
Jonathan Taylor et al., Articulated Distance Fields for Ultra-Fast Tracking of Hands Interacting, ACM Transactions on Graphics, vol. 36, No. 4, Article 244, Publication Date: Nov. 2017, pp. 1-12.
Jonathan Taylor et al., Efficient and Precise Interactive Hand Tracking Through Joint, Continuous Optimization of Pose and Correspondences, SIGGRAPH '16 Technical Paper, Jul. 24-28, 2016, Anaheim, CA, ISBN: 978-1-4503-4279-87/16/07, pp. 1-12.
Jonathan Tompson et al., Real-Time Continuous Pose Recovery of Human Hands Using Convolutional Networks, ACM Trans. Graph. 33, 5, Article 169, Aug. 2014, pp. 1-10.
K. Jia, Dynamic properties of micro-particles in ultrasonic transportation using phase-controlled standing waves, J. Applied Physics 116, n. 16 (2014) (12 pages).
Kai Tsumoto, Presentation of Tactile Pleasantness Using Airborne Ultrasound, 2021 IEEE World Haptics Conference (WHC) Jul. 6-9, 2021. Montreal, Canada.
Kaiming He et al., Deep Residual Learning for Image Recognition, http://image-net.org/challenges/LSVRC/2015/ and http://mscoco.org/dataset/#detections-challenge2015, Dec. 10, 2015, pp. 1-12.
Kamakura, T. and Aoki, K. (2006) “A Highly Directional Audio System using a Parametric Array in Air” WESPAC IX 2006 (8 pages).
Keisuke Hasegawa, Electronically steerable ultrasound-driven long narrow air stream, Applied Physics Letters 111, 064104 (2017).
Keisuke Hasegawa, Midair Ultrasound Fragrance Rendering, IEEE Transactions on Visualization and Computer Graphics, vol. 24, No. 4, Apr. 2018 1477.
Keisuke Hasegawa,,Curved acceleration path of ultrasound-driven air flow, J. Appl. Phys. 125, 054902 (2019).
Kolb, et al., “Time-of-Flight Cameras in Computer Graphics,” Computer Graphics forum, vol. 29 (2010), No. 1, pp. 141-159.
Konstantinos Bousmalis et al., Domain Separation Networks, 29th Conference on Neural Information Processing Sysgtems (NIPS 2016), Barcelona, Spain. Aug. 22, 2016, pp. 1-15.
Krim, et al., “Two Decades of Array Signal Processing Research—The Parametric Approach”, IEEE Signal Processing Magazine, Jul. 1996, pp. 67-94.
Lang, Robert, “3D Time-of-Flight Distance Measurement with Custom Solid-State Image Sensors in CMOS/CCD—Technology”, A dissertation submitted to Department of EE and CS at Univ. of Siegen, dated Jun. 28, 2000, 223 pages.
Large et al.,Feel the noise: Mid-air ultrasound haptics as a novel human-vehicle interaction paradigm, Applied Ergonomics (2019) (10 pages).
Li, Larry, “Time-of-Flight Camera—An Introduction,” Texas Instruments, Technical White Paper, SLOA190B—Jan. 2014 Revised May 2014, 10 pages.
Light, E.D., Progress in Two Dimensional Arrays for Real Time Volumetric Imaging, 1998 (17 pages).
Line S Loken, Coding of pleasant touch by unmyelinated afferents in humans, Nature Neuroscience vol. 12 [ No. 5 [ May 2009 547.
M. Barmatz et al, “Acoustic radiation potential on a sphere in plane, cylindrical, and spherical standing wave fields”, The Journal of the Acoustical Society of America, New York, NY, US, (Mar. 1, 1985), vol. 77, No. 3, pp. 928-945, XP055389249.
M. Toda, New Type of Matching Layer for Air-Coupled Ultrasonic Transducers, IEEE Transactions on Ultrasonics, Ferroelecthcs, and Frequency Control, vol. 49, No. 7, Jul. 2002 (8 pages).
