Datasets:

shangdatalab-ucsd

/

PatentAP

like 2

The semiconductor device of claim 20 , wherein the field effect transistor is an n-channel field effect transistor with a vertical current flow between the source region and a drain region, the source region associated with a first surface of the semiconductor body and the drain region associated with a second surface, opposite of the first surface, of the semiconductor body.

Utility

["257", "051000"]

2018-01

2018-06

A semiconductor device may include a semiconductor body of silicon carbide (SiC) and a field effect transistor. The field effect transistor has the semiconductor body that includes a drift region. A polycrystalline silicon layer is formed over or on the semiconductor body, wherein the polycrystalline silicon layer has an average particle size in the range of 10 nm to 5 μm, and includes a source region and a body region. Furthermore, the field effect transistor includes a layer adjacent to the body region gate structure.

['15858406', '11399452', '11952447', '15275184', '15291168']

none

(15880716, 36)

test

The semiconductor device of claim 32 , further comprising a degeneration region formed between the conduction region and the semiconductor body.

Utility

["257", "051000"]

2018-01

2018-06

A semiconductor device may include a semiconductor body of silicon carbide (SiC) and a field effect transistor. The field effect transistor has the semiconductor body that includes a drift region. A polycrystalline silicon layer is formed over or on the semiconductor body, wherein the polycrystalline silicon layer has an average particle size in the range of 10 nm to 5 μm, and includes a source region and a body region. Furthermore, the field effect transistor includes a layer adjacent to the body region gate structure.

['15858406', '11399452', '11952447', '15275184', '15291168']

open

(15880716, 35)

test

The semiconductor device of claim 32 , further comprising a charge accumulation region dielectrically separated from the semiconductor body, the charge accumulation region configured to provide a carrier accumulation.

Utility

["257", "051000"]

2018-01

2018-06

A semiconductor device may include a semiconductor body of silicon carbide (SiC) and a field effect transistor. The field effect transistor has the semiconductor body that includes a drift region. A polycrystalline silicon layer is formed over or on the semiconductor body, wherein the polycrystalline silicon layer has an average particle size in the range of 10 nm to 5 μm, and includes a source region and a body region. Furthermore, the field effect transistor includes a layer adjacent to the body region gate structure.

['15858406', '11399452', '11952447', '15275184', '15291168']

open

(15880716, 34)

test

An isolated, synthetic, or recombinant disulfide-rich peptide, wherein the peptide comprises, consists of, or consists essentially of, a sequence of Formula (I):\n X-L-Y\u2003\u2003(I) wherein X and Y each represent a peptide sequence having an inhibitor cystine knot (ICK) fold and L is a linker, and wherein said peptide is preferably capable of specifically binding to acid sensing ion channel subtype 1a (ASIC1a).

Utility

["514", "017700"]

2018-01

2018-07

The invention relates to disulfide-rich peptides derived from spider venom and their use, particularly as neuroprotective agents. The invention also relates to nucleic acid molecules encoding the peptides as well as constructs and host cells comprising those nucleic acid molecules.

['16312020', '12670099', '14116862', '09852378', '13812457']

none

(15745432, 99)

test

The battery energy storage system of claim 1 , wherein the plurality of battery packs are vertically stacked.

Utility

["320", "128000"]

2018-01

2018-08

Embodiments disclosed herein relate to a battery energy storage system (BESS) that can be used to store energy that is produced by conventional sources (e.g., coal, gas, nuclear) as well as renewable sources (e.g., wind, solar), and provide the stored energy on-demand.

['14932688', '15845598', '15389188', '14962491', '14819779']

none

(15882713, 8)

test

A method for processing a request of a user equipment (UE) performed by a Mobility Management Entity (MME) existing in a Visited Public Land Mobile Network (V-PLMN), comprising:\n receiving a Packet Data Network (PDN) connection request message for an emergency service from the UE; when the UE is being roamed to the V-PLMN, acquiring subscriber information of the UE; delivering the acquired subscriber information to a Home Subscriber Server (HSS) existing in the V-PLMN; and transmitting a PDN connection accept message to the UE, wherein the PDN connection accept message includes an indication indicating that a Network to Network Interface (NNI) does not exist between the V-PLMN and a Home PLMN (H-PLMN).

