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A device for starting an application program, the device being applied to a terminal comprising a sliding cover <REFNUM> and a device body <REFNUM> slidably connected with each other, and the device comprising: a first detecting module <REFNUM> , configured to: during a running process of a target application program, detect a first movement of the sliding cover <REFNUM> relative to the device body <REFNUM> , and obtain a first sliding information of the sliding cover <REFNUM> based on the first movement when a preset target interface of the target application program is displayed; a first starting module <REFNUM> , configured to start a first application program when the first sliding information indicates that the sliding cover <REFNUM> performs a preset sliding movement; a first displaying module <REFNUM> , configured to display a first target information of the first application program in a suspension window which is popped up in the preset target interface of the target application program; a second detecting module <REFNUM> , configured to detect a second movement of the sliding cover <REFNUM> relative to the device body <REFNUM> , and obtain a second sliding information of the sliding cover <REFNUM> based on the second movement; an exiting module <REFNUM> , configured to exit the first application program when the second sliding information indicates that the sliding cover <REFNUM> performs a sliding movement different from the preset sliding movement; an outputting module <REFNUM> , configured to output an inquiry information after the first application program is exited, wherein the inquiry information is to inquire whether a user starts a second application program, and the second application program is associated with the first application program, and wherein the terminal performs statistics on historic usage information of each application program used immediately following the exit of the first application program when the preset target interface of the target application program is displayed in a historic period, and takes an application program with the historic usage information satisfying a preset usage condition as the second application program; a second starting module <REFNUM> , configured to start the second application program when an instruction from the user to confirm starting the second application program is received; and a second displaying module <REFNUM> , configured to display a second target information of the second application program. a first detecting module <REFNUM> , configured to: during a running process of a target application program, detect a first movement of the sliding cover <REFNUM> relative to the device body <REFNUM> , and obtain a first sliding information of the sliding cover <REFNUM> based on the first movement when a preset target interface of the target application program is displayed; a first starting module <REFNUM> , configured to start a first application program when the first sliding information indicates that the sliding cover <REFNUM> performs a preset sliding movement; a first displaying module <REFNUM> , configured to display a first target information of the first application program in a suspension window which is popped up in the preset target interface of the target application program; a second detecting module <REFNUM> , configured to detect a second movement of the sliding cover <REFNUM> relative to the device body <REFNUM> , and obtain a second sliding information of the sliding cover <REFNUM> based on the second movement; an exiting module <REFNUM> , configured to exit the first application program when the second sliding information indicates that the sliding cover <REFNUM> performs a sliding movement different from the preset sliding movement; an outputting module <REFNUM> , configured to output an inquiry information after the first application program is exited, wherein the inquiry information is to inquire whether a user starts a second application program, and the second application program is associated with the first application program, and wherein the terminal performs statistics on historic usage information of each application program used immediately following the exit of the first application program when the preset target interface of the target application program is displayed in a historic period, and takes an application program with the historic usage information satisfying a preset usage condition as the second application program; a second starting module <REFNUM> , configured to start the second application program when an instruction from the user to confirm starting the second application program is received; and a second displaying module <REFNUM> , configured to display a second target information of the second application program.
A semiconductor device comprising: a first electrode; a second electrode apart from the first electrode; and a phase change layer between the first electrode and the second electrode, the phase change layer including a quasicrystalline material, the quasicrystalline material comprising: a polyhedral quasicrystalline element, the polyhedral quasicrystalline element having one or more of a 2-fold axis of symmetry, a 3-fold axis of symmetry, a 5-fold axis of symmetry, or a higher-fold axes of symmetry, the higher-fold axis of symmetry being greater than the 5-fold axis of symmetry, wherein the polyhedral quasicrystalline element having one of pentagonal, octagonal, decagonal, dodecagonal, icohsahedral, and triacontahedral polyhedron, the quasicrystalline material being capable of a phase change between a quasicrystalline phase and an approximant crystalline phase, the approximant crystalline phase having a further regular atom arrangement than an atom arrangement of the quasicrystalline phase, and the atom arrangement of the quasicrystalline phase being arranged quasiperiodically; characterised in that the phase of the phase change layer is configured to change between the quasicrystalline phase and the approximant crystalline phase in response to an electric signal applied to the phase change layer through the first electrode and second electrode. a first electrode; a second electrode apart from the first electrode; and a phase change layer between the first electrode and the second electrode, the phase change layer including a quasicrystalline material, the quasicrystalline material comprising: a polyhedral quasicrystalline element, the polyhedral quasicrystalline element having one or more of a 2-fold axis of symmetry, a 3-fold axis of symmetry, a 5-fold axis of symmetry, or a higher-fold axes of symmetry, the higher-fold axis of symmetry being greater than the 5-fold axis of symmetry, wherein the polyhedral quasicrystalline element having one of pentagonal, octagonal, decagonal, dodecagonal, icohsahedral, and triacontahedral polyhedron, the quasicrystalline material being capable of a phase change between a quasicrystalline phase and an approximant crystalline phase, the approximant crystalline phase having a further regular atom arrangement than an atom arrangement of the quasicrystalline phase, and the atom arrangement of the quasicrystalline phase being arranged quasiperiodically; characterised in that the phase of the phase change layer is configured to change between the quasicrystalline phase and the approximant crystalline phase in response to an electric signal applied to the phase change layer through the first electrode and second electrode. a polyhedral quasicrystalline element, the polyhedral quasicrystalline element having one or more of a 2-fold axis of symmetry, a 3-fold axis of symmetry, a 5-fold axis of symmetry, or a higher-fold axes of symmetry, the higher-fold axis of symmetry being greater than the 5-fold axis of symmetry, wherein the polyhedral quasicrystalline element having one of pentagonal, octagonal, decagonal, dodecagonal, icohsahedral, and triacontahedral polyhedron, the quasicrystalline material being capable of a phase change between a quasicrystalline phase and an approximant crystalline phase, the approximant crystalline phase having a further regular atom arrangement than an atom arrangement of the quasicrystalline phase, and the atom arrangement of the quasicrystalline phase being arranged quasiperiodically; characterised in that the phase of the phase change layer is configured to change between the quasicrystalline phase and the approximant crystalline phase in response to an electric signal applied to the phase change layer through the first electrode and second electrode.