Mahdi Rad et al., Feature Mapping for Learning Fast and Accurate 3D Pose Inference from Synthetic Images, Mar. 26, 2018, pp. 1-14.
Marco A B Andrade et al, “Matrix method for acoustic levitation simulation”, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, IEEE, US, (Aug. 1, 2011), vol. 58, No. 8, ISSN 0885-3010, pp. 1674-1683.
Mariana von Mohr, The soothing function of touch: affective touch reduces feelings of social exclusion, Scientific Reports, 7: 13516, Oct. 18, 2017.
Marin, About LibHand, LibHand—A Hand Articulation Library, www.libhand.org/index.html, Mar. 26, 2020, pp. 1-2; www.libhand.org/download.html, 1 page; www.libhand.org/examples.html, pp. 1-2.
Markus Oberweger et al., DeepPrior++: Improving Fast and Accurate 3D Hand Pose Estimation, Aug. 28, 2017, pp. 1-10.
Markus Oberweger et al., Hands Deep in Deep Learning for Hand Pose Estimation, Dec. 2, 2016, pp. 1-10.
Marshall, M ., Carter, T., Alexander, J., & Subramanian, S. (2012). Ultratangibles: creating movable tangible objects on interactive tables. In Proceedings of the 2012 ACM annual conference on Human Factors in Computing Systems, (pp. 2185-2188).
Marzo et al., Holographic acoustic elements for manipulation of levitated objects, Nature Communications DOI: I0.1038/ncomms9661 (2015) (7 pages).
Meijster, A., et al., “A General Algorithm for Computing Distance Transforms in Linear Time,” Mathematical Morphology and its Applications to Image and Signal Processing, 2002, pp. 331-340.
Mingzhu Lu et al. (2006) Design and experiment of 256-element ultrasound phased array for noninvasive focused ultrasound surgery, Ultrasonics, vol. 44, Supplement, Dec. 22, 2006, pp. e325-e330.
Mitsuru Nakajima, Remotely Displaying Cooling Sensation via Ultrasound-Driven Air Flow, Haptics Symposium 2018, San Francisco, USA p. 340.
Mohamed Yacine Tsalamlal, Affective Communication through Air Jet Stimulation: Evidence from Event-Related Potentials, International Journal of Human-Computer Interaction 2018.
Mohamed Yacine Tsalamlal, Non-Intrusive Haptic Interfaces: State-of-the Art Survey, HAID 2013, LNCS 7989, pp. 1-9, 2013.
Mueller, GANerated Hands for Real-Time 3D Hand Tracking from Monocular RGB, Eye in-Painting with Exemplar Generative Adverserial Networks, pp. 49-59 (Jun. 1, 2018).
Nina Gaissert, Christian Wallraven, and Heinrich H. Bulthoff, “Visual and Haptic Perceptual Spaces Show High Similarity in Humans”, published to Journal of Vision in 2010, available at http://www.journalofvision.org/content/10/11/2 and retrieved on Apr. 22, 2020 ( Year: 2010), 20 pages.
Notice of Allowance dated Apr. 20, 2021 for U.S. Appl. No. 16/563,608 (pp. 1-5).
Notice of Allowance dated Apr. 22, 2020 for U.S. Appl. No. 15/671,107 (pp. 1-5).
Notice of Allowance dated Dec. 19, 2018 for U.S. Appl. No. 15/665,629 (pp. 1-9).
Notice of Allowance dated Dec. 21, 2018 for U.S. Appl. No. 15/983,864 (pp. 1-7).
Notice of Allowance dated Feb. 10, 2020, for U.S. Appl. No. 16/160,862 (pp. 1-9).
Notice of Allowance dated Feb. 7, 2019 for U.S. Appl. No. 15/851,214 (pp. 1-7).
Notice of Allowance dated Jul. 22, 2021 for U.S. Appl. No. 16/600,500 (pp. 1-9).
