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A system <REFNUM> as recited in claim 1, wherein the chambers <REFNUM> are coaxial with the longitudinal axis (X1).
The method according to any one of claims 11 - 14, wherein the product is a piping product, and each of the plurality of parts is a cylindrical part forming a portion of the piping product. the product is a piping product, and each of the plurality of parts is a cylindrical part forming a portion of the piping product.
The conveying device <REFNUM> according to any one of claims 8 or 9, characterized in that the frame <REFNUM> has at least one rail <REFNUM> , in particular a pair of rails, on which the conveying unit <REFNUM> is movably mounted and/or that at least the receiving means <REFNUM> is rotatably mounted in particular by at least 180°, about a vertical axis <REFNUM> .
Drive unit <REFNUM> for an electric vehicle, comprising a dual-clutch transmission <REFNUM> according to one of the preceding claims and an electric motor <REFNUM> for driving the input shaft <REFNUM> of the dual-clutch transmission <REFNUM> .
The automotive lighting apparatus according to Claim 6 or 7, wherein the opaque protruding plug or plugs <REFNUM> reach the top of said protruding collar or collars <REFNUM> .
The method of claim 1, wherein the control resource set comprises at least one subband within the control resource region that may comprise a control channel resource or a data channel resource.
Wall <REFNUM> according to either one of Claims 2 and 3, wherein the mass <REFNUM> , seen from the front, has an outer periphery <REFNUM> inscribed within the cavity <REFNUM> .
A needle <REFNUM> for aspirating a sample from a sample source and injecting the sample into a liquid chromatography system, the needle comprising: a needle body <REFNUM> including a tip <REFNUM> and a conical section (CS) adjacent to the tip, the conical section having a rough textured surface finish <REFNUM> in a region <REFNUM> that is offset from the tip, the needle body further having a smooth surface finish <REFNUM> in a region <REFNUM> extending from the tip to the rough textured surface region <REFNUM> ; wherein the rough textured surface finish <REFNUM> reduces a coefficient of friction of the needle body to avoid a seal material covering the sample source from clinging to the needle body as the needle enters or exits the sample source; wherein the smooth surface finish <REFNUM> maintains a liquid tight seal between the tip of the needle body and an injection seat when the needle injects the sample into an analytic flow path of the liquid chromatography system. a needle body <REFNUM> including a tip <REFNUM> and a conical section (CS) adjacent to the tip, the conical section having a rough textured surface finish <REFNUM> in a region <REFNUM> that is offset from the tip, the needle body further having a smooth surface finish <REFNUM> in a region <REFNUM> extending from the tip to the rough textured surface region <REFNUM> ; wherein the rough textured surface finish <REFNUM> reduces a coefficient of friction of the needle body to avoid a seal material covering the sample source from clinging to the needle body as the needle enters or exits the sample source; wherein the smooth surface finish <REFNUM> maintains a liquid tight seal between the tip of the needle body and an injection seat when the needle injects the sample into an analytic flow path of the liquid chromatography system.
The inverter device according to any one of claims 1 to 12, wherein the control unit is configured to, when detecting a failure in the power supply current detection sensor <REFNUM> or the phase current detection sensor <REFNUM> , to calculate the phase voltage commands based on a current command corresponding to a current flowing through the AC motor <REFNUM> , and an electric constant of the AC motor <REFNUM> .
Steering system for a vehicle, with a steering handle <REFNUM> for the manual application of a steering angle, with a steering angle sensor <REFNUM> for the detection of the steering angle (δ L ) and with a steering gear <REFNUM> for the conversion of the steering angle (δ L ) into a wheel steering angle (δ V ) at one or more steerable wheels <REFNUM> of the vehicle, the steering system being provided with a planetary gear mechanism which is coupled to the steering handle <REFNUM> , by a steering shaft <REFNUM> which is connected to the steering handle <REFNUM> being connected to the sun gear <REFNUM> of the planetary gear mechanism <REFNUM> , the steering system being configured as a steer-by-wire steering system without mechanical or hydraulic coupling between the steering shaft <REFNUM> of the steering handle <REFNUM> and a steering gear <REFNUM> , at least two planetary gears <REFNUM> of the planetary gear mechanism <REFNUM> being connected to steering angle sensors <REFNUM> , and the outer gear <REFNUM> of the planetary gear mechanism <REFNUM> being connected to an actuator <REFNUM> for the application of a torque to the steering handle <REFNUM> .
Sliding door system of one of claims 1 to 5, characterized by a running rail <REFNUM> which is designed as a floor rail, wherein a carriage which is guided on the floor rail is arranged on the lower side of the door leaf <REFNUM> , and wherein the guiding rail <REFNUM> guides the upper side of the door leaf <REFNUM> .
The fingerprint identification device according to claim 6, wherein, the pressure sensitive material is polyvinylidene fluoride or a quantum channel synthetic material.
The method as claimed in any one of claims 3-4, comprising controlling the optical communication by one or more layers of a protocol stack of the radio frequency communication.
The method of claim 1, wherein the indicator is xylenol orange tetrasodium salt.
The electric motor for a vehicle according to claim 1, characterized in that each of the cooling oil rings <REFNUM> comprises an inner ring <REFNUM> and an outer ring <REFNUM> , the outer ring <REFNUM> is sleeved outside the inner ring <REFNUM> , the inner ring <REFNUM> and the outer ring <REFNUM> are each provided with limiting teeth <REFNUM> for mounting with the stator <REFNUM> to prevent the cooling oil ring <REFNUM> from rotating circumferentially with the stator <REFNUM> , and the inner ring <REFNUM> and the outer ring <REFNUM> are each further provided with an oil ring fastener <REFNUM> for axially fixedly connecting the cooling oil ring <REFNUM> to the stator <REFNUM> .
Method for configuring radio resources <REFNUM> according to the preceding claim, wherein the step of detecting a cable link <REFNUM> comprises an exchange of messages between the first <REFNUM> and second <REFNUM> node devices via interfaces configured for being connected by at least one cable link <REFNUM> .