Utility

["455", "404100"]

2018-01

2018-07

An embodiment of the present description provides, in a situation in which, when a user equipment (UE) is roaming in a visited network, i.e. V-PLMN, the roaming is processed by means of a home routed (HR) mode and is successfully registered to H-PLMN IMS and a service is received, a method for performing authentication/registration of a UE, which is to receive an emergency service, if IMS-NNI does not exist between H-PLMN and V-PLMN.

['15768723', '15752990', '15755725', '15244120', '15300083']

open

(15747853, 4)

test

The method of claim 4 , wherein the subscriber information is acquired from a HSS existing in the H-PLMN.

Utility

["455", "404100"]

2018-01

2018-07

An embodiment of the present description provides, in a situation in which, when a user equipment (UE) is roaming in a visited network, i.e. V-PLMN, the roaming is processed by means of a home routed (HR) mode and is successfully registered to H-PLMN IMS and a service is received, a method for performing authentication/registration of a UE, which is to receive an emergency service, if IMS-NNI does not exist between H-PLMN and V-PLMN.

['15768723', '15752990', '15755725', '15244120', '15300083']

none

(15747853, 6)

test

The method according to claim 8 , wherein\n the method further comprises: providing the whole cabinet server system with a Coolant Distribution Unit CDU to provide low-temperature water for the water-cooling coil pipe, obtain water stream that is drained out of each water-cooling plate and has absorbed heat, and discharge heat into ambient environment after treatment.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 9)

test

The method according to claim 6 , wherein\n the method further comprises: using the water-cooling coil pipe to provide low-temperature water for the water-cooling plate.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 8)

test

The method according to claim 6 , wherein\n the designated heat-generating element comprises a Central Processing Unit CPU and Graphics Processing Unit GPU; the low-temperature water comprises cooling water and chilled water.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 7)

test

A heat-dissipating method of a whole cabinet server system, wherein the method comprises:\n disposing a water-cooling plate on a designated heat-generating element in each server of the whole cabinet server system so that low-temperature water in the water-cooling plate is used to take away heat generated by the designated heat-generating elements; providing a water-cooling coil pipe for the whole cabinet server system, and providing a fan for the whole cabinet server system, to produce low-temperature air stream, the air stream flowing through the whole cabinet server system and the water-cooling coil pipe in turn, the water-cooling coil pipe cooling the air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 6)

test

The heat-dissipating system according to claim 4 , wherein\n the heat-dissipating system further comprises an ingress water manifold and a return water manifold; the ingress water manifold is configured to convey the low-temperature water obtained from the water-cooling coil pipe to each water-cooling plate respectively; the return water manifold is configured to return water stream that is drained out of each water-cooling plate and has absorbed heat, to the CDU.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 5)

test

The heat-dissipating system according to claim 3 , wherein\n the heat-dissipating system further comprises a Coolant Distribution Unit CDU; the CDU is configured to provide low-temperature water for the water-cooling coil pipe, obtain water stream that is drained out of each water-cooling plate and has absorbed heat, and discharge heat into ambient environment after treatment.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 4)

test

The heat-dissipating system according to claim 1 , wherein\n the water-cooling coil pipe is further configured to provide low-temperature water for the water-cooling plate.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 3)

test

The heat-dissipating system according to claim 1 , wherein\n the designated heat-generating element comprises a Central Processing Unit CPU and Graphics Processing Unit GPU; the low-temperature water comprises cooling water and chilled water.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 2)

test

A heat-dissipating system of a whole cabinet server system, wherein the system comprises:\n a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on a designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 1)

test

The method according to claim 2 ,\n wherein the cross-sectional shape of the cutting edge of the cutting blade is a round shape; and in the cutting step, the workpiece is cut while the center of the cutting blade in thicknesswise directions thereof positionally deviates from the cracks in the direction perpendicular to the direction along which the streets extend.

Utility

["438", "463000"]

2018-01

2018-07

Disclosed herein is a method of processing a workpiece having a plurality of streets provided on a face side thereof, the method including: a laser beam applying step of applying a laser beam having a wavelength that is transmittable through the workpiece along the streets while focusing the laser beam at a point within the workpiece, thereby forming modified layers in the workpiece along the streets and cracks extending from the modified layers to the face side; and a cutting step of, thereafter, cutting the workpiece from a reverse side thereof along the streets while supplying the workpiece with a cutting fluid, thereby removing the modified layers from the workpiece.

