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Wellbore drilling system according to claim 1, wherein the drilling tubular storage rack comprises multiple corresponding releasably connected fingerboard disc members provided at different heights on the post, which disc members are provided with corresponding tubular storage slots and which are adapted to store one or more drilling tubulars in combination.
Motor vehicle seat protective film <REFNUM> of claim 9, characterised in that the motor vehicle seat protective film <REFNUM> is a tubular piece <REFNUM> wherein a) the tubular piece <REFNUM> comprises flattenings which form the foldings <REFNUM> , b) the tubular piece <REFNUM> comprises a slit <REFNUM> which separates a lower edge <REFNUM> of the plastic film from an upper edge <REFNUM> of the plastic film <REFNUM> and c) tubular piece ends of the tubular piece <REFNUM> form the side edges <REFNUM> of the plastic film <REFNUM> . a) the tubular piece <REFNUM> comprises flattenings which form the foldings <REFNUM> , b) the tubular piece <REFNUM> comprises a slit <REFNUM> which separates a lower edge <REFNUM> of the plastic film from an upper edge <REFNUM> of the plastic film <REFNUM> and c) tubular piece ends of the tubular piece <REFNUM> form the side edges <REFNUM> of the plastic film <REFNUM> .
A control unit <REFNUM> for a vehicle <REFNUM> , arranged to estimate a position of the vehicle <REFNUM> relative to one or more radio transceivers <REFNUM> , comprising; a first obtaining module (Sx1) arranged to obtain vehicle motion data related to a trajectory of the vehicle <REFNUM> ; a second obtaining module (Sx2) arranged to obtain propagation delay data <REFNUM> associated with radio transmission between a vehicle transceiver <REFNUM> comprised in the vehicle <REFNUM> and the one or more radio transceivers <REFNUM> ; an identification module (Sx3) arranged to identify one or more multipath components <REFNUM> , MPC, in the propagation delay data, where each MPC relates to a radio transmission propagation path between a fixed radio transceiver <REFNUM> and the vehicle transceiver <REFNUM> , and where at least one MPC relates to an indirect radio transmission propagation path between a fixed radio transceiver <REFNUM> and the vehicle transceiver <REFNUM> ; a determining module (Sx4) arranged to determine an MPC track for each identified MPC based on the vehicle motion data and on the propagation delay data <REFNUM> , where an MPC track represents evolution of an MPC over time; and an estimating module (Sx5) arranged to estimate the position of the vehicle <REFNUM> relative to the one or more radio transceivers <REFNUM> based on the MPC tracks, characterised in that identification module (Sx3) is arranged to detect propagation paths, group detected paths within a defined distance and based on respective propagation path delay, and to identify each group of propagation paths as a single MPC having a respective MPC delay value. a first obtaining module (Sx1) arranged to obtain vehicle motion data related to a trajectory of the vehicle <REFNUM> ; a second obtaining module (Sx2) arranged to obtain propagation delay data <REFNUM> associated with radio transmission between a vehicle transceiver <REFNUM> comprised in the vehicle <REFNUM> and the one or more radio transceivers <REFNUM> ; an identification module (Sx3) arranged to identify one or more multipath components <REFNUM> , MPC, in the propagation delay data, where each MPC relates to a radio transmission propagation path between a fixed radio transceiver <REFNUM> and the vehicle transceiver <REFNUM> , and where at least one MPC relates to an indirect radio transmission propagation path between a fixed radio transceiver <REFNUM> and the vehicle transceiver <REFNUM> ; a determining module (Sx4) arranged to determine an MPC track for each identified MPC based on the vehicle motion data and on the propagation delay data <REFNUM> , where an MPC track represents evolution of an MPC over time; and an estimating module (Sx5) arranged to estimate the position of the vehicle <REFNUM> relative to the one or more radio transceivers <REFNUM> based on the MPC tracks, characterised in that identification module (Sx3) is arranged to detect propagation paths, group detected paths within a defined distance and based on respective propagation path delay, and to identify each group of propagation paths as a single MPC having a respective MPC delay value.
Method according to one of claims 1 to 7, wherein the vascular tree <REFNUM> and the at least one assigned value (p BI ) of the characteristic measured variable is visually displayed.
A computer-implemented method of identifying a pupil edge in a digital image, the method comprising: receiving <REFNUM> a digital pupil image; determining <REFNUM> a pupil candidate region in the digital pupil image; generating <REFNUM> a mean first portion pixel intensity of a first portion of the pupil candidate region <REFNUM> and generating <REFNUM> a mean second portion pixel intensity of a second portion of the pupil candidate region <REFNUM> , wherein the first portion is an area positioned along the left side edge of the pupil candidate region <REFNUM> and the second portion is an area positioned along the right side edge of the pupil candidate region <REFNUM> ; averaging the mean first portion pixel intensity and the mean second portion pixel intensity to generate <REFNUM> an average pixel intensity; determining <REFNUM> a modified standard deviation, including: calculating a standard deviation of a pixel intensity for each pixel within the first portion and the second portion; and multiplying the standard deviation by a multiplier, wherein the multiplier is more than 1 but no greater than 3; generating <REFNUM> a threshold value by summing the average pixel intensity and the modified standard deviation; and using the threshold value, identifying the pupil edge in the digital pupil image. receiving <REFNUM> a digital pupil image; determining <REFNUM> a pupil candidate region in the digital pupil image; generating <REFNUM> a mean first portion pixel intensity of a first portion of the pupil candidate region <REFNUM> and generating <REFNUM> a mean second portion pixel intensity of a second portion of the pupil candidate region <REFNUM> , wherein the first portion is an area positioned along the left side edge of the pupil candidate region <REFNUM> and the second portion is an area positioned along the right side edge of the pupil candidate region <REFNUM> ; averaging the mean first portion pixel intensity and the mean second portion pixel intensity to generate <REFNUM> an average pixel intensity; determining <REFNUM> a modified standard deviation, including: calculating a standard deviation of a pixel intensity for each pixel within the first portion and the second portion; and multiplying the standard deviation by a multiplier, wherein the multiplier is more than 1 but no greater than 3; calculating a standard deviation of a pixel intensity for each pixel within the first portion and the second portion; and multiplying the standard deviation by a multiplier, wherein the multiplier is more than 1 but no greater than 3; generating <REFNUM> a threshold value by summing the average pixel intensity and the modified standard deviation; and using the threshold value, identifying the pupil edge in the digital pupil image.