Notice of Allowance dated Jul. 31, 2019 for U.S. Appl. No. 15/851,214 (pp. 1-9).
Notice of Allowance dated Jul. 31, 2019 for U.S. Appl. No. 16/296,127 (pp. 1-9).
Notice of Allowance dated Jun. 10, 2021 for U.S. Appl. No. 17/092,333 (pp. 1-9).
Notice of Allowance dated Jun. 17, 2020 for U.S. Appl. No. 15/210,661 (pp. 1-9).
Notice of Allowance dated Jun. 25, 2021 for U.S. Appl. No. 15/396,851 (pp. 1-10).
Notice of Allowance dated May 30, 2019 for U.S. Appl. No. 15/966,213 (pp. 1-9).
Notice of Allowance dated Nov. 5, 2021 for U.S. Appl. No. 16/899,720 (pp. 1-9).
Notice of Allowance dated Oct. 1, 2020 for U.S. Appl. No. 15/897,804 (pp. 1-9).
Notice of Allowance dated Oct. 16, 2020 for U.S. Appl. No. 16/159,695 (pp. 1-7).
Notice of Allowance dated Oct. 30, 2020 for U.S. Appl. No. 15/839,184 (pp. 1-9).
Notice of Allowance dated Oct. 6, 2020 for U.S. Appl. No. 16/699,629 (pp. 1-8).
Notice of Allowance dated Sep. 30, 2020 for U.S. Appl. No. 16/401,148 (pp. 1-10).
Notice of Allowance in U.S. Appl. No. 15/210,661 dated Jun. 17, 2020 (22 pages).
Obrist et al., Emotions Mediated Through Mid-Air Haptics, CHI 2015, Apr. 18-23, 2015, Seoul, Republic of Korea. (10 pages).
Obrist et al., Talking about Tactile Experiences, CHI 2013, Apr. 27-May 2, 2013 (10 pages).
Office Action (Final Rejection) dated Mar. 14, 2022 for U.S. Appl. No. 16/564,016 (pp. 1-12).
Office Action (Non-Final Rejection) dated Jan. 21, 2022 for U.S. Appl. No. 17/068,834 (pp. 1-12).
Office Action (Non-Final Rejection) dated Jan. 24, 2022 for U.S. Appl. No. 16/228,767 (pp. 1-22).
Office Action (Non-Final Rejection) dated Mar. 4, 2022 for U.S. Appl. No. 16/404,660 (pp. 1-5).
Office Action (Non-Final Rejection) dated Mar. 15, 2022 for U.S. Appl. No. 16/144,474 (pp. 1-13).
Office Action (Non-Final Rejection) dated Dec. 20, 2021 for U.S. Appl. No. 17/195,795 (pp. 1-7).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Jan. 18, 2022 for U.S. Appl. No. 16/899,720 (pp. 1-2).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Feb. 11, 2022 for U.S. Appl. No. 16/228,760 (pp. 1-8).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Feb. 28, 2022 for U.S. Appl. No. 17/068,825 (pp. 1-7).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Mar. 7, 2022 for U.S. Appl. No. 16/600,496 (pp. 1-5).
Office Action (Notice of Allowance and Fees Due (PTOL-85)) dated Dec. 14, 2021 for U.S. Appl. No. 17/170,841 (pp. 1-8).
Office Action dated Apr. 8, 2020, for U.S. Appl. No. 16/198,959 (pp. 1-17).
Office Action dated Apr. 16, 2020 for U.S. Appl. No. 15/839,184 (pp. 1-8).
Office Action dated Apr. 17, 2020 for U.S. Appl. No. 16/401,148 (pp. 1-15).
Office Action dated Apr. 18, 2019 for U.S. Appl. No. 16/296,127 (pp. 1-6).
Office Action dated Apr. 28, 2020 for U.S. Appl. No. 15/396,851 (pp. 1-12).
Office Action dated Apr. 29, 2020 for U.S. Appl. No. 16/374,301 (pp. 1-18).