The manufacturing machine <REFNUM> according to claim 12 and comprising: a second moving device <REFNUM> , which moves, through the coupling station (S20), a second band <REFNUM> provided with a plurality of second pockets <REFNUM> housing respective absorbent pads <REFNUM> ; and a second feeding device <REFNUM> , which is arranged in the coupling station (S20), picks up an absorbent pad <REFNUM> from the second band <REFNUM> and couples the absorbent pad <REFNUM> to a mouthpiece <REFNUM> carried by the second seat <REFNUM> ; wherein the second band <REFNUM> has a succession of second through guide holes <REFNUM> ; and wherein the second moving device <REFNUM> has at least one second toothed guide drum <REFNUM> having a plurality of teeth, each designed to engage a corresponding second guide hole <REFNUM> of the second band <REFNUM> . a second moving device <REFNUM> , which moves, through the coupling station (S20), a second band <REFNUM> provided with a plurality of second pockets <REFNUM> housing respective absorbent pads <REFNUM> ; and a second feeding device <REFNUM> , which is arranged in the coupling station (S20), picks up an absorbent pad <REFNUM> from the second band <REFNUM> and couples the absorbent pad <REFNUM> to a mouthpiece <REFNUM> carried by the second seat <REFNUM> ; wherein the second band <REFNUM> has a succession of second through guide holes <REFNUM> ; and wherein the second moving device <REFNUM> has at least one second toothed guide drum <REFNUM> having a plurality of teeth, each designed to engage a corresponding second guide hole <REFNUM> of the second band <REFNUM> .
The method of claim 11, wherein the partial frequency sounding indicator comprises a value of 2, 3, 4, or 8.
Supporting structure according to Claim 9, characterized in that the fastening means <REFNUM> comprise eyes and/or chains and/or cables, the auxiliary frames <REFNUM> being able to be fastened thereby to the compression bars <REFNUM> .
Method according to the preceding claim, in which the second predetermined reduced value (Deg min) is between 0.2 and 0.8 times the first predetermined value (Deg n).
Watercraft for surface navigation according to any one of the preceding claims 2 to 4, characterized in that the first hinge <REFNUM> of said support means <REFNUM> comprises a fork element <REFNUM> with said housing body <REFNUM> interposed pivoted along a rotation axis (Y') parallel to said pitch axis (Y).
Flow cell according to Claim 5, characterized in that the material is an amorphous plastic, for example PMMA, PC, PS, COC or COP.
A system comprising: one or more computers; and one or more computer-readable media storing instructions that, when executed by the one or more computers, cause the one or more computers to perform the actions of the method of any of claims 1-13. one or more computers; and one or more computer-readable media storing instructions that, when executed by the one or more computers, cause the one or more computers to perform the actions of the method of any of claims 1-13.
The plastisol composition of claim 1, wherein the at least one epoxy resin is selected from the group consisting of aromatic epoxy resin, alicyclic epoxy resin, aliphatic epoxy resin, glycidyl ester resin, thioglycidyl ether resin, N-glycidyl ether resin, and combinations thereof.
The method of claim 9, further comprising: determining whether variations in the optical density data for each of the pel forming elements are greater than a predetermined threshold; transmitting a message indicating that the variations are greater than the predetermined threshold upon determining that the variations are greater than a predetermined threshold; and transmitting a message indicating that the variations are less than the pre-determined threshold upon determining that the variations are less than the pre-determined threshold. determining whether variations in the optical density data for each of the pel forming elements are greater than a predetermined threshold; transmitting a message indicating that the variations are greater than the predetermined threshold upon determining that the variations are greater than a predetermined threshold; and transmitting a message indicating that the variations are less than the pre-determined threshold upon determining that the variations are less than the pre-determined threshold.
The method of any of claims 9-10, further comprising: before expiration of the timer, receiving <REFNUM> one of the following from a second node that is configured to provide the SCG: a third indication that the SCG should be activated, or a fourth indication that the SCG should be deactivated; and stopping the timer <REFNUM> in response to the third indication or the fourth indication. before expiration of the timer, receiving <REFNUM> one of the following from a second node that is configured to provide the SCG: a third indication that the SCG should be activated, or a fourth indication that the SCG should be deactivated; and a third indication that the SCG should be activated, or a fourth indication that the SCG should be deactivated; and stopping the timer <REFNUM> in response to the third indication or the fourth indication.
The medical image processing device according to claim 1, wherein the correction unit applies the correction factor as a basic correction factor within the first depth range and applies a reduced correction factor that is relatively reduced from the basic correction factor within the second depth range.
Method according to the preceding claim, wherein said first thermoforming temperature is comprised in a range from 170°C - 190°C, subsequently to said provision step and prior to said flattening step, a second step for cooling said semi-finished product <REFNUM> being provided for a period of time comprised in a range from 0.5-1.5 s to reach a second predetermined temperature comprised in a range from 90°C - 110°C relative to the outer surface of said semi-finished product <REFNUM> .
The learning device of Claim 8, wherein the processor further performs processes of: (v) generating or supporting another device to generate at least one existence loss which represents whether one of GT lanes is present near each of the estimated lanes, based on whether coordinates of said one of the GT lanes is present within a certain number of pixels in either direction parallel to an x-axis from respective coordinates of each of the estimated lanes; (vi) if said one of the GT lanes is determined as present near each of the estimated lanes, generating or supporting another device to generate at least one distance regression loss by referring to each of distances x - f ( y | θ k ) between each of pixels ( f ( y | θ k ), y ) of each of the estimated lanes and each of pixels (x ,y) of each corresponding one among the GT lanes; and (vii) backpropagating or supporting another device to backpropagate the existence loss and the distance regression loss, to thereby optimize the device parameters of the CNN. (v) generating or supporting another device to generate at least one existence loss which represents whether one of GT lanes is present near each of the estimated lanes, based on whether coordinates of said one of the GT lanes is present within a certain number of pixels in either direction parallel to an x-axis from respective coordinates of each of the estimated lanes; (vi) if said one of the GT lanes is determined as present near each of the estimated lanes, generating or supporting another device to generate at least one distance regression loss by referring to each of distances x - f ( y | θ k ) between each of pixels ( f ( y | θ k ), y ) of each of the estimated lanes and each of pixels (x ,y) of each corresponding one among the GT lanes; and (vii) backpropagating or supporting another device to backpropagate the existence loss and the distance regression loss, to thereby optimize the device parameters of the CNN.