['10914152', '12110839', '14397040', '13871125', '11269548']

none

(15874550, 4)

test

The method according to claim 9 , wherein\n the method further comprises: providing the whole cabinet server system with an ingress water manifold to convey the low-temperature water obtained from the water-cooling coil pipe to each water-cooling plate respectively; providing the whole cabinet server system with a return water manifold to return water stream that is drained out of each water-cooling plate and has absorbed heat, to the CDU.

Utility

["361", "679520"]

2018-01

2018-07

The present disclosure provides a heat-dissipating system and method of a whole cabinet server system. The system comprises: a whole cabinet server system, a water-cooling plate, a water-cooling coil pipe and a fan; the water-cooling plate is disposed on each designated heat-generating element in each server of the whole cabinet server system; the water-cooling plate is configured to use low-temperature water therein to take away heat generated by the designated heat-generating element; the fan is configured to produce low-temperature air stream which flows through the whole cabinet server system and the water-cooling coil pipe in turn; the water-cooling coil pipe is configured to cool air stream that have absorbed the heat of the whole cabinet server system as low-temperature air stream. The solutions of the present disclosure can be applied to improve the heat-dissipating efficiency and reduce the costs of implementation.

['15547350', '13110384', '15526313', '10786307', '13184948']

none

(15860590, 10)

test

The method according to claim 2 ,\n wherein the cross-sectional shape of the cutting edge of the cutting blade is a centrally recessed shape where the center of the cutting edge is recessed between projecting end ridges or a one-sided unsymmetrical slanted shape where an essentially flat surface is oblique from one side to another; and in the cutting step, the workpiece is cut while the center of the cutting blade in thicknesswise directions thereof is positionally aligned with the cracks.

Utility

["438", "463000"]

2018-01

2018-07

Disclosed herein is a method of processing a workpiece having a plurality of streets provided on a face side thereof, the method including: a laser beam applying step of applying a laser beam having a wavelength that is transmittable through the workpiece along the streets while focusing the laser beam at a point within the workpiece, thereby forming modified layers in the workpiece along the streets and cracks extending from the modified layers to the face side; and a cutting step of, thereafter, cutting the workpiece from a reverse side thereof along the streets while supplying the workpiece with a cutting fluid, thereby removing the modified layers from the workpiece.

['10914152', '12110839', '14397040', '13871125', '11269548']

none

(15874550, 3)

test

A method of processing a workpiece having a plurality of streets provided on a face side thereof, the method comprising:\n a laser beam applying step of applying a laser beam having a wavelength that is transmittable through the workpiece to a reverse side of the workpiece along the streets while focusing the laser beam at a point within the workpiece, thereby forming modified layers in the workpiece along the streets and cracks extending from the modified layers to the face side; and a cutting step of cutting the workpiece from the reverse side thereof along the streets while supplying the workpiece with a cutting fluid, thereby removing the modified layers from the workpiece, after performing said laser beam applying step.

Utility

["438", "463000"]

2018-01

2018-07

Disclosed herein is a method of processing a workpiece having a plurality of streets provided on a face side thereof, the method including: a laser beam applying step of applying a laser beam having a wavelength that is transmittable through the workpiece along the streets while focusing the laser beam at a point within the workpiece, thereby forming modified layers in the workpiece along the streets and cracks extending from the modified layers to the face side; and a cutting step of, thereafter, cutting the workpiece from a reverse side thereof along the streets while supplying the workpiece with a cutting fluid, thereby removing the modified layers from the workpiece.

['10914152', '12110839', '14397040', '13871125', '11269548']

open

(15874550, 1)

test

The resilient bearing as claim in claim 18 , wherein the elasticity of the elastic material in the plurality of limbs is lower at the distal connection points and the central connection point and higher between the distal connection points and the central connection point.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 19)

test

The resilient bearing as claimed in claim 10 , wherein the functional property is the elasticity of the elastic material.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 18)

test

The resilient bearing as claim in claim 16 , wherein the hardness of the elastic material in the plurality of limbs is higher at the distal connection points and the central connection point and lower between the distal connection points and the central connection point.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 17)

test

The resilient bearing as claimed in claim 10 , wherein the functional property is the hardness of the elastic material.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 16)

test

The resilient bearing as claimed in claim 10 , wherein the elastic material is a rubber.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 15)

test

The resilient bearing as claimed in claim 13 , wherein the vertical support is a supporting column, which supports the weight of either the first structure or the second structure.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 14)

test

The resilient bearing as claimed in claim 10 , wherein the resilient bearing includes an elongate vertical support, comprising:\n a. a first end connected to the central connection point; and b. a second end adjacent to, but able to move relative to, the second structure.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

open

(15879155, 13)

test

The resilient bearing as claimed in claim 10 , wherein there are between two and four limbs.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 12)

test

The resilient bearing as claimed in claim 10 , wherein the plurality of limbs are evenly distributed around the central connection point.