Office Action dated Apr. 4, 2019 for U.S. Appl. No. 15/897,804 (pp. 1-10).
Office Action dated Aug. 10, 2021 for U.S. Appl. No. 16/564,016 (pp. 1-14).
Office Action dated Aug. 19, 2021 for U.S. Appl. No. 17/170,841 (pp. 1-9).
Office Action dated Aug. 22, 2019 for U.S. Appl. No. 16/160,862 (pp. 1-5).
Office Action dated Aug. 9, 2021 for U.S. Appl. No. 17/068,825 (pp. 1-9).
Office Action dated Dec. 11, 2019 for U.S. Appl. No. 15/959,266 (pp. 1-15).
Office Action dated Dec. 7, 2020 for U.S. Appl. No. 16/563,608 (pp. 1-8).
Office Action dated Feb. 20, 2019 for U.S. Appl. No. 15/623,516 (pp. 1-8).
Office Action dated Feb. 25, 2020 for U.S. Appl. No. 15/960,113 (pp. 1-7).
Office Action dated Feb. 7, 2020 for U.S. Appl. No. 16/159,695 (pp. 1-8).
Office Action dated Jan. 10, 2020 for U.S. Appl. No. 16/228,767 (pp. 1-6).
Office Action dated Jan. 29, 2020 for U.S. Appl. No. 16/198,959 (p. 1-6).
Office Action dated Jul. 10, 2019 for U.S. Appl. No. 15/210,661 (pp. 1-12).
Office Action dated Jul. 26, 2019 for U.S. Appl. No. 16/159,695 (pp. 1-8).
Office Action dated Jul. 9, 2020 for U.S. Appl. No. 16/228,760 (pp. 1-17).
Office Action dated Jun. 19, 2020 for U.S. Appl. No. 16/699,629 (pp. 1-12).
Office Action dated Jun. 25, 2020 for U.S. Appl. No. 16/228,767 (pp. 1-27).
Office Action dated Jun. 25, 2021 for U.S. Appl. No. 16/899,720 (pp. 1-5).
Office Action dated Mar. 11, 2021 for U.S. Appl. No. 16/228,767 (pp. 1-23).
Office Action dated Mar. 20, 2020 for U.S. Appl. No. 15/210,661 (pp. 1-10).
Office Action dated Mar. 31, 2021 for U.S. Appl. No. 16/228,760 (pp. 1-21).
Office Action dated May 13, 2021 for U.S. Appl. No. 16/600,500 (pp. 1-9).
Office Action dated May 14, 2021 for U.S. Appl. No. 16/198,959 (pp. 1-6).
Office Action dated May 16, 2019 for U.S. Appl. No. 15/396,851 (pp. 1-7).
Office Action dated May 18, 2020 for U.S. Appl. No. 15/960,113 (pp. 1-21).
Office Action dated Oct. 17, 2019 for U.S. Appl. No. 15/897,804 (pp. 1-10).
Office Action dated Oct. 29, 2021 for U.S. Appl. No. 16/198,959 (pp. 1-7).
Office Action dated Oct. 31, 2019 for U.S. Appl. No. 15/671,107 (pp. 1-6).
Office Action dated Oct. 7, 2019 for U.S. Appl. No. 15/396,851 (pp. 1-9).
Office Action dated Sep. 16, 2021 for U.S. Appl. No. 16/600,496 (pp. 1-8).
Office Action dated Sep. 18, 2020 for U.S. Appl. No. 15/396,851 (pp. 1-14).
Office Action dated Sep. 21, 2020 for U.S. Appl. No. 16/198,959 (pp. 1-17).
Office Action dated Sep. 24, 2021 for U.S. Appl. No. 17/080,840 (pp. 1-9).
OGRECave/ogre—GitHub: ogre/Samples/Media/materials at 7de80a7483f20b50f2b10d7ac6de9d9c6c87d364, Mar. 26, 2020, 1 page.