A computer program comprising instructions which, when the program is executed by a computer, cause the computer to carry out the method according to any of claims 1 to 5 or claims 6 to 12.
A carousel according to the preceding claim, wherein the two pins <REFNUM> are diametrically opposed.
A computer-implemented method <REFNUM> in a computer server, the method comprising: authenticating <REFNUM> a requesting party accessing the computer server from a remote communication system; receiving <REFNUM> selective availability attributes for a target mobile station from the requesting party, the requesting party is a first device that is not the target mobile station, the selective availability attributes indicating conditions under which the target mobile station is enabled or disabled to operate, and features that are available on the target mobile station under one or more conditions when the target mobile station is enabled, wherein the selective availability attributes restrict features available on the target mobile station <REFNUM> during a specified time period; and downloading the selective availability attributes to the target mobile station <REFNUM> . authenticating <REFNUM> a requesting party accessing the computer server from a remote communication system; receiving <REFNUM> selective availability attributes for a target mobile station from the requesting party, the requesting party is a first device that is not the target mobile station, the selective availability attributes indicating conditions under which the target mobile station is enabled or disabled to operate, and features that are available on the target mobile station under one or more conditions when the target mobile station is enabled, wherein the selective availability attributes restrict features available on the target mobile station <REFNUM> during a specified time period; and downloading the selective availability attributes to the target mobile station <REFNUM> .
The method of claim 13 or claim 14, wherein the multi-grade lubricating oil composition includes about 1 to about 8 weight percent of the hydrocarbyl substituted succinamide or succinimide dispersant.
The panel assembly <REFNUM> of any of claims 2 to 4, wherein the sealing member <REFNUM> is of a zigzagged shape in the moving direction (S).
The system of one of the preceding claims, wherein determining whether the search query is included in the high local intent cluster or the low local intent cluster comprises: searching multiple different query clusters using the search query; determining whether a given query cluster that is determined to include the search query based on the search has been assigned a value to the intent flag indicating as a high local intent cluster or a low local intent cluster; and assigning to the intent flag a value indicating that the search query is a high local intent query or a low local intent query based on the determined assigned value to the intent flag of the given query cluster that includes the search query. searching multiple different query clusters using the search query; determining whether a given query cluster that is determined to include the search query based on the search has been assigned a value to the intent flag indicating as a high local intent cluster or a low local intent cluster; and assigning to the intent flag a value indicating that the search query is a high local intent query or a low local intent query based on the determined assigned value to the intent flag of the given query cluster that includes the search query.
The casting device <REFNUM> according to claim 6, wherein the inner circumferential surface <REFNUM> of a trailing end <REFNUM> of the sleeve <REFNUM> that is adjacent to the pouring hole <REFNUM> and positioned toward the injection device <REFNUM> includes a first section <REFNUM> and a second section <REFNUM> , the first section <REFNUM> overlapping with the pouring hole <REFNUM> in the direction of the central axis (O) of the sleeve <REFNUM> , the second section <REFNUM> being adjacent to the first section <REFNUM> in the circumferential direction of the sleeve <REFNUM> and in contact with the outer circumferential surface of the tip <REFNUM> ; and wherein the distance between the first section <REFNUM> and the centerline (O) of the sleeve <REFNUM> is longer than the distance between the second section <REFNUM> and the centerline (O).
The apparatus of claim 8, further comprising a non-conductive material <REFNUM> disposed in the cavity <REFNUM> , wherein the non-conductive material <REFNUM> at least partially surrounds the circuit element <REFNUM> , preferably wherein the non-conductive material comprises a non- conductive epoxy.
Use of a bag and/or a bag and tube set filled with baby food concentrate as a source of baby food concentrate <REFNUM> in a device according to one of Claims 1 to 7 for preparing baby food, in particular baby milk.
The manufacturing method for a suspension body <REFNUM> for an elevator according to claim 7, wherein the number of fibers contained in the high-strength fiber groups <REFNUM> continuously changes from the center portion toward the both end portions.
The method according to claim 1, wherein the SOC value is converted and expressed in one of units including percentage (%), ampere-hour (Ah) and watt-hour (Wh).
The compound of any one of the preceding claims, wherein R 2 and R 3 are the same; optionally wherein R 2 and R 3 are C 1-9 alkyl, further optionally wherein R 2 and R 3 are C 8 alkyl.
The method of any of claims 29 to 31, characterized by including forwarding the measured values to a remote node, communicatively coupled to the control unit.
Method for monitoring clock synchronization errors for a network <REFNUM> , the method comprising the steps of - sending, by a monitoring node <REFNUM> , a synchronization error test message <REFNUM> to at least two nodes <REFNUM> in the network <REFNUM> ; - receiving, by the monitoring node <REFNUM> , an acknowledgment message <REFNUM> from each of the at least two nodes <REFNUM> , wherein each acknowledgement message <REFNUM> comprises a time-stamp representing the local time at which the node <REFNUM> has received the synchronization error test message <REFNUM> ; and - computing, by the monitoring node <REFNUM> , synchronization errors based on the received time-stamps. - sending, by a monitoring node <REFNUM> , a synchronization error test message <REFNUM> to at least two nodes <REFNUM> in the network <REFNUM> ; - receiving, by the monitoring node <REFNUM> , an acknowledgment message <REFNUM> from each of the at least two nodes <REFNUM> , wherein each acknowledgement message <REFNUM> comprises a time-stamp representing the local time at which the node <REFNUM> has received the synchronization error test message <REFNUM> ; and - computing, by the monitoring node <REFNUM> , synchronization errors based on the received time-stamps.