The infusion set of claim 1, wherein said catheter <REFNUM> comprises a splined lumen <REFNUM> wherein said spline <REFNUM> comprises one of a linear axis and a helical axis.
An interatrial shunt device comprising an apparatus according to any preceding claim, wherein the conformable mesh layer further comprises a second opening, and mesh elements adapted to hold open a flow path through the interatrial septum.
The RFID reader <REFNUM> according to one of the previous claims, wherein the processor <REFNUM> is configured to determine a distance of the at least one RFID tag (12a to 12d) as motion parameter; or wherein the processor <REFNUM> is configured to determine a distance of the at least one RFID tag (12a to 12d) as motion parameter based on a determined slope of a Doppler shift change of the time; and/or wherein the processor <REFNUM> is configured to determine a point of time of a passing of the at least one RFID tag (12a to 12d) and/or a position of the at least one RFID tag (12a to 12d) as motion parameter; or wherein the processor <REFNUM> is configured to determine a point of time of a passing of the at least one RFID tag (12a to 12d) and/or a position of the at least one RFID tag (12a to 12d) as motion parameter based on a determined slope of a Doppler shift change of the time describing a distance to the at least one RFID tag (12a to 12d) and/or based on a point of time on which the Doppler shift is detected; and/or wherein the processor <REFNUM> is configured to determine a direction of the at least one RFID tag (12a to 12d) as motion parameter; or wherein the processor <REFNUM> is configured to determine a direction of the at least one RFID tag (12a to 12d) as motion parameter based on the comparison of determined characteristics of the Doppler shift using at least two antennas of the RFID receiver <REFNUM> . wherein the processor <REFNUM> is configured to determine a point of time of a passing of the at least one RFID tag (12a to 12d) and/or a position of the at least one RFID tag (12a to 12d) as motion parameter; or wherein the processor <REFNUM> is configured to determine a point of time of a passing of the at least one RFID tag (12a to 12d) and/or a position of the at least one RFID tag (12a to 12d) as motion parameter based on a determined slope of a Doppler shift change of the time describing a distance to the at least one RFID tag (12a to 12d) and/or based on a point of time on which the Doppler shift is detected; and/or wherein the processor <REFNUM> is configured to determine a direction of the at least one RFID tag (12a to 12d) as motion parameter; or wherein the processor <REFNUM> is configured to determine a direction of the at least one RFID tag (12a to 12d) as motion parameter based on the comparison of determined characteristics of the Doppler shift using at least two antennas of the RFID receiver <REFNUM> .
The SSRF water heating apparatus according to one or more of the preceding claims, further comprising: at least one outlet valve <REFNUM> operatively coupled to the tank <REFNUM> , the outlet valve <REFNUM> in communication with the control processors <REFNUM> and configured to dispense at least one of air, steam, and heated water from the tank <REFNUM> by opening.
The network processing method of claim 1, wherein receiving (S402) the NG interface terminal radio capability check response message fed back by the master base station comprises: initiating, by the master base station, Xn interface 5G dual-connectivity, DC, related procedure information to a secondary base station, wherein the Xn interface 5G DC related procedure information comprises at least terminal radio capability information of a corresponding type for the secondary base station; feeding back, by the secondary base station, Xn interface 5G DC related procedure response information to the master base station, wherein the Xn interface 5G DC related procedure response information carries indication information of whether the secondary base station supports a specific service; and receiving, by the core network side, the NG interface terminal radio capability check response message fed back by the master base station according to the Xn interface 5G DC related procedure response information, wherein the NG interface terminal radio capability check response message carries indication information of whether the master base station and the secondary base station support the specific service respectively, or joint indication information of whether the master base station and the secondary base station support the specific service, preferably, the master base station initiates the Xn interface 5G DC related procedure information to the secondary base station before or after the core network side initiates the NG interface terminal radio capability check request message to the master base station. initiating, by the master base station, Xn interface 5G dual-connectivity, DC, related procedure information to a secondary base station, wherein the Xn interface 5G DC related procedure information comprises at least terminal radio capability information of a corresponding type for the secondary base station; feeding back, by the secondary base station, Xn interface 5G DC related procedure response information to the master base station, wherein the Xn interface 5G DC related procedure response information carries indication information of whether the secondary base station supports a specific service; and receiving, by the core network side, the NG interface terminal radio capability check response message fed back by the master base station according to the Xn interface 5G DC related procedure response information, wherein the NG interface terminal radio capability check response message carries indication information of whether the master base station and the secondary base station support the specific service respectively, or joint indication information of whether the master base station and the secondary base station support the specific service, preferably, the master base station initiates the Xn interface 5G DC related procedure information to the secondary base station before or after the core network side initiates the NG interface terminal radio capability check request message to the master base station.