Optimal regularisation for acoustic source reconstruction by inverse methods, Y. Kim, P.A. Nelson, Institute of Sound and Vibration Research, University of Southampton, Southampton, SO17 1BJ, UK Received Feb. 25, 2003; 25 pages.
Oscar Martínez-Graullera et al, “2D array design based on Fermat spiral for ultrasound imaging”, Ultrasonics, (Feb. 1, 2010), vol. 50, No. 2, ISSN 0041-624X, pp. 280-289, XP055210119.
Partial International Search Report for Application No. PCT/GB2018/053735, dated Apr. 12, 2019, 14 pages.
Partial ISR for Application No. PCT/GB2020/050013 dated May 19, 2020 (16 pages).
PCT Partial International Search Report for Application No. PCT/GB2018/053404 dated Feb. 25, 2019, 13 pages.
Péter Tamás Kovács et al, “Tangible Holographic 3D Objects with Virtual Touch”, Interactive Tabletops & Surfaces, ACM, 2 Penn Plaza, Suite 701 New York NY 10121-0701 USA, (Nov. 15, 2015), ISBN 978-1-4503-3899-8, pp. 319-324.
Phys.org, Touchable Hologram Becomes Reality, Aug. 6, 2009, by Lisa Zyga (2 pages).
Pompei, F.J. (2002), “Sound from Ultrasound: The Parametric Array as an Audible Sound Source”, Massachusetts Institute of Technology (132 pages).
Rocchesso et al., Accessing and Selecting Menu Items by In-Air Touch, ACM CHItaly'19, Sep. 23-25, 2019, Padova, Italy (9 pages).
Rochelle Ackerley, Human C-Tactile Afferents Are Tuned to the Temperature of a Skin-Stroking Caress, J. Neurosci., Feb. 19, 2014, 34(8):2879-2883.
Ryoko Takahashi, Tactile Stimulation by Repetitive Lateral Movement of Midair Ultrasound Focus, Journal of Latex Class Files, vol. 14, No. 8, Aug. 2015.
Schmidt, Ralph, “Multiple Emitter Location and Signal Parameter Estimation” IEEE Transactions of Antenna and Propagation, vol. AP-34, No. 3, Mar. 1986, pp. 276-280.
Sean Gustafson et al., “Imaginary Phone”, Proceedings of the 24th Annual ACM Symposium on User Interface Software and Techology: Oct. 16-19, 2011, Santa Barbara, CA, USA, ACM, New York, NY, Oct. 16, 2011, pp. 283-292, XP058006125, DOI: 10.1145/2047196.2047233, ISBN: 978-1-4503-0716-1.
Search report and Written Opinion of ISA for PCT/GB2015/050417 dated Jul. 8, 2016 (20 pages).
Search report and Written Opinion of ISA for PCT/GB2015/050421 dated Jul. 8, 2016 (15 pages).
Search report and Written Opinion of ISA for PCT/GB2017/050012 dated Jun. 8, 2017. (18 pages).
Search Report by EPO for EP 17748466 dated Jan. 13, 2021 (16 pages).
Search Report for GB1308274.8 dated Nov. 11, 2013. (2 pages).
Search Report for GB1415923.0 dated Mar. 11, 2015. (1 page).
Search Report for PCT/GB/2017/053729 dated Mar. 15, 2018 (16 pages).
Search Report for PCT/GB/2017/053880 dated Mar. 21, 2018. (13 pages).
Search report for PCT/GB2014/051319 dated Dec. 8, 2014 (4 pages).
Search report for PCT/GB2015/052507 dated Mar. 11, 2020 (19 pages).
Search report for PCT/GB2015/052578 dated Oct. 26, 2015 (12 pages).
Search report for PCT/GB2015/052916 dated Feb. 26, 2020 (18 pages).
Search Report for PCT/GB2017/052332 dated Oct. 10, 2017 (12 pages).
Search report for PCT/GB2018/051061 dated Sep. 26, 2018 (17 pages).