The fluid injector system of claim 2, wherein the user interface is configured to display at least one of: a total volume of the at least one of the first fluid and the second fluid to be injected according to the diagnostic injection protocol; and for each of the one or more phases of the diagnostic injection protocol, a particular volume of the at least one of the first fluid and the second fluid therein and a flow rate at which the particular volume is to be injected into the patient during administration thereof. a total volume of the at least one of the first fluid and the second fluid to be injected according to the diagnostic injection protocol; and for each of the one or more phases of the diagnostic injection protocol, a particular volume of the at least one of the first fluid and the second fluid therein and a flow rate at which the particular volume is to be injected into the patient during administration thereof.
The thrombectomy catheter of any one of claims 1-9, wherein the elongated member comprises a solid core wire <REFNUM> .
The memory device <REFNUM> of any of claims 9-11, comprising a three-dimensional, 3D, cross-point array structure.
The process of claim 1, wherein the electrically conductive layer comprises a material suitable for use as a positive electrode current collector layer or a negative electrode current collector.
The process according to either of claims 4 or 5, wherein the linking group to Z is a single bond or an ether group -CH 2 -O- or an ester group -CH 2 -O-C(=O)-.
The epicardial pacing lead device <REFNUM> of any of claims 1 to 4, wherein distal end portions of the first shaft and the second shaft are interconnected by the flexible elongate spacing member <REFNUM> .
The system of claim 13, wherein the BOP stack connection assembly <REFNUM> comprises: a connection assembly <REFNUM> attached to a pipe string <REFNUM> extending from the lifting device <REFNUM> or a first rope <REFNUM> extending from the lifting device <REFNUM> , wherein the connection assembly <REFNUM> is pivotally coupled to the control pod exchange device <REFNUM> ; a winch <REFNUM> coupled to the housing <REFNUM> ; a BOP stack connector <REFNUM> moveably coupled to the housing <REFNUM> , wherein the BOP stack connector <REFNUM> is configured to be secured to the BOP stack <REFNUM> ; a second rope <REFNUM> configured to be paid in and paid out from the winch <REFNUM> , wherein the second rope <REFNUM> extends over a sheave <REFNUM> of the connection assembly <REFNUM> and has an end coupled to the BOP stack connector <REFNUM> . a connection assembly <REFNUM> attached to a pipe string <REFNUM> extending from the lifting device <REFNUM> or a first rope <REFNUM> extending from the lifting device <REFNUM> , wherein the connection assembly <REFNUM> is pivotally coupled to the control pod exchange device <REFNUM> ; a winch <REFNUM> coupled to the housing <REFNUM> ; a BOP stack connector <REFNUM> moveably coupled to the housing <REFNUM> , wherein the BOP stack connector <REFNUM> is configured to be secured to the BOP stack <REFNUM> ; a second rope <REFNUM> configured to be paid in and paid out from the winch <REFNUM> , wherein the second rope <REFNUM> extends over a sheave <REFNUM> of the connection assembly <REFNUM> and has an end coupled to the BOP stack connector <REFNUM> .
Method according to claim 8, wherein the method further comprises the following steps: unrolling part of the cable <REFNUM> from the two rollers <REFNUM> ; determining the length of the unrolled part of the cable <REFNUM> ; detecting the change in position of the second roller <REFNUM> while unrolling the part of the cable <REFNUM> ; and determining the number of loops of the cable <REFNUM> around the two rollers <REFNUM> on the basis of the length of the unrolled part of the cable <REFNUM> and the resulting change in position of the second roller <REFNUM> . unrolling part of the cable <REFNUM> from the two rollers <REFNUM> ; determining the length of the unrolled part of the cable <REFNUM> ; detecting the change in position of the second roller <REFNUM> while unrolling the part of the cable <REFNUM> ; and determining the number of loops of the cable <REFNUM> around the two rollers <REFNUM> on the basis of the length of the unrolled part of the cable <REFNUM> and the resulting change in position of the second roller <REFNUM> .
Boiler for the combustion of fuel <REFNUM> , in particular pellets, having a combustion chamber <REFNUM> , having a fuel feed <REFNUM> for charging the combustion chamber <REFNUM> with fuel <REFNUM> , wherein the fuel feed <REFNUM> comprises an intermediate container <REFNUM> for the fuel <REFNUM> , a burn-back safety device (4.1, 4.2) with a shut-off element <REFNUM> , in particular slide valve (12. 1), and a drive <REFNUM> for actuating the shut-off element <REFNUM> , and having an air supply <REFNUM> which opens into the combustion chamber <REFNUM> and comprises at least one device <REFNUM> with a drivable actuating element <REFNUM> , in particular an air slide valve (11.1), for air quantity adjustment, characterized in that the drive <REFNUM> of the burn-back safety device (4.1) also actuates the actuating element <REFNUM> of the device <REFNUM> for the air quantity adjustment.
Laundry care appliance <REFNUM> according to one of the preceding claims, characterised in that the volume recording facility <REFNUM> is embodied to record a volume (161-1) of the washing liquid recirculated through the liquid pipe <REFNUM> by the pump <REFNUM> during the time segment <REFNUM> in order to record the volume (161-1) of the washing liquid not bound to the laundry.
Method according to one of claims 1 to 4, wherein the spaces <REFNUM> above and below the membrane <REFNUM> are formed between the bottom of the housing recess <REFNUM> and a preparation cover <REFNUM> suitable for closing the housing recess.