A network node comprising the arrangement of any of claims 8 through 12.
A crosslinkable rubber composition based on at least one elastomer, the composition comprising other ingredients which include a crosslinking system and a thermoplastic polymeric phase which has at least one melting temperature Tm and which is dispersed in said at least one elastomer in the form of nodules, the crosslinkable composition comprising the product: a) of a melt reaction by thermomechanical working of a reaction mixture comprising said at least one elastomer and said other ingredients, with the exception of the crosslinking system, to obtain a precursor mixture of the crosslinkable composition, then b) of mechanical working of said precursor mixture with prior addition of the crosslinking system to obtain the crosslinkable composition, wherein: - the nodules have a weight-average greatest transverse dimension of between 10 nm and 10 μm, - said reaction comprises heating of the reaction mixture up to a maximum compounding temperature Ta which is greater than the highest of said at least one melting temperature Tm of the thermoplastic polymeric phase and which is maintained for a holding time, and - the crosslinking system comprises sulfur when said at least one elastomer is unsaturated and said thermoplastic polymeric phase comprises saturated polymer chains, and comprises a peroxide when said at least one elastomer is saturated. a) of a melt reaction by thermomechanical working of a reaction mixture comprising said at least one elastomer and said other ingredients, with the exception of the crosslinking system, to obtain a precursor mixture of the crosslinkable composition, then b) of mechanical working of said precursor mixture with prior addition of the crosslinking system to obtain the crosslinkable composition, - the nodules have a weight-average greatest transverse dimension of between 10 nm and 10 μm, - said reaction comprises heating of the reaction mixture up to a maximum compounding temperature Ta which is greater than the highest of said at least one melting temperature Tm of the thermoplastic polymeric phase and which is maintained for a holding time, and - the crosslinking system comprises sulfur when said at least one elastomer is unsaturated and said thermoplastic polymeric phase comprises saturated polymer chains, and comprises a peroxide when said at least one elastomer is saturated.
The co-rotating self-cleaning extruder with two screws and an internal baffle <REFNUM> in accordance with claim 1, characterized in that the cross-sections of the first and second screws <REFNUM> are comprised of several circle arcs of different radii, and the number of circle arcs of the first and second screw <REFNUM> are the same.
Ethernet communication device <REFNUM> according to Claim 10 or 11, characterized in that the forwarding to the media access control unit <REFNUM> is blocked until the configuration of the communication device <REFNUM> is complete.
An LED lighting circuit, comprising an input (Vbus, GND) adapted to receive an input voltage, a plurality of LED segments (LED1, LED2, LED3, LED4) connected in a series string, whereby said series string is connected to the input; a buffer component (C9) connected to an anode and a cathode of the series string; a current source circuit (B1) in series connection with a parallel connection of the buffer component (C9) and the at least two LED segments; characterized in that the LED lighting circuit further comprises a further buffer component (C5) across the current source circuit (B1), wherein said buffer component (C9) and the further buffer component (C5) are in series connection. an input (Vbus, GND) adapted to receive an input voltage, a plurality of LED segments (LED1, LED2, LED3, LED4) connected in a series string, whereby said series string is connected to the input; a buffer component (C9) connected to an anode and a cathode of the series string; a current source circuit (B1) in series connection with a parallel connection of the buffer component (C9) and the at least two LED segments; characterized in that the LED lighting circuit further comprises a further buffer component (C5) across the current source circuit (B1), wherein said buffer component (C9) and the further buffer component (C5) are in series connection.
The helical permanent magnet structure <REFNUM> of claim 1, wherein the number of the permanent magnets <REFNUM> is two or four.
Device <REFNUM> for assessing the effectiveness of ventilation in a patient under respiratory assistance, designed to interface with a patient ventilation system <REFNUM> comprising a flow-inflating bag or a self-inflating bag, the device <REFNUM> comprising: - a bidirectional thermal mass sensor <REFNUM> for measuring, in real time, the airflows during insufflation and during expiration, - an electronic unit <REFNUM> connected to said sensor <REFNUM> , the connection between the sensor and the electronic unit being made by a removable electromechanical connection, the electronic unit <REFNUM> being configured to receive and process data relating to the airflows measured by the sensor <REFNUM> , the electronic unit <REFNUM> comprising: i. a user interface comprising a display device <REFNUM> and data input means, ii. a data-processing centre, the data-processing centre functioning according to programmed algorithms for acquiring, processing and displaying data, for analysing the effectiveness of the ventilation in real time, and for managing alarms, and iii. a means for supplying electricity. - a bidirectional thermal mass sensor <REFNUM> for measuring, in real time, the airflows during insufflation and during expiration, - an electronic unit <REFNUM> connected to said sensor <REFNUM> , the connection between the sensor and the electronic unit being made by a removable electromechanical connection, the electronic unit <REFNUM> being configured to receive and process data relating to the airflows measured by the sensor <REFNUM> , the electronic unit <REFNUM> comprising: i. a user interface comprising a display device <REFNUM> and data input means, ii. a data-processing centre, the data-processing centre functioning according to programmed algorithms for acquiring, processing and displaying data, for analysing the effectiveness of the ventilation in real time, and for managing alarms, and iii. a means for supplying electricity. i. a user interface comprising a display device <REFNUM> and data input means, ii. a data-processing centre, the data-processing centre functioning according to programmed algorithms for acquiring, processing and displaying data, for analysing the effectiveness of the ventilation in real time, and for managing alarms, and iii. a means for supplying electricity.