Search report for PCT/US2018/028966 dated Jul. 13, 2018 (43 pages).
Sergey Ioffe et al., Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariat Shift, Mar. 2, 2015, pp. 1-11.
Seungryul, Pushing the Envelope for RGB-based Dense 3D Hand Pose Estimation for RGB-based Desne 3D Hand Pose Estimation via Neural Rendering, arXiv:1904.04196v2 [cs.CV] Apr. 9, 2019 (5 pages).
Shakeri, G., Williamson, J. H. and Brewster, S. (2018) May the Force Be with You: Ultrasound Haptic Feedback for Mid-Air Gesture Interaction in Cars. In: 10th International ACM Conference on Automotive User Interfaces and Interactive Vehicular Applications (AutomotiveUI 2018) (11 pages).
Shanxin Yuan et al., BigHand2.2M Bechmark: Hand Pose Dataset and State of the Art Analysis, Dec. 9, 2017, pp. 1-9.
Shome Subhra Das, Detectioin of Self Intersection in Synthetic Hand Pose Generators, 2017 Fifteenth IAPR International Conference on Machine Vision Applications (MVA), Nagoya University, Nagoya, Japan, May 8-12, 2017, pp. 354-357.
Sixth Sense webpage, http://www.pranavmistry.com/projects/sixthsense/ Accessed Nov. 30, 2018, 7 pages.
Stan Melax et al., Dynamics Based 3D Skeletal Hand Tracking, May 22, 2017, pp. 1-8.
Stanley J. Bolanowski, Hairy Skin: Psychophysical Channels and Their Physiological Substrates, Somatosensory and Motor Research, vol. 11. No. 3, 1994, pp. 279-290.
Stefan G. Lechner, Hairy Sensation, Physiology 28: 142-150, 2013.
Steve Guest et al., “Audiotactile interactions in roughness perception”, Exp. Brain Res (2002) 146:161-171, DOI 10.1007/s00221-002-1164-z, Received: Feb. 9, 2002/Accepted: May 16, 2002/ Published online: Jul. 26, 2002, Springer-Verlag 2002, (11 pages).
Supplemental Notice of Allowability dated Jul. 28, 2021 for U.S. Appl. No. 16/563,608 (pp. 1-2).
Supplemental Notice of Allowability dated Jul. 28, 2021 for U.S. Appl. No. 17/092,333 (pp. 1-2).
Sylvia Gebhardt, Ultrasonic Transducer Arrays for Particle Manipulation (date unknown) (2 pages).
Takaaki Kamigaki, Noncontact Thermal and Vibrotactile Display Using Focused Airborne Ultrasound, EuroHaptics 2020, LNCS 12272, pp. 271-278, 2020.
Takahashi Dean: “Ultrahaptics shows off sense of touch in virtual reality”, Dec. 10, 2016 (Dec. 10, 2016), XP055556416, Retrieved from the Internet: URL: https://venturebeat.com/2016/12/10/ultrahaptics-shows-off-sense-of-touch-in-virtual-reality/ [retrieved on Feb. 13, 2019] 4 pages.
Takahashi, M. et al., Large Aperture Airborne Ultrasound Tactile Display Using Distributed Array Units, SICE Annual Conference 2010 p. 359-62.
Takayuki et al., “Noncontact Tactile Display Based on Radiation Pressure of Airborne Ultrasound” IEEE Transactions on Haptics vol. 3, No. 3, p. 165 (2010).
Teixeira, et al., “A brief introduction to Microsoft's Kinect Sensor,” Kinect, 26 pages, retrieved Nov. 2018.
Toby Sharp et al., Accurate, Robust, and Flexible Real-time Hand Tracking, CHI '15, Apr. 18-23, 2015, Seoul, Republic of Korea, ACM 978-1-4503-3145-6/15/04, pp. 1-10.