Probe measuring apparatus <REFNUM> according to one of the preceding Claims 10 to 15, characterized by a radially extending abutment face <REFNUM> for axial planar abutment, and/or by a substantially cylindrical subsection <REFNUM> for radial centring.
The attack detection device <REFNUM> according to claim 1, wherein types of physical quantities that can be observed by the two sensors are different from each other.
The network component of claim 8, wherein each client is configured to determine a mutual information index as a function of the entropy of the output weights of the local and global networks, and the correlation coefficient between them.
Particle sensor according to claim 2, wherein the particle sensor is arranged such that the first portion of the electromagnetic wave <REFNUM> emitted by the emitter <REFNUM> traverses the detection space <REFNUM> and enters then the detector <REFNUM> , and the second portion of the electromagnetic wave <REFNUM> emitted by the emitter <REFNUM> enters the further detector <REFNUM> traversing the detection space <REFNUM> with a different path length before entering the further detector <REFNUM> .
The food processor of claim 2, wherein: the feeding hole <REFNUM> extends from an edge of one end surface of the mounting protrusion <REFNUM> away from the storage cavity <REFNUM> to a bottom of the storage base <REFNUM> ; and/or a side wall surface of the mounting protrusion <REFNUM> is inclined outward from one end of the mounting protrusion <REFNUM> away from a bottom wall of the storage base <REFNUM> to one end of the mounting protrusion <REFNUM> near the bottom wall of the storage base <REFNUM> ; and/or a shape of the receiving groove <REFNUM> is adapted to a shape of one end of the working screw <REFNUM> protruding into the receiving groove <REFNUM> ; and/or the bottom wall of the storage base <REFNUM> is recessed into the storage cavity <REFNUM> to form the receiving groove <REFNUM> and the mounting protrusion <REFNUM> . the feeding hole <REFNUM> extends from an edge of one end surface of the mounting protrusion <REFNUM> away from the storage cavity <REFNUM> to a bottom of the storage base <REFNUM> ; and/or a side wall surface of the mounting protrusion <REFNUM> is inclined outward from one end of the mounting protrusion <REFNUM> away from a bottom wall of the storage base <REFNUM> to one end of the mounting protrusion <REFNUM> near the bottom wall of the storage base <REFNUM> ; and/or a shape of the receiving groove <REFNUM> is adapted to a shape of one end of the working screw <REFNUM> protruding into the receiving groove <REFNUM> ; and/or the bottom wall of the storage base <REFNUM> is recessed into the storage cavity <REFNUM> to form the receiving groove <REFNUM> and the mounting protrusion <REFNUM> .
The pitch system of any of claims 10-14, wherein the speed parameter of the wind turbine <REFNUM> comprises at least one of rotor speed or generator speed.
The method of any of claims 1 to 3, wherein the pre-determined modulation format is a quadrature-amplitude modulation, QAM, format.
A tubular compression garment for monitoring the therapy and physiological activity of the person, said tubular compression garment comprising a classic compression garment <REFNUM> and a sensor-control unit <REFNUM> , characterized in that , the compression garment <REFNUM> comprises at least one stretch-measuring sensor <REFNUM> attached to the compression garment <REFNUM> , wherein the stretch-measuring sensor <REFNUM> is implemented as a strip made of electroactive polymers that change their capacitance during stretch, and the stretch-measuring sensor <REFNUM> is attached to the compression garment <REFNUM> in a way for measuring the stretch of the compression garment predominantly in the circumferential direction perpendicular to the longitudinal axis of a part of the body wrapped by the compression garment, wherein the compression garment <REFNUM> is provided with a socket <REFNUM> for receiving the sensor-control unit <REFNUM> and the socket <REFNUM> is provided with first contacts <REFNUM> for connection with the stretch-measuring sensor <REFNUM> and the compression garment <REFNUM> is, in the area of the socket <REFNUM> , provided with a hole <REFNUM> , and wherein the sensor-control unit <REFNUM> is provided with second contacts <REFNUM> for connecting to the first contacts <REFNUM> made on the socket <REFNUM> and wherein the sensor-control unit <REFNUM> comprises at least a motion sensor, a photoplethysmographic sensor, a temperature sensor and a processing unit with a clock, and the sensor-control unit <REFNUM> is detachably secured to the compression garment <REFNUM> .
Method according to one of Claims 10 to 12, characterized in that the compressor elements <REFNUM> are simultaneously moved in different movement directions <REFNUM> .
The apparatus of any of claims 1-4, wherein the on-duration monitoring comprises discontinuous reception on-duration monitoring.
The vehicle suction system according to claim 11, wherein the pump circuit comprises a feed pump unit <REFNUM> with a feed outlet <REFNUM> and with a feed inlet connected to the suction line <REFNUM> ; wherein optionally the feed pump unit may be provided in another additional compartment <REFNUM> .
The robot cleaner <REFNUM> of claim 1, wherein the memory further stores a first artificial intelligence model trained to determine pollution sources, wherein the processor <REFNUM> is further configured to: input the information on a degree of pollution for each location in the map from two or more pollution maps among the pollution map (2, 2-1, 2-2, 2-3, 121, 320, 410, 420) related to a time section from a time point when a predetermined event occurs to a predetermined time point after the event was finished. wherein the memory further stores a first artificial intelligence model trained to determine pollution sources, wherein the processor <REFNUM> is further configured to: input the information on a degree of pollution for each location in the map from two or more pollution maps among the pollution map (2, 2-1, 2-2, 2-3, 121, 320, 410, 420) related to a time section from a time point when a predetermined event occurs to a predetermined time point after the event was finished.