The multimedia file processing apparatus of claim 7, wherein the attribute of the multimedia file includes at least one of the following or a combination thereof: the name of the multimedia file, the source of the multimedia file, the format of the multimedia file, and the security level of the multimedia file.
The LIBS system according to claim 2, wherein the probe optics <REFNUM> further comprises a scanning mirror assembly <REFNUM> provided between the upstream dichroic filter and the probing interface <REFNUM> .
Spring-loaded brake (BR) according to claim 1, characterized in that the coil carrier <REFNUM> is designed in one piece together with the spacer strips <REFNUM> .
The process according to claim 1, wherein, the oil is selected from the group consisting of waste animal and vegetable oil, waste mineral oil, mineral oil, distillate oil, and any combination thereof.
A terminal in a long term evolution, LTE, communication system, configured to: acquire aggregation level configuration information, wherein the aggregation level configuration information indicates a first aggregation level of a first physical downlink control channel, PDCCH, carrying dedicated control information of a terminal, and a second aggregation level of a second PDCCH carrying control information of a group, and wherein the group comprises the terminal; and blindly detect and receive, according to the first aggregation level, the dedicated control information of the terminal from a base station through the first PDCCH. acquire aggregation level configuration information, wherein the aggregation level configuration information indicates a first aggregation level of a first physical downlink control channel, PDCCH, carrying dedicated control information of a terminal, and a second aggregation level of a second PDCCH carrying control information of a group, and wherein the group comprises the terminal; and blindly detect and receive, according to the first aggregation level, the dedicated control information of the terminal from a base station through the first PDCCH.
The refrigeration and air conditioning device according to claim 5, wherein the opposite end portions of the bottom portion of the foot portion <REFNUM> each include a through hole through which bolts are disposed to fix the foot portion <REFNUM> to a stand <REFNUM> , and wherein the raised portion <REFNUM> extends upwardly to a height dimension (H) approximately equal to a difference in the dimensions of the first (D1) and second (D3) widths of the bottom portion of the foot portion <REFNUM> .
A user equipment, UE, for enabling active feedback control by a base station in a cellular communication network, the UE comprising logic for receiving from the base station an allocation information of a first time slot within a frame or multiframe, the first time slot being associated with an uplink physical control signal so that the uplink physical control signal is separate from the uplink shared physical channel comprised in said frame or multiframe, wherein the uplink physical control signal is a beacon signal; sending data to the base station over the uplink shared physical channel in a second different time slot; sending said uplink physical control signal to the base station in said first time slot when data is not being sent from the UE to the base station; receiving feedback information from the base station over a physical layer downlink control channel, the feedback information being in response to the uplink physical control signal and including power control commands for a plurality of UEs using different bits <REFNUM> , the plurality of UEs including said UE. cellular communication network, the UE comprising logic for receiving from the base station an allocation information of a first time slot within a frame or multiframe, the first time slot being associated with an uplink physical control signal so that the uplink physical control signal is separate from the uplink shared physical channel comprised in said frame or multiframe, wherein the uplink physical control signal is a beacon signal; sending data to the base station over the uplink shared physical channel in a second different time slot; sending said uplink physical control signal to the base station in said first time slot when data is not being sent from the UE to the base station; receiving feedback information from the base station over a physical layer downlink control channel, the feedback information being in response to the uplink physical control signal and including power control commands for a plurality of UEs using different bits <REFNUM> , the plurality of UEs including said UE.
A processing apparatus <REFNUM> that determines conditions of pole figure measurement by X-ray diffraction, comprising: an input unit <REFNUM> configured to receive input of a diffraction angle 2θ; a condition determination unit <REFNUM> configured to determine an angle ω formed by an incident X-ray and an x-axis, and a tilt angle χ of a sample in each φ scan for a rotation angle φ within a sample plane so as to make a range of an angle α continuous from α = 90° to α = 0° without overlapping, the angle α being formed by the sample plane and a scattering vector, the range of the angle α is measured in one φ scan on a two-dimensional detection plane in the pole figure measurement at the input angle 2θ; a processing control unit <REFNUM> configured to repeat determining the angle ω and the angle χ; a measurement control unit <REFNUM> configured to make a measuring apparatus <REFNUM> arrange the diffraction angle to 2θ which has been set, and move to sample to each of ω and χ which has been calculated, and to execute the diffraction measurement by carrying out the φ scan with respect to each X , wherein the angle ω is calculated by the formula ω = tan − 1 − x k a z k a with k a being a unit vector of a diffraction vector and x(k a ) and z(k a ) being the x- and z-component of k a respectively, and the tilt angle χ is calculated by the formula χ = cos − 1 cos Ψ max sin ω Ψ i > Ψ max , χ = cos − 1 cosΨ i sinω Ψ i ≦ Ψ max with Ψi being an angle formed by the diffraction vector and a normal line of the sample plane and Ψ max being the maximum angle formed by the diffraction vector and a normal line of the sample plane within the range that the diffracted X-rays do not pass through the sample, wherein Ψ max = cos -1 (sinθ cosψ kmax ) and wherein ψ kmax = π/2 - α min . an input unit <REFNUM> configured to receive input of a diffraction angle 2θ; a condition determination unit <REFNUM> configured to determine an angle ω formed by an incident X-ray and an x-axis, and a tilt angle χ of a sample in each φ scan for a rotation angle φ within a sample plane so as to make a range of an angle α continuous from α = 90° to α = 0° without overlapping, the angle α being formed by the sample plane and a scattering vector, the range of the angle α is measured in one φ scan on a two-dimensional detection plane in the pole figure measurement at the input angle 2θ; a processing control unit <REFNUM> configured to repeat determining the angle ω and the angle χ; a measurement control unit <REFNUM> configured to make a measuring apparatus <REFNUM> arrange the diffraction angle to 2θ which has been set, and move to sample to each of ω and χ which has been calculated, and to execute the diffraction measurement by carrying out the φ scan with respect to each X , wherein the angle ω is calculated by the formula ω = tan − 1 − x k a z k a with k a being a unit vector of a diffraction vector and x(k a ) and z(k a ) being the x- and z-component of k a respectively, and the tilt angle χ is calculated by the formula χ = cos − 1 cos Ψ max sin ω Ψ i > Ψ max , χ = cos − 1 cosΨ i sinω Ψ i ≦ Ψ max with Ψi being an angle formed by the diffraction vector and a normal line of the sample plane and Ψ max being the maximum angle formed by the diffraction vector and a normal line of the sample plane within the range that the diffracted X-rays do not pass through the sample, wherein Ψ max = cos -1 (sinθ cosψ kmax ) and wherein ψ kmax = π/2 - α min .