Paper machine according to one of the preceding claims, wherein the forming section <REFNUM> is designed as a fourdrinier wire.
The airway adapter <REFNUM> according to any one of Claims 9 to 12, wherein the second cylindrical portion <REFNUM> has a second proximal end portion <REFNUM> that is nearer to the first cylindrical portion <REFNUM> , and a second distal end portion <REFNUM> that is farther from the first cylindrical portion <REFNUM> ; and a dimension of the fitting portion <REFNUM> in the radial direction of the second cylindrical portion <REFNUM> is smaller in value at the second proximal end portion <REFNUM> than at the second distal end portion <REFNUM> . the second cylindrical portion <REFNUM> has a second proximal end portion <REFNUM> that is nearer to the first cylindrical portion <REFNUM> , and a second distal end portion <REFNUM> that is farther from the first cylindrical portion <REFNUM> ; and a dimension of the fitting portion <REFNUM> in the radial direction of the second cylindrical portion <REFNUM> is smaller in value at the second proximal end portion <REFNUM> than at the second distal end portion <REFNUM> .
A device <REFNUM> according to any one of the preceding claims, characterized in that said thrust element <REFNUM> is positionable between said operating position and said idle position by rotation.
Method for managing an electric motor according to Claim 1, wherein short-circuiting of the phases (pH) of the electric motor <REFNUM> is performed by means of an electric switch of an inverter <REFNUM> supplying a supply voltage to the electric motor <REFNUM> .
The method of claim 1, further comprising producing a plurality of polymer scaffold compositions and combining the plurality of polymer scaffold compositions to form a multilayer construct.
An industrial automation device <REFNUM> according to any preceding claim, wherein the operational information comprises one or more measured values at least for temperature and/or vibration associated with the industrial asset, and the internal technical information comprises at least a value for an output current from the industrial automation device <REFNUM> to the industrial asset.
The system according to claim 1, wherein said first valve is configured to completely block said by-pass duct in said second operating condition.
Conveying device <REFNUM> according to any one of the preceding claims, wherein the conveyor belt support <REFNUM> comprises a slider bed made up of a plurality of slider beds <REFNUM> , each slider bed <REFNUM> being fitted on a plurality of crossmembers <REFNUM> .
The method of any of claims 1-5, wherein determining one or more confidence values associated with the one or more user status options comprises: evaluating a probability associated with each of the user status option; and assigning a confidence value to each of the user status options based on the probability associated with the corresponding user status option. evaluating a probability associated with each of the user status option; and assigning a confidence value to each of the user status options based on the probability associated with the corresponding user status option.
A system <REFNUM> for transmission of quantum information for quantum error correction, comprising: an ancilla qubit chip <REFNUM> comprising a plurality of ancilla qubits <REFNUM> ; a data qubit chip <REFNUM> spaced apart from said ancilla qubit chip <REFNUM> , said data qubit chip <REFNUM> comprising a plurality of data qubits <REFNUM> ; an interposer <REFNUM> coupled to said ancilla qubit chip <REFNUM> and said data qubit chip, said interposer <REFNUM> comprising a dielectric material <REFNUM> ; and a plurality of superconducting resonators each comprising one of the plurality of superconducting structures <REFNUM> ; wherein each respective superconducting structure of the plurality of superconducting structures <REFNUM> forms a part of a respective superconducting resonator having a third frequency; wherein the respective superconducting structure <REFNUM> extends from a respective data qubit, having a first frequency, of the plurality of data qubits <REFNUM> to a respective ancilla qubit, having a second frequency, of the plurality of ancilla qubits <REFNUM> ; wherein the third frequency is detuned from the first and second frequency to prevent real photon transfer between the respective data qubit <REFNUM> and the respective ancilla qubit <REFNUM> ; wherein the respective superconducting structure enables transmission of quantum information between the respective data qubit on said data qubit chip <REFNUM> and the respective ancilla qubit on said ancilla qubit chip <REFNUM> via virtual photons for quantum error correction. an ancilla qubit chip <REFNUM> comprising a plurality of ancilla qubits <REFNUM> ; a data qubit chip <REFNUM> spaced apart from said ancilla qubit chip <REFNUM> , said data qubit chip <REFNUM> comprising a plurality of data qubits <REFNUM> ; an interposer <REFNUM> coupled to said ancilla qubit chip <REFNUM> and said data qubit chip, said interposer <REFNUM> comprising a dielectric material <REFNUM> ; and a plurality of superconducting resonators each comprising one of the plurality of superconducting structures <REFNUM> ; wherein each respective superconducting structure of the plurality of superconducting structures <REFNUM> forms a part of a respective superconducting resonator having a third frequency; wherein the respective superconducting structure <REFNUM> extends from a respective data qubit, having a first frequency, of the plurality of data qubits <REFNUM> to a respective ancilla qubit, having a second frequency, of the plurality of ancilla qubits <REFNUM> ; wherein the third frequency is detuned from the first and second frequency to prevent real photon transfer between the respective data qubit <REFNUM> and the respective ancilla qubit <REFNUM> ; wherein the respective superconducting structure enables transmission of quantum information between the respective data qubit on said data qubit chip <REFNUM> and the respective ancilla qubit on said ancilla qubit chip <REFNUM> via virtual photons for quantum error correction.
A speech coding method for encoding an input speech signal by searching for a pulse using an algebraic codebook , the algebraic codebook being formed with a plurality of code vectors, the speech coding method comprising: calculating a first parameter related to a perceptual characteristic and a second parameter related to a spectrum characteristic using the input speech signal, and generating a target vector to be encoded using the first parameter and the second parameter; generating a third parameter related to both the perceptual characteristic and the spectrum characteristic using the first parameter and the second parameter; and a vector quantization method of claim 7, wherein the parameter related to the speech spectrum characteristic is the third parameter. calculating a first parameter related to a perceptual characteristic and a second parameter related to a spectrum characteristic using the input speech signal, and generating a target vector to be encoded using the first parameter and the second parameter; generating a third parameter related to both the perceptual characteristic and the spectrum characteristic using the first parameter and the second parameter; and a vector quantization method of claim 7, wherein the parameter related to the speech spectrum characteristic is the third parameter.