. The onboard computing device <REFNUM> of any of claims 1 to 7, wherein the forecast of network availability includes a probability that the target network will be available for transmission at a time prior to the maximum allowable delay period.
The controller <REFNUM> for rotary electric machine according to any one of claims 1 to 4, wherein the current detection unit <REFNUM> detects the current at least twice in the one period (Th) of the carrier wave.
The direct current circuit breaker handcart according to any one of claims 1-13, wherein the commutation inductor <REFNUM> is located on a side of the commutation capacitor charger <REFNUM> away from the support surface <REFNUM> in the third direction (Z), and is located between the main circuit breaker <REFNUM> and the auxiliary circuit breaker <REFNUM> in the second direction (Y); the direct current circuit breaker handcart further comprises an isolation transformer <REFNUM> , the isolation transformer <REFNUM> is electrically connected with the commutation switch assembly <REFNUM> , and is located on a side of the commutation capacitor <REFNUM> away from the support surface <REFNUM> , and is adjacent to and spaced apart from the commutation switch assembly <REFNUM> . the commutation inductor <REFNUM> is located on a side of the commutation capacitor charger <REFNUM> away from the support surface <REFNUM> in the third direction (Z), and is located between the main circuit breaker <REFNUM> and the auxiliary circuit breaker <REFNUM> in the second direction (Y); the direct current circuit breaker handcart further comprises an isolation transformer <REFNUM> , the isolation transformer <REFNUM> is electrically connected with the commutation switch assembly <REFNUM> , and is located on a side of the commutation capacitor <REFNUM> away from the support surface <REFNUM> , and is adjacent to and spaced apart from the commutation switch assembly <REFNUM> .
The stable liquid eutectic system according to claim 1, wherein the active ingredient is green tea catechins, in particularly chosen from epicatechins, epigallocatechin, epicatechin-3-gallate, epigallocatechin gallate.
System according to claim 3, wherein the annular component <REFNUM> is designed as a separate unit which is configured in such a way that it is connectable to the rotational component <REFNUM> .
An apparatus <REFNUM> for fabricating an elastic nonwoven material, said apparatus comprising: a rotary ultrasonic horn <REFNUM> ; and a rotary anvil <REFNUM> positionable in close proximity to the rotary ultrasonic horn, wherein the rotary anvil has a face <REFNUM> with a width and a circumferential axis <REFNUM> , the face having a plurality of ridges <REFNUM> each of which defines a plurality of interspaced lands <REFNUM> and notches <REFNUM> , the ridges extending obliquely across the circumferential axis, and the notches oriented substantially parallel to the circumferential axis. a rotary ultrasonic horn <REFNUM> ; and a rotary anvil <REFNUM> positionable in close proximity to the rotary ultrasonic horn, wherein the rotary anvil has a face <REFNUM> with a width and a circumferential axis <REFNUM> , the face having a plurality of ridges <REFNUM> each of which defines a plurality of interspaced lands <REFNUM> and notches <REFNUM> , the ridges extending obliquely across the circumferential axis, and the notches oriented substantially parallel to the circumferential axis.
The instrument assembly of any one of Claims 7 to 10, wherein the twisted member of the second flexible member includes a single flat wire <REFNUM> twisted between the first twisted member end and the second twisted member end.
A method for producing a protein of interest (POI) encoded by a gene of interest (GOI) by culturing the host cell of any one of claims 1 to 8 under conditions to produce said POI.
Aircraft comprising at least one nacelle as claimed in one of the preceding claims.
Reflective optical element according to any of Claims 1 to 3, characterized in that the metallic coating <REFNUM> comprises aluminium, an aluminium-silicon alloy, an aluminium-manganese alloy, an aluminium-silicon-manganese alloy, rhodium or a combination thereof.
An auto-configuration method, comprising: obtaining (S210), by a base station, inventory configuration information of the base station, wherein the base station comprises a control node and at least one hardware node, the inventory configuration information of the base station comprises inventory configuration information of the at least one hardware node, and inventory configuration information of each hardware node indicates topology information and hardware attribute information of each hardware node; sending (S220), by the base station, the inventory configuration information of the base station to an auto-configuration apparatus, wherein the inventory configuration information of the base station is used to determine physical configuration information of the base station, the physical configuration information of the base station indicates topology information and hardware attribute information of each node that needs to be configured, and all the nodes that need to be configured comprise some or all of the at least one hardware node, wherein the topology information of each node that needs to be configured indicates a connection relationship among the nodes that need to be configured; receiving (S250), by the base station, the physical configuration information of the base station and logical mapping configuration information of the base station that are sent by the auto-configuration apparatus, wherein the logical mapping configuration information of the base station indicates a mapping relationship between a hardware resource comprised in the base station and a logical resource corresponding to the hardware resource, and the hardware resource comprises each node that needs to be configured, wherein the logical resource can be used by each node that needs to be configured to transmit a service; and configuring (S260), by the base station based on the physical configuration information of the base station and the logical mapping configuration information of the base station, each node that needs to be configured. obtaining (S210), by a base station, inventory configuration information of the base station, wherein the base station comprises a control node and at least one hardware node, the inventory configuration information of the base station comprises inventory configuration information of the at least one hardware node, and inventory configuration information of each hardware node indicates topology information and hardware attribute information of each hardware node; sending (S220), by the base station, the inventory configuration information of the base station to an auto-configuration apparatus, wherein the inventory configuration information of the base station is used to determine physical configuration information of the base station, the physical configuration information of the base station indicates topology information and hardware attribute information of each node that needs to be configured, and all the nodes that need to be configured comprise some or all of the at least one hardware node, wherein the topology information of each node that needs to be configured indicates a connection relationship among the nodes that need to be configured; receiving (S250), by the base station, the physical configuration information of the base station and logical mapping configuration information of the base station that are sent by the auto-configuration apparatus, wherein the logical mapping configuration information of the base station indicates a mapping relationship between a hardware resource comprised in the base station and a logical resource corresponding to the hardware resource, and the hardware resource comprises each node that needs to be configured, wherein the logical resource can be used by each node that needs to be configured to transmit a service; and configuring (S260), by the base station based on the physical configuration information of the base station and the logical mapping configuration information of the base station, each node that needs to be configured.