Utility

["052", "167800"]

2018-01

2018-05

A resilient bearing to be positioned between a first structure and a second structure including a central connection point for connecting the resilient bearing to the first structure and a plurality of limbs extending outwardly from the central connection point to distal connection points. The resilient bearing may be formed from a single piece of elastic material adapted to dampen forces due to environmental events. A functional property of the elastic material may vary along at least some of the plurality of limbs. The angle between each of at least some of the plurality of limbs and the second structure may be between 20 and 70 degrees.

['15035164', '13445638', '11731425', '13212176', '12074930']

none

(15879155, 11)

test

The method according to claim 1 ,\n wherein, in the cutting step, the workpiece is cut while a lowermost position on the cross-sectional shape of a cutting edge of the cutting blade positionally deviates from the cracks in a direction perpendicular to a direction along which the streets extend, thereby preventing the cutting fluid and cut chips from entering the cracks.

Utility

["438", "463000"]

2018-01

2018-07

Disclosed herein is a method of processing a workpiece having a plurality of streets provided on a face side thereof, the method including: a laser beam applying step of applying a laser beam having a wavelength that is transmittable through the workpiece along the streets while focusing the laser beam at a point within the workpiece, thereby forming modified layers in the workpiece along the streets and cracks extending from the modified layers to the face side; and a cutting step of, thereafter, cutting the workpiece from a reverse side thereof along the streets while supplying the workpiece with a cutting fluid, thereby removing the modified layers from the workpiece.

['10914152', '12110839', '14397040', '13871125', '11269548']

none

(15874550, 2)

test

A method comprising:\n a virtual machine executing a body of code, wherein said virtual machine is configured to dynamically create attributes of objects referenced by said body of code and hidden classes used to store attributes of said objects referenced by said body code, wherein said virtual machine executing said body of code includes:\n determining whether a particular hidden class satisfies one or more encoding criteria for generating encoding machine code for encoding one or more particular instances of said hidden class; \n in response to determining that said particular determining satisfies said one or more encoding criteria:\n generating said particular encoding machine code to encode said one or more particular instances; \n executing said particular encoding machine code to encode a particular instance of said one or more particular instances; \n \n wherein the method is performed by one or more computing devices.

Utility

["717", "106000"]

2018-01

2018-08

Computer-implemented techniques described herein provide fast access to structured, semi-structured, and unstructured data using a virtual machine that provides support for dynamic code generation. In an embodiment, a virtual machine allows for the efficient encoding of data objects into hierarchically marked up data. A virtual machine is configured to dynamically create attributes of objects referenced by a body of code and hidden classes used to store attributes of objects referenced by the body of code. The virtual machine will determine whether a hidden class of an object satisfies one or more encoding criteria for encoding instances of objects with the hidden class. Encoding machine code is generated and executed to encode instances of objects with the hidden class. In another embodiment, direct structure decoding enables the generation of efficient machine code that is specialized for accessing only a subset of the input data that is used by an application. A parse operation is received to parse a hierarchical data object and a proxy object is created in a runtime memory space that references the hierarchical data object. It is then determined that the hierarchical data object is syntactically valid, and in response to receiving a request to read a property of the hierarchical data object, a subset of hierarchical data from the hierarchical data object is parsed to materialize a value of the property in the proxy object.

['14699685', '10278728', '14498893', '09573768', '14836680']

open

(15864863, 1)

test

The method of claim 1 , further comprising: generating an intermediate representation based on the attributes of objects referenced by said body of code.