The blend composition of claim 10, further comprising a blend ratio for HDPE/EVOH/COC of 60/20/20 to 90/5/5 by weight.
The image capturing apparatus according to claim 1 or 2, wherein the command is a command for reading data from the device or a command for requesting a response regarding a status to the device.
The system according to claim 14, wherein the first orientation tag <REFNUM> comprises: a second machine readable code indicating a second axis of sensitivity of the transducer extending substantially orthogonal to the first axis of sensitivity of the transducer <REFNUM> ; and optionally: a third machine readable code indicating a third axis of sensitivity of the transducer <REFNUM> extending substantially orthogonal to each of the first and second axes of sensitivity of the transducer <REFNUM> .
The heat pump system <REFNUM> according to any one of claims 1 to 4, wherein the induction heating sheet <REFNUM> is attached to an outer peripheral wall of the outdoor heat exchanger <REFNUM> .
The method of any preceding claim, further comprising removing the mask regions from the surface under conditions wherein the analyte remains attached to the gel layer on the surface.
The brake caliper diagnostic device <REFNUM> according to claim 2, wherein the brake mode includes a service brake command mode, an emergency brake command mode, and a stop brake command mode, and a pressure reference value and a temperature reference value preset according to the modes are compared with measured values received from the internal pressure sensor <REFNUM> , the internal temperature sensors <REFNUM> , the assembly plate temperature sensors <REFNUM> , and the piston temperature sensors <REFNUM> to diagnose whether the brake caliper fails or is abnormal.
The method of claim 1, wherein the alkaline reducing phase further comprises adding to the coolant water a base selected from the group consisting of lithium hydroxide, potassium hydroxide and mixtures thereof.
A supplementary device <REFNUM> according to any preceding claim wherein the securing member <REFNUM> is integrally formed with the housing <REFNUM> .
An apparatus <REFNUM> as claimed in claim 11, wherein the control unit <REFNUM> is configured to cause the change in the posture by: providing an instruction or command to the subject or a care provider for the subject that the posture of the torso of the subject is to be changed; or outputting a control signal to an actuator <REFNUM> for a bed or chair associated with the subject to change the angle of the bed or chair. providing an instruction or command to the subject or a care provider for the subject that the posture of the torso of the subject is to be changed; or outputting a control signal to an actuator <REFNUM> for a bed or chair associated with the subject to change the angle of the bed or chair.
An aerosol-generating device <REFNUM> according to claim 11, wherein the heater comprises wick or capillary element to direct liquid from the reservoir <REFNUM> to one or more heating elements.
The method for forming a fluidic connection of claim 12, wherein the diameter of the external threaded male end portions <REFNUM> of the first and second connector bodies <REFNUM> are the same diameter as the threaded internal bore <REFNUM> of the first and second connector bodies <REFNUM> female end portions <REFNUM> ; and engaging the threaded surfaces <REFNUM> of said second connector body male end portion <REFNUM> to the threaded internal bore <REFNUM> of said female end portion <REFNUM> of said first connector body <REFNUM> .
A display device <REFNUM> for an electrically driven motor scooter <REFNUM> , featuring the following: - a first display device, i.e., a flat screen <REFNUM> , having a first resolution; - a second electric or electronic display device having a second resolution, wherein the second resolution preferably is significantly lower than the first resolution, wherein the display device <REFNUM> is configured to display information based on a measured value <REFNUM> and/or a variable at the same time on the first display device and the second display device, characterized in that the first resolution is by at least 70 % higher than the second resolution, and wherein the first display device comprises an LCD flat screen, a plasma flat screen or an OLED flat screen having a resolution of more than 1000 pixels. - a first display device, i.e., a flat screen <REFNUM> , having a first resolution; - a second electric or electronic display device having a second resolution, wherein the second resolution preferably is significantly lower than the first resolution, the display device <REFNUM> is configured to display information based on a measured value <REFNUM> and/or a variable at the same time on the first display device and the second display device, characterized in that the first resolution is by at least 70 % higher than the second resolution, and wherein the first display device comprises an LCD flat screen, a plasma flat screen or an OLED flat screen having a resolution of more than 1000 pixels.