A data processing device comprising a processor adapted to perform the method of any of claims 1 to 13.
The system of any one of claims 1-6, comprising a camera unit configured for recording images of an eye of the patient and generating eye image data based thereon, wherein said input data comprises said image data.
The article as defined in claim 1, the article is a security device.
The method according to claim 6 or 7, characterized in that the elastomer and the reinforcing material <REFNUM> are each applied as a bead of material.
The method according to any of the previous Claims, wherein said PAA is used to produce a recycled SAP; wherein said recycled SAP has a swelling ratio; and wherein said swelling ratio is greater than 45 g/g.
The method of claim 1, further comprising: determining an available temporary route for migrating the first and second services based on a dependency between a first temporary route and a second temporary route in a plurality of temporary routes, wherein: the first temporary route is configured to migrate the first service from a first route in a first step in a migration sequence to an second route in a second step in the migration sequence, the second temporary route is configured to migrate the second service from a third route in a third step in the migration sequence to a fourth route in a fourth step in the migration sequence, and if the third step is between the first and second steps in the migration sequence, then the first temporary route and the second temporary route use different resources. the first temporary route is configured to migrate the first service from a first route in a first step in a migration sequence to an second route in a second step in the migration sequence, the second temporary route is configured to migrate the second service from a third route in a third step in the migration sequence to a fourth route in a fourth step in the migration sequence, and if the third step is between the first and second steps in the migration sequence, then the first temporary route and the second temporary route use different resources.
Microscope in accordance with Claim 10, Characterized in that the axial component <REFNUM> of the spring force (F2) of the second spring arrangement <REFNUM> acting parallel to the optical axis (OA) is essentially not linearly proportional to the movement path in the Hooke's law-compliant movement range of the infinity object lens <REFNUM> relative to the housing <REFNUM> .
The method of claim 1, further comprising: for each of the plurality of models, determining, by the processor, a weight for the respective model; and generating, by the processor, and based on the corresponding boundary prediction portions of the boundary predictions and the weight for each model of the plurality of models, the clustered boundary prediction as a weighted clustered boundary prediction for the object within the image. for each of the plurality of models, determining, by the processor, a weight for the respective model; and generating, by the processor, and based on the corresponding boundary prediction portions of the boundary predictions and the weight for each model of the plurality of models, the clustered boundary prediction as a weighted clustered boundary prediction for the object within the image.
The sealable film of claim 1, wherein the slip agent and the antistatic agent in the sealable film are migratory.
A packet forwarding method, comprising: receiving (S53), by a second node <REFNUM> , a first packet from a first node <REFNUM> , wherein the first packet comprises a first session identifier; and sending, by the second node <REFNUM> , the first packet based on the first session identifier, wherein the first session identifier comprises a first application-aware identifier corresponding to the first packet, wherein the application-aware identifier is based on an application-aware networking, APN or an application-aware IPv6 networking, APN6 and comprises an application identifier and a user identifier, wherein the first session identifier is used by the second node <REFNUM> to perform load balancing, and wherein the sending, by the second node <REFNUM> , the first packet based on the first session identifier comprises: generating (S54), by the second node <REFNUM> , a session table based on the first session identifier, wherein the session table comprises a key value and next-hop information, and the key value comprises the first application-aware identifier; and finding (S55), by the second node <REFNUM> , the next-hop information based on the key value corresponding to the first session identifier, and sending the first packet based on the next-hop information. receiving (S53), by a second node <REFNUM> , a first packet from a first node <REFNUM> , wherein the first packet comprises a first session identifier; and sending, by the second node <REFNUM> , the first packet based on the first session identifier, wherein the first session identifier comprises a first application-aware identifier corresponding to the first packet, wherein the application-aware identifier is based on an application-aware networking, APN or an application-aware IPv6 networking, APN6 and comprises an application identifier and a user identifier, wherein the first session identifier is used by the second node <REFNUM> to perform load balancing, and wherein the sending, by the second node <REFNUM> , the first packet based on the first session identifier comprises: generating (S54), by the second node <REFNUM> , a session table based on the first session identifier, wherein the session table comprises a key value and next-hop information, and the key value comprises the first application-aware identifier; and finding (S55), by the second node <REFNUM> , the next-hop information based on the key value corresponding to the first session identifier, and sending the first packet based on the next-hop information. generating (S54), by the second node <REFNUM> , a session table based on the first session identifier, wherein the session table comprises a key value and next-hop information, and the key value comprises the first application-aware identifier; and finding (S55), by the second node <REFNUM> , the next-hop information based on the key value corresponding to the first session identifier, and sending the first packet based on the next-hop information.
The sheet handling apparatus <REFNUM> according to any one of claims 1 to 3, wherein the mounting unit <REFNUM> has at least one hole <REFNUM> formed in a first direction and at least one hole <REFNUM> formed in a second direction different from the first direction, the frame <REFNUM> has insertion portions <REFNUM> corresponding to the respective holes <REFNUM> of the mounting unit <REFNUM> , and the frame <REFNUM> is mounted to the mounting unit <REFNUM> with the respective insertion portions <REFNUM> being inserted to the corresponding holes <REFNUM> of the mounting unit <REFNUM> . the mounting unit <REFNUM> has at least one hole <REFNUM> formed in a first direction and at least one hole <REFNUM> formed in a second direction different from the first direction, the frame <REFNUM> has insertion portions <REFNUM> corresponding to the respective holes <REFNUM> of the mounting unit <REFNUM> , and the frame <REFNUM> is mounted to the mounting unit <REFNUM> with the respective insertion portions <REFNUM> being inserted to the corresponding holes <REFNUM> of the mounting unit <REFNUM> .