The method of any preceding claim, wherein the radiotherapy radiation source is located diametrically opposite the radiotherapy radiation detector.
The implant of claim 2, wherein the head portion <REFNUM> has an inner edge, with an included angle (a) defined between the inner edge of the head portion <REFNUM> of the connection plug <REFNUM> along the axial line of the tightening ring <REFNUM> , and the included angle ranges from 45 to 85 degrees.
A computer readable storage medium in which computer program according to claim 15 is stored.
The OLED <REFNUM> according to claim 10, wherein the OLED <REFNUM> comprises an anode <REFNUM> , a hole injection layer <REFNUM> , optional a hole transport layer <REFNUM> , an emission layer <REFNUM> , optional a hole blocking layer <REFNUM> , optional an electron transport layer <REFNUM> , optional an electron injection layer <REFNUM> , and a cathode <REFNUM> , wherein the layers are arranged in that order and sandwiched between the anode <REFNUM> and the cathode <REFNUM> .
The distributed antenna system <REFNUM> of claim 1, wherein each of the multiple downlink radio frequency signal sets includes one channel of downlink radio frequency signal for SISO.
System according to one of claims 7 to 11, characterized in that said second layer <REFNUM> of the slab has a thickness comprised between 0.3 mm and 3 mm.
A wall of a structure comprising moulded cementious material, wherein said wall comprises a first portion and a second portion, wherein the first portion is formed by a panel <REFNUM> of a polymeric material, wherein said panel <REFNUM> has a passageway formed therein, said first portion being coupled to said second portion of the wall <REFNUM> , the second portion of the wall <REFNUM> consisting of the moulded cementitious material, characterized in that the panel <REFNUM> has been manufactured from thermoplastic materials and has a structure, which is comprised of elongated hollow profiles, with straight and parallel central axes, the profiles being laterally welded together to form a double-walled panel
Process according to claim 2, wherein the etching is performed for a duration of 350 seconds at least, preferably from 350 seconds to 540 seconds, more preferably from 360 to 480 seconds, and most preferably from 360 seconds to 420 seconds.
The hearing device of claim 2, wherein the settings comprise a classification of the music content.
The method according to claim 3, wherein the polymer models are disposed between a pair of the filler models.
The method of any one of claims 1 to 7, wherein the establishing the connection to the base station comprises establishing a connection to the base station for an associated DL and an associated uplink, UL <REFNUM> ; and the method further comprises: detecting a second sPDCCH for scheduling an UL transmission via a third TTI length <REFNUM> , wherein the UE monitors and detects the second sPDCCH based at least in part on the sTTI pattern; and transmitting at least a scheduled UL transmission on at least an associated UL channel, wherein for a number of sPDCCHs within the first TTI on the associated DL, a plurality of associated UL channels having the at least the scheduled UL transmission occur within the another first TTI on the associated UL <REFNUM> . detecting a second sPDCCH for scheduling an UL transmission via a third TTI length <REFNUM> , wherein the UE monitors and detects the second sPDCCH based at least in part on the sTTI pattern; and transmitting at least a scheduled UL transmission on at least an associated UL channel, wherein for a number of sPDCCHs within the first TTI on the associated DL, a plurality of associated UL channels having the at least the scheduled UL transmission occur within the another first TTI on the associated UL <REFNUM> .
The device of any preceding claim, further comprising a linkage assembly <REFNUM> having a first end connected to the picker <REFNUM> and a second end connected to a base <REFNUM> , wherein the linkage assembly <REFNUM> causes motion of the picker <REFNUM> or the plunger <REFNUM> in a horizontal plane and a vertical plane in response to a signal from the controller <REFNUM> .
The method of any preceding claim, wherein the method further comprises thermomechanical processing, preferably calendering the bonded multilayer web.
The method <REFNUM> of claim 4, wherein the transmitting of the indication <REFNUM> of the reception time <REFNUM> comprises at least one of: transmitting, to multiple user equipments including the user equipment <REFNUM> , a general indication of the reception time <REFNUM> using a radio resource message <REFNUM> ; or transmitting, to the user equipment <REFNUM> , a user-equipment-specific indication of the reception time <REFNUM> using a DL information message <REFNUM> . transmitting, to multiple user equipments including the user equipment <REFNUM> , a general indication of the reception time <REFNUM> using a radio resource message <REFNUM> ; or transmitting, to the user equipment <REFNUM> , a user-equipment-specific indication of the reception time <REFNUM> using a DL information message <REFNUM> .
A method implemented by a network device <REFNUM> in a communication network to protect a vehicle <REFNUM> from insertion of malicious operations, the method comprising: establishing, by a virtual vehicle entity <REFNUM> executed by the network device, a communication session with a requestor, the virtual vehicle entity operating as a proxy for the vehicle, wherein a location of the network device is in proximity to the vehicle; receiving, by the virtual vehicle entity, status information from the vehicle via a radio access network; querying, by the virtual vehicle entity, a deep learning platform with the status information and a message from the requestor; and dropping, by the virtual vehicle entity, the message from the requestor in response to the deep learning platform indicating the message is malicious. establishing, by a virtual vehicle entity <REFNUM> executed by the network device, a communication session with a requestor, the virtual vehicle entity operating as a proxy for the vehicle, wherein a location of the network device is in proximity to the vehicle; receiving, by the virtual vehicle entity, status information from the vehicle via a radio access network; querying, by the virtual vehicle entity, a deep learning platform with the status information and a message from the requestor; and dropping, by the virtual vehicle entity, the message from the requestor in response to the deep learning platform indicating the message is malicious.