Insect rearing box according to claim 1 or 2, wherein each panel has generally a planar configuration, and it has a stem <REFNUM> and wherein the bars <REFNUM> extend orthogonally from the stem <REFNUM> , and wherein the stem <REFNUM> runs transversally to the bars <REFNUM> joining them at the middle area between of the panel <REFNUM> and top and bottom ends (5',5") of the bars are free ends, or at the top of the panel <REFNUM> and the bottom ends (5',5") of the bars are free ends.
Control device unit <REFNUM> , in particular for a motor vehicle, comprising: a circuit board element <REFNUM> having electrical components <REFNUM> arranged on a mounting surface <REFNUM> of the circuit board element <REFNUM> , a housing <REFNUM> in which the circuit board element <REFNUM> is arranged, and a plurality of rectilinear connector pins (40-43) for connecting a female connector, wherein the connector pins (40-43) are each electrically connected to one or more of the electrical components <REFNUM> , wherein the connector pins (40-43) are fastened in the circuit board element <REFNUM> and are not fastened directly in the housing <REFNUM> , and the housing <REFNUM> has a connector reception opening <REFNUM> for receiving the female connector, wherein the connector pins (40-43) extend from the circuit board element <REFNUM> into the connector reception opening <REFNUM> , wherein the connector reception opening <REFNUM> comprises at least one centring lug <REFNUM> for aligning the connector reception opening <REFNUM> relative to the connector pins (40-43), characterized in that the control device unit further comprises a first casting layer <REFNUM> , wherein the first casting layer <REFNUM> is at least partially applied to a first side <REFNUM> of the circuit board element <REFNUM> in such a way that the first casting layer <REFNUM> in each case completely surrounds a partial area of the connector pins (40-43). a circuit board element <REFNUM> having electrical components <REFNUM> arranged on a mounting surface <REFNUM> of the circuit board element <REFNUM> , a housing <REFNUM> in which the circuit board element <REFNUM> is arranged, and a plurality of rectilinear connector pins (40-43) for connecting a female connector, wherein the connector pins (40-43) are each electrically connected to one or more of the electrical components <REFNUM> , wherein the connector pins (40-43) are fastened in the circuit board element <REFNUM> and are not fastened directly in the housing <REFNUM> , and the housing <REFNUM> has a connector reception opening <REFNUM> for receiving the female connector, wherein the connector pins (40-43) extend from the circuit board element <REFNUM> into the connector reception opening <REFNUM> , wherein the connector reception opening <REFNUM> comprises at least one centring lug <REFNUM> for aligning the connector reception opening <REFNUM> relative to the connector pins (40-43), characterized in that the control device unit further comprises a first casting layer <REFNUM> , wherein the first casting layer <REFNUM> is at least partially applied to a first side <REFNUM> of the circuit board element <REFNUM> in such a way that the first casting layer <REFNUM> in each case completely surrounds a partial area of the connector pins (40-43).
A plant according to any one of the preceding claims, wherein the filtration unit (1; 1**) comprises a plurality of tangential filtration elements <REFNUM> arranged in parallel.
The image processing apparatus according to claim 12, wherein the dot arrangement determination unit <REFNUM> is configured to: cancel an output value of a pixel located at the non-ejectable nozzle position in the target area of the halftone image data; select the complementation pixel in accordance with the arrangement order determined by the complementation pixel determination unit; and repeatedly perform processing to increase the output value of the selected pixel by one a number of times corresponding to the compensation value. cancel an output value of a pixel located at the non-ejectable nozzle position in the target area of the halftone image data; select the complementation pixel in accordance with the arrangement order determined by the complementation pixel determination unit; and repeatedly perform processing to increase the output value of the selected pixel by one a number of times corresponding to the compensation value.
The steering system according to claim 6, wherein the clearance member <REFNUM> has a shape of an O-ring, and a shape of a section of the clearance member <REFNUM> taken along a plane orthogonal to the axial direction is a circular shape.
The composite blade for the gas turbine engine of any preceding claim, wherein the SMA (440...450; 640; 940) comprises at least one of conductive wires or conductive sheets extending through an inner portion of the airfoil.
The evaporator <REFNUM> of claim 4, wherein the partition member <REFNUM> comprises a communication hole <REFNUM> through which the refrigerant inflow path (RI) and the refrigerant outflow path (RO) are communicated to allow the refrigerant in the refrigerant inflow path (RI) to flow to the refrigerant outflow path (RO) .
The system for guiding a vehicle <REFNUM> of claim 1, wherein the UV reactive paint defining each path of the plurality of paths is coated in sheen leveler to hide the respective path.
The retractable leash assembly <REFNUM> of any preceding claim, wherein the contact area and/or frictional force between the braking device <REFNUM> and any one or both of the spool arrangement <REFNUM> and the lead line <REFNUM> increase proportionally with an increase in the pulling force.
The method of claim 5, wherein the inflammatory bowel disease and/or condition is very early onset.