The Fc-silenced anti-oxMIF antibody of claims 1 to 3 comprising i.) SEQ ID NOs:3 and 6, ii.) SEQ ID NOs:9 and 6, iii.) SEQ ID NOs:4 and 6, iv.) SEQ ID NOs:4 and 8, v.) SEQ ID NOs:4 and 5, or vi.) SEQ ID NO:43 and any one of SEQ ID NOs:5, 6 or 8. i.) SEQ ID NOs:3 and 6, ii.) SEQ ID NOs:9 and 6, iii.) SEQ ID NOs:4 and 6, iv.) SEQ ID NOs:4 and 8, v.) SEQ ID NOs:4 and 5, or vi.) SEQ ID NO:43 and any one of SEQ ID NOs:5, 6 or 8.
A system in accordance with claim 4, wherein the processing means is adapted to calculate a volumetric flow rate of the first phase using the tomography data and said signal, calculate a volumetric flow rate of the second phase using the tomography data, the density data, and said signal, and calculate a volumetric flow rate of the third phase using the tomography data and the density data.
The method as claimed in claim 1, wherein the intent associated with the at least one voice input is identified by performing Natural-Language Understanding on the at least one voice input.
The actuator <REFNUM> of one of claims 1 to 7, wherein the electric motor <REFNUM> is a brushless direct current motor.
The composition of any one of claims 1 to 7, where starting material (E), the anchorage additive, is present and is selected from the group consisting of (E-1) vinyltriacetoxysilane, (E-2) glycidoxypropyltrimethoxysilane, (E-3) a combination of (E-1) and (E-2), and (E-4) a combination of (E-3) and a polydimethylsiloxane terminated with hydroxyl groups, methoxy groups, or terminated with both a hydroxy group and a methoxy group.
The method of claim 1, wherein the forming of the core structure <REFNUM> further comprises forming a second of the baffles <REFNUM> ; and overmolding thermoplastic material onto the ribbon material <REFNUM> , between the second of the baffles <REFNUM> and the first of the septums <REFNUM> , to form a second set of the walls <REFNUM> .
The composite transmission housing according to claim 6, wherein the attachment insert <REFNUM> and/or bearing insert <REFNUM> has a spool-shape.
The method according to claim 6, wherein the first channel state information configuration is further associated with N 2 CSI-IM resources, the N 2 CSI-IM resources comprise a first-type CSI-IM resource and/or a second-type CSI-IM resource, the first-type CSI-IM resource is used to measure interference information in a multi-station joint transmission mechanism, and the second-type CSI-IM resource is used to measure interference information in a single-station transmission mechanism, wherein N 2 is a positive integer.
A compound according to the formula: or or a pharmaceutically acceptable salt thereof
Steam turbine plant <REFNUM> according to Claim 7, in which the heat accumulator <REFNUM> is designed as a Ruths accumulator.
The light control sheet according to any one of claims 1 to 6, wherein: the second transparent electrode layer comprises a second electrode section <REFNUM> and a second insulating section <REFNUM> that is adjacent to the second electrode section in the direction parallel to the surface of the light control sheet, the second insulating section extending along an outer edge of the second electrode section in the plan view; and the first insulating section of the first transparent electrode layer overlaps the second insulating section of the second transparent electrode layer in the plan view. the second transparent electrode layer comprises a second electrode section <REFNUM> and a second insulating section <REFNUM> that is adjacent to the second electrode section in the direction parallel to the surface of the light control sheet, the second insulating section extending along an outer edge of the second electrode section in the plan view; and the first insulating section of the first transparent electrode layer overlaps the second insulating section of the second transparent electrode layer in the plan view.
The system of any preceding claim, wherein the controller <REFNUM> is configured to command the actuator <REFNUM> to maintain the lid in the closed position in response to a door to the aircraft lavatory being unlocked, and/or wherein the controller is configured to command the actuator to perform the opening actuation in response to a passenger pressing a button electrically coupled to the controller.
The device of claim 6, wherein the gas storage device is a gas tank, a purifier, filter, scrubber, pressure swing adsorption device, molecular sieve, hollow fiber membrane, ceramic membrane, cryogenic air separation device, or hybrid gas separation device.
The method of any preceding claims, wherein the phycocyanin synthesized by the cyanobacteria leaches from the cyanobacteria.
Longitudinal adjuster <REFNUM> , in particular for a vehicle seat <REFNUM> , having at least one pair of rails <REFNUM> which is formed from a first rail <REFNUM> and a second rail <REFNUM> guided displaceably in the longitudinal direction (x) relative to the first rail <REFNUM> , wherein at least the first rail <REFNUM> or the second rail <REFNUM> has at least one opening <REFNUM> for the fastening of an end cap <REFNUM> for an end <REFNUM> of the respective rail <REFNUM> , characterized in that the longitudinal adjuster <REFNUM> has an end cap <REFNUM> fastened in the opening <REFNUM> according to one of Claims 1 to 12.
Construction system according to any of the previous claims, characterized by the fact that said first electrode (110 / 210) acts as electric field source electrode and said second electrode (120 / 220) acts as electric field sensor electrode.
An electronic device <REFNUM> , comprising a circuit board and the wireless communication system according to any one of claims 1 to 14.
The method according to any of the preceding claims, wherein the circuit lines <REFNUM> comprise a metal ink and the electrical component <REFNUM> comprises a surface mounted device (SMD) placed before the thermoforming process (P).