The compound according to any of the preceding claims, wherein R 1 represents cyclopropyl, unsubstituted; -CH 2 -cyclopropyl, unsubstituted; phenyl, unsubstituted or mono- or disubstituted with substituents independently of one another selected from the group consisting of -F, -Cl, -Br, -CH 3 , -CF 3 , -CN, cyclopropyl and -OCH 3 , wherein phenyl is optionally annealed to a dioxolane ring by a substituent -O-CH 2 CH 2 -O-; or pyridyl, unsubstituted or mono- or disubstituted with substituents independently of one another selected from the group consisting of -F, -Cl, -Br, -CH 3 , -CF 3 , -CN, and -OCH 3 . R 1 represents cyclopropyl, unsubstituted; -CH 2 -cyclopropyl, unsubstituted; phenyl, unsubstituted or mono- or disubstituted with substituents independently of one another selected from the group consisting of -F, -Cl, -Br, -CH 3 , -CF 3 , -CN, cyclopropyl and -OCH 3 , wherein phenyl is optionally annealed to a dioxolane ring by a substituent -O-CH 2 CH 2 -O-; or pyridyl, unsubstituted or mono- or disubstituted with substituents independently of one another selected from the group consisting of -F, -Cl, -Br, -CH 3 , -CF 3 , -CN, and -OCH 3 . cyclopropyl, unsubstituted; -CH 2 -cyclopropyl, unsubstituted; phenyl, unsubstituted or mono- or disubstituted with substituents independently of one another selected from the group consisting of -F, -Cl, -Br, -CH 3 , -CF 3 , -CN, cyclopropyl and -OCH 3 , wherein phenyl is optionally annealed to a dioxolane ring by a substituent -O-CH 2 CH 2 -O-; or pyridyl, unsubstituted or mono- or disubstituted with substituents independently of one another selected from the group consisting of -F, -Cl, -Br, -CH 3 , -CF 3 , -CN, and -OCH 3 .
The battery <REFNUM> according to any one of claims 1-8, wherein the fixing portion <REFNUM> is further configured to fix the first end cover <REFNUM> and the second end cover <REFNUM> .
The apparatus of any previous claim, wherein the indication of the instrument current is obtained utilizing a component configured to provide an inductive or capacitive measurement.
Device according to at least one of the preceding claims, characterized in that the heating block consists essentially of aluminum.
The flywheel energy storage device of claim 2, wherein each set of helical wraps has a radially oriented, layered composite shell.
The vapor compression system <REFNUM> of claim 4 or 5, wherein the working fluid from the inductor portion <REFNUM> is transferred to the compressor <REFNUM> .
The dialysate regenerator <REFNUM> of any of claims 1 to 9, wherein the dialysate regenerator <REFNUM> comprises one reversible retainer <REFNUM> positioned upstream of the purification means <REFNUM> in a first direction of the dialysate flow path through the reversible retainer <REFNUM> and the same reversible retainer <REFNUM> positioned downstream of the purification means <REFNUM> in a second direction of the dialysate flow path, wherein the second direction of the dialysate flow path through the reversible retainer <REFNUM> is reverse to the first direction of the dialysate flow path through the reversible retainer <REFNUM> .
The system of claim 10, comprising the processor configured to: dividing the second task into a plurality of sub-tasks configured to fit within a number of peripheral regions associated with the determined number of pages; and reconstruct at least a portion of the second task based on the plurality of sub-tasks. dividing the second task into a plurality of sub-tasks configured to fit within a number of peripheral regions associated with the determined number of pages; and reconstruct at least a portion of the second task based on the plurality of sub-tasks.
The system of any of claims 7 to 8, wherein hash values are provided using a hash function.
The device <REFNUM> of claim 5 or 6, wherein the groove <REFNUM> comprises a circumferential part and an axial part.
Device <REFNUM> according to any of claims 1-3, wherein the frangible joint <REFNUM> of the connecting element <REFNUM> with the base plate <REFNUM> ; and the frangible joint <REFNUM> of the connecting element <REFNUM> with the wedge receiving plate <REFNUM> ; are separated by a distance in the range of 4.0-5.0 cm, in the range of 6.0-7.0 cm, in the range of 9.0-10.0 cm or in the range of 19.0-20.0 cm. the frangible joint <REFNUM> of the connecting element <REFNUM> with the base plate <REFNUM> ; and the frangible joint <REFNUM> of the connecting element <REFNUM> with the wedge receiving plate <REFNUM> ; are separated by a distance in the range of 4.0-5.0 cm, in the range of 6.0-7.0 cm, in the range of 9.0-10.0 cm or in the range of 19.0-20.0 cm.
The test panel claim 1 or claim 2, wherein the solid carrier is a well of a multiwell plate, a bead, an electrical sensor, a chemical sensor, a microchip or an adsorptive film.
The composition according to any one of claims 3 to 6 wherein the weight ratio of silicone resin to the non-volatile silicone oil is in the range of 2:5 to 50:1.
Arc mitigation apparatus according to claim 6, wherein the merging unit comprises a stored energy unit from the solar-cell into the unit and wherein activation of the merging unit is configured to release energy to activate the arc mitigation device.
The printer <REFNUM> according to any one of claims 9-10, characterized in that the contact surface <REFNUM> is designed, when printing the cable marker strip <REFNUM> , to push a labeling surface <REFNUM> of the cable marker <REFNUM> in a pressure direction (y) against a print head <REFNUM> of the printer <REFNUM> with a force, in particular a spring force.
The system of claim 1, wherein the hub <REFNUM> further includes an inflation fluid channel <REFNUM> sized and shaped to deliver the inflation fluid from an inlet in the hub to the opening in the hub for providing the inflation fluid to the soft robotic actuator.
The magnetoresistive stack of claim 1, wherein the first ferromagnetic layer <REFNUM> , the second ferromagnetic layer <REFNUM> , and the transition layer <REFNUM> each comprise approximately 1 percent to approximately 15 atomic percent of the auxiliary additional metal; and the transition layer <REFNUM> includes more of the auxiliary additional metal, by atomic percent, than the first ferromagnetic layer.