Tom Carter et al, “UltraHaptics: Multi-Point Mid-Air Haptic Feedback for Touch Surfaces”, Proceedings of the 26th Annual ACM Symposium on User Interface Software and Technology, UIST '13, New York, New York, USA, (Jan. 1, 2013), ISBN 978-1-45-032268-3, pp. 505-514.
Tom Nelligan and Dan Kass, Intro to Ultrasonic Phased Array (date unknown) (8 pages).
Tomoo Kamakura, Acoustic streaming induced in focused Gaussian beams, J. Acoust. Soc. Am. 97 (5), Pt. 1, May 1995 p. 2740.
Uta Sailer, How Sensory and Affective Attributes Describe Touch Targeting C-Tactile Fibers, Experimental Psychology (2020), 67(4), 224-236.
Vincent Lepetit et al., Model Based Augmentation and Testing of an Annotated Hand Pose Dataset, ResearchGate, https://www.researchgate.net/publication/307910344, Sep. 2016, 13 pages.
Wang et al., Device-Free Gesture Tracking Using Acoustic Signals, ACM MobiCom '16, pp. 82-94 (13 pages).
Wilson et al., Perception of Ultrasonic Haptic Feedback on the Hand: Localisation and Apparent Motion, CHI 2014, Apr. 26-May 1, 2014, Toronto, Ontario, Canada. (10 pages).
Wooh et al., “Optimum beam steering of linear phased arays,” Wave Motion 29 (1999) pp. 245-265, 21 pages.
Xin Cheng et al, “Computation of the acoustic radiation force on a sphere based on the 3-D FDTD method”, Piezoelectricity, Acoustic Waves and Device Applications (SPAWDA), 2010 Symposium on, IEEE, (Dec. 10, 2010), ISBN 978-1-4244-9822-2, pp. 236-239.
Xu Hongyi et al, “6-DoF Haptic Rendering Using Continuous Collision Detection between Points and Signed Distance Fields”, IEEE Transactions on Haptics, IEEE, USA, vol. 10, No. 2, ISSN 1939-1412, (Sep. 27, 2016), pp. 151-161, (Jun. 16, 2017).
Yang Ling et al, “Phase-coded approach for controllable generation of acoustical vortices”, Journal of Applied Physics, American Institute of Physics, US, vol. 113, No. 15, ISSN 0021-8979, (Apr. 21, 2013), pp. 154904-154904.
Yarin Gal et al., Dropout as a Bayesian Approximation: Representing Model Uncertainty in Deep Learning, Oct. 4, 2016, pp. 1-12, Proceedings of the 33rd International Conference on Machine Learning, New York, NY, USA, 2016, JMLR: W&CP vol. 48.
Yaroslav Ganin et al., Domain-Adversarial Training of Neural Networks, Journal of Machine Learning Research 17 (2016) 1-35, submitted May 2015; published Apr. 2016.
Yaroslav Ganin et al., Unsupervised Domain Adaptataion by Backpropagation, Skolkovo Institute of Science and Technology (Skoltech), Moscow Region, Russia, Proceedings of the 32nd International Conference on Machine Learning, Lille, France, 2015, JMLR: W&CP vol. 37, copyright 2015 by the author(s), 11 pages.
Yoshino, K. and Shinoda, H. (2013), “Visio Acoustic Screen for Contactless Touch Interface with Tactile Sensation”, University of Tokyo (5 pages).
Zeng, Wejun, “Microsoft Kinect Sensor and Its Effect,” IEEE Multimedia, Apr.-Jun. 2012, 7 pages.
Related Publications (1)
Number Date Country
20220198892 A1 Jun 2022 US
Provisional Applications (6)
Number Date Country
62275002 Jan 2016 US
62268573 Dec 2015 US
62193125 Jul 2015 US
62193194 Jul 2015 US
62141935 Apr 2015 US
62118543 Feb 2015 US
Continuations (3)
Number Date Country
Parent 16899720 Jun 2020 US
Child 17692852 US
Parent 16160862 Oct 2018 US
Child 16899720 US
Parent 15047791 Feb 2016 US
Child 16160862 US