The method according to claim 1, wherein the performing, by the terminal, detection on the search space in a first time period comprises: detecting, by the terminal, an uplink grant, UL grant, in the search space in the first time period; and the sending, by the terminal, the first request to the network device in a second time period comprises: sending, by the terminal, uplink data on a fifth transmission resource in the second time period, wherein the uplink data carries the first request, and the fifth transmission resource is a transmission resource that is used to transmit the uplink data and that is indicated by the UL grant. detecting, by the terminal, an uplink grant, UL grant, in the search space in the first time period; and the sending, by the terminal, the first request to the network device in a second time period comprises: sending, by the terminal, uplink data on a fifth transmission resource in the second time period, wherein the uplink data carries the first request, and the fifth transmission resource is a transmission resource that is used to transmit the uplink data and that is indicated by the UL grant.
The system of claim 9, wherein each warning for a corresponding task of the set of tasks comprises warning content, at least one media <REFNUM> used to deliver the warning content, and a manner by which the warning content is to be delivered to the driver.
The method of claim 1, further comprising: in response to the first user input: in accordance with a determination that the first location corresponds to a second region different from the first region where an edge swipe gesture starting from the edge of the touch-sensitive display and moving onto the touch-sensitive display will cause display of a second user interface element different from the first user interface element, displaying, on the touch-sensitive display, the second user interface element; and in accordance with a determination that the first location does not correspond to the second region, forgoing displaying the second user interface element. in accordance with a determination that the first location corresponds to a second region different from the first region where an edge swipe gesture starting from the edge of the touch-sensitive display and moving onto the touch-sensitive display will cause display of a second user interface element different from the first user interface element, displaying, on the touch-sensitive display, the second user interface element; and in accordance with a determination that the first location does not correspond to the second region, forgoing displaying the second user interface element.
The device according to Claim 9, characterized by a transmission and anonymization apparatus (DW) arranged in the backend computer (BE), which apparatus anonymizes the FAS data transmitted to the swarm memory (SQ) at the request of the analysis device (AW) and transmits the anonymized data to the user (N).
A system <REFNUM> for operating an automated vehicle <REFNUM> comprising the controller-circuit <REFNUM> of the preceding claim, said system <REFNUM> comprising: the detector <REFNUM> configured to detect construction-objects <REFNUM> .
The thrust control assembly of any preceding claim wherein the balk application arrangement comprises a smooth transition arrangement for providing a gradual reduction in balk force upon removal of the balk command, wherein the smooth transition arrangement comprises a smooth transition filter <REFNUM> .
Electrical machine <REFNUM> according to any one of the previous claims, characterised in that the cooling tube <REFNUM> can be filled with a cryogenic fluid.
A wing <REFNUM> for an aircraft <REFNUM> , comprising a main wing <REFNUM> , the high lift assembly <REFNUM> according to claim 1, wherein the connection assembly <REFNUM> movably connects the high lift body <REFNUM> to the main wing <REFNUM> , such that the high lift body <REFNUM> can be moved between the retracted position and the at least one extended position, and wherein the drive system <REFNUM> is mounted to the main wing <REFNUM> . a main wing <REFNUM> , the high lift assembly <REFNUM> according to claim 1, wherein the connection assembly <REFNUM> movably connects the high lift body <REFNUM> to the main wing <REFNUM> , such that the high lift body <REFNUM> can be moved between the retracted position and the at least one extended position, and wherein the drive system <REFNUM> is mounted to the main wing <REFNUM> .
The use of a reverse osmosis <REFNUM> of claim 1, wherein the reverse osmosis spacer <REFNUM> with a high recovery rate is stacked multiple times.
A cutting assembly as claimed in any preceding claim, in which the cutting element laterally overhangs the tool holder by at least 1 mm on either side.
An auto-aligning cable sensor <REFNUM> according to claim 3 or 4, wherein the flange <REFNUM> is formed by a ferrule <REFNUM> at the end of the cable <REFNUM> .
The method of any one of claims 1 to 5, wherein recognizing <REFNUM> the real-world items that already exist in the real-world environment and analyzing <REFNUM> the real-world items to determine the preferred characteristics for the real-world environment are implemented in response to receiving a user input that specifically requests that the item be displayed in the environment.
A shaped article according to claim 11, for use as a tissue support.
The nucleic acid complex of any of claims 1-7, wherein the voltage-sensing fluorophore and the reference label are present in 1:0.5 to 0.5:1 stoichiometry; preferably in about 1:1 stoichiometry; and/or wherein the first and/or second single-stranded nucleic acid molecule is less than 200 nucleotides; or less than 100 nucleotides; or less than 50 nucleotides.
The 400 MPa corrosion-resistant steel bar according to claim 1, wherein a nominal diameter of the steel bar is 6-32 mm.
The method of claim 1, wherein, in the nanowire synthesis solution, the metal ions include one or more selected from the group consisting of zinc ions (Zn 2+ ), zirconium ions (Zr 2+ ), aluminum ions (A1 3+ ), manganese ions (Mn 2+ ), titanium ions (Ti 2+ ), copper ions (Cu 2+ ), tungsten ions (W 6+ ), vanadium ions (V 4+ ), iron ions (Fe 2+ , Fe 3+ ), cobalt ions (Co 2+ , Co 3+ ), nickel ions (Ni 2+ ), silver ions (Ag + ), and gold ions (Au + ).
The light scattering measuring apparatus according to claim 1 or 2, wherein the optical element <REFNUM> has a portion having a triangular prism shape including the first surface <REFNUM> and a second surface <REFNUM> , which is opposed in parallel to the cell on a side opposite to the first surface <REFNUM> .
A kit of parts according to claim 1 or claim 2, wherein the sensor unit <REFNUM> includes a battery compartment <REFNUM> having a battery compartment closure element <REFNUM> , and the interchangeable covers <REFNUM> are so configured that the interchangeable covers <REFNUM> can only be mounted to or removed from the sensor unit <REFNUM> while the battery compartment closure element <REFNUM> of the sensor unit <REFNUM> is in an open position, the interchangeable covers <REFNUM> being securable to the sensor unit <REFNUM> by securing the battery compartment closure element <REFNUM> to the sensor unit <REFNUM> .