The apparatus according to claim 8, wherein the determining module <REFNUM> comprises: a block determining unit, configured to determine a plurality of first blocks in the blocks in the target blockchain, the plurality of first blocks being configured to store the voting transaction data of the node devices; and a representative node device determining unit, configured to determine a preset quantity of representative node devices in the blockchain system according to the voting transaction data stored in the plurality of first blocks. a block determining unit, configured to determine a plurality of first blocks in the blocks in the target blockchain, the plurality of first blocks being configured to store the voting transaction data of the node devices; and a representative node device determining unit, configured to determine a preset quantity of representative node devices in the blockchain system according to the voting transaction data stored in the plurality of first blocks.
Coupling device according to any of claims 1 to 6, characterised in that the drive sprocket <REFNUM> is designed annular and self-contained and is located at the outer circumferential surface <REFNUM> of the actuating sleeve <REFNUM> while being oriented coaxially therewith.
Device <REFNUM> for supporting a treatment with pulsed electric fields for wound healing and/or for inactivating microorganisms, comprising - an electrical energy storage <REFNUM> , - a pulse generator <REFNUM> for providing electrical excitation pulses, - a transformer <REFNUM> for providing high-frequency electrical pulses <REFNUM> at an output side <REFNUM> , wherein a first terminal of an input side <REFNUM> of the transformer <REFNUM> is connected to the pulse generator <REFNUM> , and - a treatment instrument <REFNUM> comprising a body <REFNUM> made of an electrically insulating material and an electrode <REFNUM> arranged inside the body <REFNUM> , wherein a gas or gas mixture is accommodated inside the body <REFNUM> and the treatment instrument <REFNUM> is configured for gas discharge upon electrical excitation, wherein a first end <REFNUM> of the treatment instrument <REFNUM> is configured for coupling to a first terminal of the output side <REFNUM> of the transformer <REFNUM> , wherein a second end <REFNUM> of the treatment instrument <REFNUM> is configured to contact surfaces and/or biological tissue, and that a second terminal of the output side <REFNUM> of the transformer <REFNUM> is connected to a second terminal of an input side <REFNUM> of the transformer <REFNUM> , wherein the transformer <REFNUM> and the pulse generator <REFNUM> are configured in such a way that the high-frequency electrical pulses <REFNUM> have a pulse repetition rate in the range from 100 Hz to 400 Hz, wherein the treatment instrument <REFNUM> is configured to conduct the generated high-frequency electric pulses <REFNUM> or their electric fields to an object to be treated or to an organic or biological material to be treated, characterized in that said body <REFNUM> is a closed body <REFNUM> , wherein the device comprises a housing and a housing shield <REFNUM> to which said second terminal of the output side <REFNUM> of the transformer <REFNUM> is connected, wherein the housing shield <REFNUM> is electrically insulated from the outside world by a housing of the device <REFNUM> and thus is configured as a floating ground, wherein the pulse generator <REFNUM> is configured in such a way that the high-frequency electrical pulses <REFNUM> have a frequency in the range from 10 kHz to 100 kHz. - an electrical energy storage <REFNUM> , - a pulse generator <REFNUM> for providing electrical excitation pulses, - a transformer <REFNUM> for providing high-frequency electrical pulses <REFNUM> at an output side <REFNUM> , wherein a first terminal of an input side <REFNUM> of the transformer <REFNUM> is connected to the pulse generator <REFNUM> , and - a treatment instrument <REFNUM> comprising a body <REFNUM> made of an electrically insulating material and an electrode <REFNUM> arranged inside the body <REFNUM> , wherein a gas or gas mixture is accommodated inside the body <REFNUM> and the treatment instrument <REFNUM> is configured for gas discharge upon electrical excitation, wherein a first end <REFNUM> of the treatment instrument <REFNUM> is configured for coupling to a first terminal of the output side <REFNUM> of the transformer <REFNUM> , wherein a second end <REFNUM> of the treatment instrument <REFNUM> is configured to contact surfaces and/or biological tissue, and that a second terminal of the output side <REFNUM> of the transformer <REFNUM> is connected to a second terminal of an input side <REFNUM> of the transformer <REFNUM> , wherein the transformer <REFNUM> and the pulse generator <REFNUM> are configured in such a way that the high-frequency electrical pulses <REFNUM> have a pulse repetition rate in the range from 100 Hz to 400 Hz, wherein the treatment instrument <REFNUM> is configured to conduct the generated high-frequency electric pulses <REFNUM> or their electric fields to an object to be treated or to an organic or biological material to be treated, characterized in that said body <REFNUM> is a closed body <REFNUM> , wherein the device comprises a housing and a housing shield <REFNUM> to which said second terminal of the output side <REFNUM> of the transformer <REFNUM> is connected, wherein the housing shield <REFNUM> is electrically insulated from the outside world by a housing of the device <REFNUM> and thus is configured as a floating ground, wherein the pulse generator <REFNUM> is configured in such a way that the high-frequency electrical pulses <REFNUM> have a frequency in the range from 10 kHz to 100 kHz.
The system as recited in any preceding claim, wherein the plurality of RFID readers includes RFID readers <REFNUM> positioned to read RFID tags in rolling luggage items <REFNUM> in an aisle <REFNUM> of the aircraft cabin.
A computer-implemented method according to any one of claims 5 to 7, further comprising performing an exclusive or XOR operation of the recovery password and the data associated with the private key shares; and/or wherein the mapping data is signed using private key Sk and mined into the proof-of-work blockchain on which the account resides. further comprising performing an exclusive or XOR operation of the recovery password and the data associated with the private key shares; and/or wherein the mapping data is signed using private key Sk and mined into the proof-of-work blockchain on which the account resides.
The modular track connection <REFNUM> according to one of the preceding claims, characterized in that the floating axle <REFNUM> passes completely through the spacer body <REFNUM> .