The method <REFNUM> according to any of claims 1-11, wherein: stacking sheets <REFNUM> of fusible material comprises stacking a second sheet <REFNUM> of semi-transparent fusible material onto a first sheet of transparent fusible material and stacking a third sheet of transparent fusible material onto the second sheet <REFNUM> of semi-transparent fusible material, such that the second sheet <REFNUM> is interposed between the first sheet and the third sheet, to form the stack <REFNUM> ; directing the laser beam <REFNUM> further comprises directing the laser beam <REFNUM> through the third sheet of the stack <REFNUM> and into the second sheet <REFNUM> of the stack <REFNUM> at multiple locations of the second sheet <REFNUM> ; and transferring energy from the laser beam <REFNUM> further comprises absorbing energy from the laser beam <REFNUM> at the multiple locations of the second sheet <REFNUM> to form corresponding multiple molten regions <REFNUM> , conjoined together, in the first sheet, the second sheet <REFNUM> , and the third sheet to form the fused portion <REFNUM> of the first sheet, the second sheet <REFNUM> , and the third sheet, wherein the fused portion <REFNUM> of the first sheet, the second sheet <REFNUM> , and the third sheet defines the part <REFNUM> . stacking sheets <REFNUM> of fusible material comprises stacking a second sheet <REFNUM> of semi-transparent fusible material onto a first sheet of transparent fusible material and stacking a third sheet of transparent fusible material onto the second sheet <REFNUM> of semi-transparent fusible material, such that the second sheet <REFNUM> is interposed between the first sheet and the third sheet, to form the stack <REFNUM> ; directing the laser beam <REFNUM> further comprises directing the laser beam <REFNUM> through the third sheet of the stack <REFNUM> and into the second sheet <REFNUM> of the stack <REFNUM> at multiple locations of the second sheet <REFNUM> ; and transferring energy from the laser beam <REFNUM> further comprises absorbing energy from the laser beam <REFNUM> at the multiple locations of the second sheet <REFNUM> to form corresponding multiple molten regions <REFNUM> , conjoined together, in the first sheet, the second sheet <REFNUM> , and the third sheet to form the fused portion <REFNUM> of the first sheet, the second sheet <REFNUM> , and the third sheet, wherein the fused portion <REFNUM> of the first sheet, the second sheet <REFNUM> , and the third sheet defines the part <REFNUM> .
A first base station comprising: one or more processors; and memory storing instructions that, when executed by the one or more processors, cause the first base station to perform the method of any one of claims 8 to 11.
The system of claim 5 wherein the system controller <REFNUM> communicates with a controller for the elevator car <REFNUM> over a first network, and the system controller <REFNUM> communicates with the first mobile device over a second network, and the system controller <REFNUM> communicates with the third device over a third network.
The cooking appliance <REFNUM> of claim 14, wherein the controller <REFNUM> is configured to analyze the image data to determine an image quality of each sub-image <REFNUM> , and wherein if the image quality of at least one of the sub-images <REFNUM> is below a predefined quality threshold the controller <REFNUM> is configured to determine that the corresponding secondary mirror <REFNUM> is obstructed and consequently configured to utilize a different sub-image <REFNUM> for subsequent image processing.
The method of claim 10, wherein increasing the regulation point of the voltage regulator circuit comprises adjusting a reference voltage for the voltage regulator circuit.
The method of claim 1 or 2, wherein the frame is a proprietary frame and is specified if a bit-15 of a "duration/ID" field of a media access control, in the following also referred to as MAC, header of the power saving poll, in the following also referred to as PS-Poll, frame is zero.
The method of any one of claims 1 to 4, further comprising determining a breathing or ventilation frequency (VF) of the patient (P) based on the at least one measuring signal (LVP meas ) and/or consecutive actual values (EDLVP; FG) and/or a measuring signal of a ventilation pressure.
The RRAM device <REFNUM> of claim 1, 2, 3, or 4, further comprising a layer <REFNUM> including a noble metal or alloy under the encapsulating layer <REFNUM> and the bottom electrode <REFNUM> .
A method for dosed dispensing of powdered substance <REFNUM> from a magazine <REFNUM> in which containers <REFNUM> containing different powdered substances are located, comprising: - removing the container <REFNUM> with the desired powdery substance from the magazine <REFNUM> by transport means <REFNUM> , - taking the desired amount of this powdery substance from this container <REFNUM> by a delivery system <REFNUM> , - placing a funnel <REFNUM> upside down on an opening provided on the top of the container <REFNUM> by lifting means <REFNUM> and coupling means <REFNUM> , - turning the container <REFNUM> and the funnel <REFNUM> thereon upside down by reversing means <REFNUM> so that the contents of the container <REFNUM> end up in the funnel <REFNUM> , - opening the funnel mouth <REFNUM> for dosed dispensing of the powdery substance <REFNUM> until the desired amount has fallen from the funnel <REFNUM> and then closing the funnel mouth <REFNUM> by means of a metering valve <REFNUM> , - turning back the container <REFNUM> and the funnel <REFNUM> underneath by the reversing means <REFNUM> so that the remaining powdery substance <REFNUM> falls back into the container, - removing the funnel <REFNUM> from the container <REFNUM> by the lifting means <REFNUM> and the coupling means <REFNUM> , and - putting the container <REFNUM> back in the magazine <REFNUM> by transport means <REFNUM> , characterized in that at removing the funnel <REFNUM> from the container <REFNUM> by the lifting means <REFNUM> and the coupling means <REFNUM> releasing dust clouds <REFNUM> are extracted by suction means <REFNUM> arranged on the funnel mouth <REFNUM> . - removing the container <REFNUM> with the desired powdery substance from the magazine <REFNUM> by transport means <REFNUM> , - taking the desired amount of this powdery substance from this container <REFNUM> by a delivery system <REFNUM> , - placing a funnel <REFNUM> upside down on an opening provided on the top of the container <REFNUM> by lifting means <REFNUM> and coupling means <REFNUM> , - turning the container <REFNUM> and the funnel <REFNUM> thereon upside down by reversing means <REFNUM> so that the contents of the container <REFNUM> end up in the funnel <REFNUM> , - opening the funnel mouth <REFNUM> for dosed dispensing of the powdery substance <REFNUM> until the desired amount has fallen from the funnel <REFNUM> and then closing the funnel mouth <REFNUM> by means of a metering valve <REFNUM> , - turning back the container <REFNUM> and the funnel <REFNUM> underneath by the reversing means <REFNUM> so that the remaining powdery substance <REFNUM> falls back into the container, - removing the funnel <REFNUM> from the container <REFNUM> by the lifting means <REFNUM> and the coupling means <REFNUM> , and - putting the container <REFNUM> back in the magazine <REFNUM> by transport means <REFNUM> , characterized in that at removing the funnel <REFNUM> from the container <REFNUM> by the lifting means <REFNUM> and the coupling means <REFNUM> releasing dust clouds <REFNUM> are extracted by suction means <REFNUM> arranged on the funnel mouth <REFNUM> .