The system of claim 12, wherein the system further comprises an analog summation circuit to combine the first and second sample of the measurement signal to remove reduce a signal offset in the first and second sample and/or wherein the system further comprises a digital summation circuit to combine the first and second sample of the measurement signal to reduce a signal offset in the first and second sample.
The refrigerator of claim 12, wherein: the first valve body <REFNUM> and the second valve body <REFNUM> are arranged to open the first outlet (3a1) and the second outlet (3a3), respectively, when the driving gear <REFNUM> is rotated at a first rotation angle, the first valve body <REFNUM> and the second valve body <REFNUM> are arranged for the first outlet (3a1) to overlap the first regulation recess <REFNUM> and to close the second outlet (3a3), when the driving gear <REFNUM> is rotated at a second rotation angle, the first valve body <REFNUM> and the second valve body <REFNUM> are arranged to close the first outlet (3a1) and the second outlet (3a3), respectively, when the driving gear <REFNUM> is rotated at a third rotation angle, and the first valve body <REFNUM> is arranged to close the first outlet (3a1) and the second valve body <REFNUM> is arranged for the second regulation recess <REFNUM> of the second valve body <REFNUM> to overlap the second outlet (3a3), when the driving gear <REFNUM> is rotated at a fourth rotation angle. the first valve body <REFNUM> and the second valve body <REFNUM> are arranged to open the first outlet (3a1) and the second outlet (3a3), respectively, when the driving gear <REFNUM> is rotated at a first rotation angle, the first valve body <REFNUM> and the second valve body <REFNUM> are arranged for the first outlet (3a1) to overlap the first regulation recess <REFNUM> and to close the second outlet (3a3), when the driving gear <REFNUM> is rotated at a second rotation angle, the first valve body <REFNUM> and the second valve body <REFNUM> are arranged to close the first outlet (3a1) and the second outlet (3a3), respectively, when the driving gear <REFNUM> is rotated at a third rotation angle, and the first valve body <REFNUM> is arranged to close the first outlet (3a1) and the second valve body <REFNUM> is arranged for the second regulation recess <REFNUM> of the second valve body <REFNUM> to overlap the second outlet (3a3), when the driving gear <REFNUM> is rotated at a fourth rotation angle.
Deep fryer tank <REFNUM> according to claim 1, characterised in that said at least one lateral stiffening indentation <REFNUM> and said at least one other lateral stiffening indentation <REFNUM> extend into the deep fryer tank <REFNUM> .
A wireless fuse switch <REFNUM> for use with an electrical system <REFNUM> of a vehicle having a vehicle battery <REFNUM> connected to provide power to at least one electrical subsystem through a fuse <REFNUM> contained within a fuse socket <REFNUM> , the wireless fuse switch <REFNUM> comprising: a harness assembly <REFNUM> , and a wireless control module <REFNUM> contained within an outer housing <REFNUM> , the wireless control module <REFNUM> comprising: a control module transceiver <REFNUM> that receives wireless control commands; a relay <REFNUM> movable between an open position and a closed position; a relay controller <REFNUM> configured to move the relay <REFNUM> between the open position and the closed position based upon the received control commands; a power supply <REFNUM> to power the control module transceiver <REFNUM> , the relay controller <REFNUM> , and the relay <REFNUM> ; and a module connector <REFNUM> coupled to the relay <REFNUM> ; wherein the harness assembly <REFNUM> is receivable within the module connector <REFNUM> of the wireless control module <REFNUM> , wherein the module connector <REFNUM> connects the relay <REFNUM> to the fuse socket of the vehicle electrical system, wherein the harness assembly <REFNUM> includes a harness fuse socket <REFNUM> that receives the fuse removed from the fuse socket. a control module transceiver <REFNUM> that receives wireless control commands; a relay <REFNUM> movable between an open position and a closed position; a relay controller <REFNUM> configured to move the relay <REFNUM> between the open position and the closed position based upon the received control commands; a power supply <REFNUM> to power the control module transceiver <REFNUM> , the relay controller <REFNUM> , and the relay <REFNUM> ; and a module connector <REFNUM> coupled to the relay <REFNUM> ; wherein the harness assembly <REFNUM> is receivable within the module connector <REFNUM> of the wireless control module <REFNUM> , wherein the module connector <REFNUM> connects the relay <REFNUM> to the fuse socket of the vehicle electrical system, wherein the harness assembly <REFNUM> includes a harness fuse socket <REFNUM> that receives the fuse removed from the fuse socket.
An apparatus according to anyone of claims 1-5, wherein the operation device comprises an injection port <REFNUM> to calibrate the amount of hydraulic fluid.
The apparatus of claim 9, wherein the polytetrafluoroethylene comprises expanded polytetrafluoroethylene.
The method of any of claims 1 to 5, wherein step c) is performed at ambient pressure.
The data processing apparatus according to any of claims 1 to 5, comprising vector length calculating means configured to calculate, as the associated information, information of a vector length indicating a magnitude of the vector and an attenuated degree of the X-ray beam transmitted through the object at each of the pixels.
The method according to any one of claims 1 to 12, wherein an aspect ratio of the pattern is not less than 5 and not more than 25.
The electrochemical cell, as defined in claim 4, wherein said second zinc powder has a tap density greater than 3.0 g/cm 3 .
Thermal container according to at least one of the preceding claims, characterized in that either the rear cushion <REFNUM> comprises a rear cushion portion <REFNUM> which projects beyond the front cushion <REFNUM> on one side, or a closure flap adjoins the rear cushion <REFNUM> on one side, it being possible for the projecting rear cushion portion <REFNUM> or the closure flap to be folded onto a surface of the front cushion <REFNUM> and directly or indirectly connected thereto in order to close the cavity <REFNUM> , the projecting rear cushion portion <REFNUM> or the closure flap being made of the same material as the material of the at least one bag <REFNUM> .