The semiconductor device according to claim 1, further comprising: an electrode pad <REFNUM> for bump connection formed on the first semiconductor substrate <REFNUM> and configured to be connected to the bump <REFNUM> ; and an electrode pad <REFNUM> for wire bonding formed on the first semiconductor substrate <REFNUM> and configured to be connected to a wire bonding, wherein a ratio of a distance <REFNUM> between a side of an opening portion <REFNUM> for wire bonding closest to the lens material <REFNUM> and a side of the lens material <REFNUM> closest to the opening portion <REFNUM> for wire bonding to a size <REFNUM> of the opening portion <REFNUM> for wire bonding is smaller than a ratio of a distance <REFNUM> between a side of an opening portion <REFNUM> for a bump <REFNUM> closest to the lens material <REFNUM> and a side of the lens material <REFNUM> closest to the opening portion <REFNUM> for a bump to a size <REFNUM> of the opening portion <REFNUM> for a bump <REFNUM> . an electrode pad <REFNUM> for bump connection formed on the first semiconductor substrate <REFNUM> and configured to be connected to the bump <REFNUM> ; and an electrode pad <REFNUM> for wire bonding formed on the first semiconductor substrate <REFNUM> and configured to be connected to a wire bonding, wherein a ratio of a distance <REFNUM> between a side of an opening portion <REFNUM> for wire bonding closest to the lens material <REFNUM> and a side of the lens material <REFNUM> closest to the opening portion <REFNUM> for wire bonding to a size <REFNUM> of the opening portion <REFNUM> for wire bonding is smaller than a ratio of a distance <REFNUM> between a side of an opening portion <REFNUM> for a bump <REFNUM> closest to the lens material <REFNUM> and a side of the lens material <REFNUM> closest to the opening portion <REFNUM> for a bump to a size <REFNUM> of the opening portion <REFNUM> for a bump <REFNUM> .
A method <REFNUM> as claimed in any of claims 1 to 5, wherein the predefined clinical view comprises one or more of: an abdominal view; a four chamber view; a left ventricular outflow tract view; a right ventricular outflow tract view; a three vessel view; a three vessel trachea view; an aortic arch view; and a ductal arch view. an abdominal view; a four chamber view; a left ventricular outflow tract view; a right ventricular outflow tract view; a three vessel view; a three vessel trachea view; an aortic arch view; and a ductal arch view.
The electrolyte composition of any one of claims 1 to 7, wherein the amount of said additional carbonate ranges from 0.1 to 10.0 wt.%, relatively to the total weight of said electrolyte composition.
Regenerative brake system according to Claim 1, the control apparatus <REFNUM> being designed, if a current practicability of the regenerative mode of the brake system is delayed or interrupted for a time interval (Δt) of at most two seconds, to actuate at least the valves <REFNUM> of the two brake circuits <REFNUM> in such a way that, at least if the requested setpoint vehicle deceleration (a driver ) lies below a predefined limit deceleration (a threshold ), the first hydraulic vehicle deceleration (a hyd1 ) which is brought about by means of the first wheel brake cylinders <REFNUM> of the two brake circuits <REFNUM> can be increased to the setpoint vehicle deceleration (a driver ), whereas a brake pressure (p2) in the each second wheel brake cylinder <REFNUM> of the two brake circuits <REFNUM> is at most equal to the response pressure of the accumulator chamber <REFNUM> of the respective brake circuit <REFNUM> .
The light emitting device of any one of the preceding claims, wherein the light emitting structure layer <REFNUM> has an outer region <REFNUM> having a step structure with respect to the conductive support member <REFNUM> .
Forge-proof document according to any of the claims 1 to 4, characterized in that - on the front side, the first and second image information of the corresponding security features coincide, - wherein preferably the second image information of the front side coincides with the second image information of the back side and with the first image information of the forge-proof document. - on the front side, the first and second image information of the corresponding security features coincide, - wherein preferably the second image information of the front side coincides with the second image information of the back side and with the first image information of the forge-proof document.
The vehicle frame as claimed in claim 1, wherein the outer covering plate <REFNUM> comprises an upper covering plate <REFNUM> and a lower covering plate <REFNUM> , the upper covering plate <REFNUM> covering the upper side beam <REFNUM> , and the lower covering plate <REFNUM> covering the lower side beam <REFNUM> .
Method of any one of the preceding claims, wherein the aqueous solution is drawn from a fermentation broth <REFNUM> , and comprising recycling the aqueous solution <REFNUM> to the fermentation broth following the extracting step.
The passive automotive coolant liquid deaerator unit <REFNUM> of claim 1, wherein the lowest edge <REFNUM> of the opening <REFNUM> of the chamber liquid inlet <REFNUM> is vertically higher than the highest edge <REFNUM> of the opening <REFNUM> of the chamber liquid outlet <REFNUM> , whereas the baffle plate <REFNUM> is horizontally positioned between the lowest edge <REFNUM> of the chamber liquid inlet opening <REFNUM> and the highest edge <REFNUM> of the chamber liquid outlet opening <REFNUM> and is lying in a horizontal plane (XY).
A method performed by a network node <REFNUM> for resuming a connection of a wireless communication device <REFNUM> after the wireless communication device <REFNUM> was suspended to a dormant state while the wireless communication device <REFNUM> was operating in dual connectivity with a Master Cell Group, MCG, with a first network node and a Secondary Cell Group, SCG, with a second network node, the method comprising: sending <REFNUM> , to the wireless communication device <REFNUM> , a connection resume message with an indication to restore the SCG of the wireless communication device <REFNUM> , the connection resume message comprising information that is mandatory when the connection resume message comprises an indication to restore the SCG, where the information that is mandatory comprises reconfigurationWithSync for an SCG or mobilityControlInfoSCG.
Guide element <REFNUM> according to any of the preceding claims, characterized in that the guide element <REFNUM> has a recess <REFNUM> which is not connected to the guide slot <REFNUM> , the recess <REFNUM> being used to attach the guide element <REFNUM> to a support of a workstation <REFNUM> of a ring spinning machine.