Utility

["717", "106000"]

2018-01

2018-08

Computer-implemented techniques described herein provide fast access to structured, semi-structured, and unstructured data using a virtual machine that provides support for dynamic code generation. In an embodiment, a virtual machine allows for the efficient encoding of data objects into hierarchically marked up data. A virtual machine is configured to dynamically create attributes of objects referenced by a body of code and hidden classes used to store attributes of objects referenced by the body of code. The virtual machine will determine whether a hidden class of an object satisfies one or more encoding criteria for encoding instances of objects with the hidden class. Encoding machine code is generated and executed to encode instances of objects with the hidden class. In another embodiment, direct structure decoding enables the generation of efficient machine code that is specialized for accessing only a subset of the input data that is used by an application. A parse operation is received to parse a hierarchical data object and a proxy object is created in a runtime memory space that references the hierarchical data object. It is then determined that the hierarchical data object is syntactically valid, and in response to receiving a request to read a property of the hierarchical data object, a subset of hierarchical data from the hierarchical data object is parsed to materialize a value of the property in the proxy object.

['14699685', '10278728', '14498893', '09573768', '14836680']

open

(15864863, 2)

test

The method of claim 2 , wherein determining whether a particular hidden class satisfies one or more encoding criteria for generating encoding machine code for encoding one or more particular instances of said hidden class includes determining whether said hidden class matches an expected hidden class mapped to said intermediate representation.

Utility

["717", "106000"]

2018-01

2018-08

Computer-implemented techniques described herein provide fast access to structured, semi-structured, and unstructured data using a virtual machine that provides support for dynamic code generation. In an embodiment, a virtual machine allows for the efficient encoding of data objects into hierarchically marked up data. A virtual machine is configured to dynamically create attributes of objects referenced by a body of code and hidden classes used to store attributes of objects referenced by the body of code. The virtual machine will determine whether a hidden class of an object satisfies one or more encoding criteria for encoding instances of objects with the hidden class. Encoding machine code is generated and executed to encode instances of objects with the hidden class. In another embodiment, direct structure decoding enables the generation of efficient machine code that is specialized for accessing only a subset of the input data that is used by an application. A parse operation is received to parse a hierarchical data object and a proxy object is created in a runtime memory space that references the hierarchical data object. It is then determined that the hierarchical data object is syntactically valid, and in response to receiving a request to read a property of the hierarchical data object, a subset of hierarchical data from the hierarchical data object is parsed to materialize a value of the property in the proxy object.

['14699685', '10278728', '14498893', '09573768', '14836680']

none

(15864863, 3)

test

The apparatus as claimed in claim 7 , wherein the lithographic apparatus is of a scanning type and wherein the algorithm specific to the first height map component is permitted to consider values from a different sized portion of a field than the algorithm specific to the second height map component.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 11)

test

The apparatus as claimed in claim 7 , wherein one or more of the algorithms specific to the different height map components have nonlinearity, while the combination of the control set-points is performed linearly.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 10)

test

The apparatus as claimed in claim 7 , wherein an algorithm specific to the first height map component is less responsive to short-range topographic variations than an algorithm specific to the second height map component.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 9)

test

The apparatus as claimed in claim 7 , wherein, to decompose the height map the data processing apparatus is arranged to calculate the first component of the height map based on an average field topography and to subtract the first component from the height map to obtain the second height map component.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 8)

test

An apparatus comprising a data processing apparatus programmed to at least:\n receive a height map of a substrate that has been subjected to lithographic processing over a plurality of device areas; decompose the height map into a plurality of components, including a first height map component representing topographical variations associated with the device pattern and a second height map component representing other topographical variations; using each of the first and second height map components, calculate control set-points according to a control algorithm specific to each of the first and second height map components; combine the control set-points calculated for the first height map component and the second height map component; and provide set-points to control a positioning system of a lithographic apparatus configured to apply a device pattern at multiple substrate locations to apply the device pattern to the substrate.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

open

(15743661, 7)

test

The method as claimed in claim 1 , wherein the calculating control set-points for at least one of the height map components includes using the height map data to generate additional height map data by extrapolation, and wherein the height map data used for extrapolation excludes the first height map component so that the extrapolated height map data is insensitive to topographical variations associated with the device pattern.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 6)

test

The method as claimed in claim 1 , wherein the lithographic apparatus is of a scanning type and wherein the algorithm specific to the first height map component is permitted to consider values from a different sized portion of a field than an algorithm specific to the second height map component.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 5)

test

The method as claimed in claim 1 , wherein in the calculating control set-points one or more of the algorithms specific to the different height map components have nonlinearity, while the combining of the control set-points is performed linearly.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 4)

test

The method as claimed in claim 1 , wherein in the calculating control set-points an algorithm specific to the first height map component is less responsive to short-range topographic variations than an algorithm specific to the second height map component.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 3)

test

The method as claimed in claim 1 , wherein the decomposing the height map comprises calculating the first component of the height map based on an average field topography and subtracting the first component from the height map to obtain the second height map component.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

none

(15743661, 2)

test

A method of controlling a lithographic apparatus to manufacture a plurality of devices on a substrate, the method comprising:\n obtaining a height map representing a topographical variation across the substrate; and using the height map to control a positioning system of the lithographic apparatus for applying a device pattern at multiple locations across the substrate, wherein using the height map comprises:\n decomposing the height map into a plurality of components, including a first height map component representing topographical variations associated with the device pattern and a second height map component representing other topographical variations; \n using each of the first and second height map components, calculating control set-points according to a control algorithm specific to each of the first and second height map components; \n combining the control set-points calculated for the first height map component and the second height map component; and \n using the combined set-points to control the positioning system to apply the device pattern to the substrate.

Utility

["355", "067000"]

2018-01

2018-07

A lithographic apparatus applies a device pattern at multiple fields across a substrate. A height map is decomposed into a plurality of components. A first height map component represents topographical variations associated with the device pattern. One or more further height map components represent other topographical variations. Using each height map component, control set-points are calculated according to a control algorithm specific to each component. The control set-points calculated for the different height map components are then combined and used to control imaging of the device pattern to the substrate. The specific control algorithms can be different from one another, and may have differing degrees of nonlinearity. The combining of the different set-points can be linear. Focus control in the presence of device-specific topography and other local variations can be improved.

['15752658', '15736142', '15121340', '16076743', '11588281']

open

(15743661, 1)

test

The method of claim 4 , wherein generating the sequence of light comprises reduced the size of the one or more image representations to fit within the scan pattern projection area.

Utility

["348", "744000"]

2018-01

2018-07

Image projection devices, high-speed fiber scanned displays and related methods for projecting an image onto a surface and interfacing with the projected image are provided. A method for projecting one or more images and obtaining feedback with an optical input-output assembly is provided. The input-output assembly comprising a light-scanning optical fiber and a sensor. The method includes generating a sequence of light in response to one or more image representations and a scan pattern of the optical fiber, articulating the optical fiber in the scan pattern, projecting the sequence of light from the articulated optical fiber, and generating a feedback signal with the sensor in response to reflections of the sequence of light.

['12468832', '14275436', '14863276', '15645350', '14379270']

none

(15862136, 5)

test

The method of claim 3 , wherein generating the sequence of light comprises matching at least a portion of the one or more image representations with a shape of the scan pattern projection area by cropping the one or more image representations.

Utility

["348", "744000"]

2018-01

2018-07

Image projection devices, high-speed fiber scanned displays and related methods for projecting an image onto a surface and interfacing with the projected image are provided. A method for projecting one or more images and obtaining feedback with an optical input-output assembly is provided. The input-output assembly comprising a light-scanning optical fiber and a sensor. The method includes generating a sequence of light in response to one or more image representations and a scan pattern of the optical fiber, articulating the optical fiber in the scan pattern, projecting the sequence of light from the articulated optical fiber, and generating a feedback signal with the sensor in response to reflections of the sequence of light.

['12468832', '14275436', '14863276', '15645350', '14379270']

none

(15862136, 4)

test

The method of claim 2 , wherein the second format is a non-rectangular format.

Utility

["348", "744000"]

2018-01

2018-07

Image projection devices, high-speed fiber scanned displays and related methods for projecting an image onto a surface and interfacing with the projected image are provided. A method for projecting one or more images and obtaining feedback with an optical input-output assembly is provided. The input-output assembly comprising a light-scanning optical fiber and a sensor. The method includes generating a sequence of light in response to one or more image representations and a scan pattern of the optical fiber, articulating the optical fiber in the scan pattern, projecting the sequence of light from the articulated optical fiber, and generating a feedback signal with the sensor in response to reflections of the sequence of light.

['12468832', '14275436', '14863276', '15645350', '14379270']