The system of any of the preceding claims, wherein the processor is configured to actuate a direction of view of the at least one focus imaging sensor prior to capturing the at least one second image, based upon the gaze direction of the user.
The method of claim 11, further comprising attaching an elastic jacket <REFNUM> around the metallic region.
A method performed by a first base station, BS, in a wireless communication system, the method comprising: in response to a request for a radio resource control, RRC, connection via an RRC reestablishment request message or an RRC resume request message, the respective message comprising an authentication token, receiving <REFNUM> , from a second BS corresponding to a second cell, a user equipment, UE, context request message comprising an identifier of a UE that had an active radio resource control, RRC, connection with the first BS, the authentication token, and indication information indicating whether the RRC connection is requested to be re-established or resumed, wherein the authentication token is based on the indication information; identifying UE context information of the UE based on the identifier of the UE; verifying the UE based on the authentication token; and transmitting <REFNUM> , to the second BS, a UE context request response message comprising the UE context information of the UE. in response to a request for a radio resource control, RRC, connection via an RRC reestablishment request message or an RRC resume request message, the respective message comprising an authentication token, receiving <REFNUM> , from a second BS corresponding to a second cell, a user equipment, UE, context request message comprising an identifier of a UE that had an active radio resource control, RRC, connection with the first BS, the authentication token, and indication information indicating whether the RRC connection is requested to be re-established or resumed, wherein the authentication token is based on the indication information; identifying UE context information of the UE based on the identifier of the UE; verifying the UE based on the authentication token; and transmitting <REFNUM> , to the second BS, a UE context request response message comprising the UE context information of the UE.
A method for producing a decorative paper by means of a digital printing facility <REFNUM> , the method featuring the following steps: a. providing at least one base paper <REFNUM> , b. printing a primer onto a surface of the base paper <REFNUM> so that a printed base paper is obtained, c. printing at least one printing ink onto the surface of the printed base paper <REFNUM> by means of a digital printing facility <REFNUM> , characterized in that neither the primer nor the printing ink is printed onto the surface of the base paper <REFNUM> at at least one point. a. providing at least one base paper <REFNUM> , b. printing a primer onto a surface of the base paper <REFNUM> so that a printed base paper is obtained, c. printing at least one printing ink onto the surface of the printed base paper <REFNUM> by means of a digital printing facility <REFNUM> ,
Ice-making apparatus <REFNUM> as in at least one of claims 1-3, characterized in that said ice storage <REFNUM> has a controllable door to avoid the loss of ozone in the atmosphere.
The method according to claim 1, wherein the radio access technology of the second wireless communication network <REFNUM> is high rate packet data, HRPD.
Tread <REFNUM> according to any one of Claims 1 to 7, wherein the tread is suitable for conferring a preferred direction of rotation to the tyre provided with this tread, and wherein the hidden cavity or cavities <REFNUM> connected to an open well <REFNUM> are oriented in such a way that, when viewed in projection onto the tread surface, that part of each hidden cavity that opens into the well is the first to come into contact with the road surface.
The method according to any one of the previous claims, wherein the forming of at least a first substantially unidirectional layer <REFNUM> comprises forming of multiple substantially unidirectional layers by reciprocating the liner <REFNUM> in the braiding machine <REFNUM> .
An optical system comprising the cemented lens according to claim 16.
A method of constructing a merge candidate list for Intra block copy, IBC, mode, the method comprising the following ordered steps: inserting a block vector of a left neighboring block of a current block into an initial merge candidate list of the current block, when the left neighboring block is available and the left neighboring block is using IBC mode; inserting a block vector of an above neighboring block of the current block into the merge candidate list, when the above neighboring block is available, the above neighboring block is using IBC mode and the block vector of the above neighboring block is not same as the block vector of the left neighboring block; inserting a block vector of last candidate in a history based motion vector predictor, HMVP, list into the merge candidate list, when the block vector of the above neighboring block is not same as the block vector of the last candidate in the HMVP list and when the block vector of the left neighboring block is not same as the block vector of the last candidate in the HMVP list; inserting one by one block vectors of other candidates in the HMVP list into the merge candidate list without pruning, until a number of block vectors in the merge candidate list is equal to a maximum number of block vectors in the merge candidate list or until the block vectors of all the candidates in the HMVP list are inserted into the merge candidate list, wherein the pruning means comparing whether two merge candidates in the merge candidate list are same, wherein if the maximum number of block vectors in the merge candidate list is reached, the last block vector in the merge candidate list of the current block is a block vector of one of the other candidates in the HMVP list; and wherein if all the candidates in the HMVP list are inserted into the merge candidate list and the number of block vectors in the merge candidate list is less than the maximum number of block vectors in the merge candidate list, one or more zeros are inserted into the merge candidate list until the number of block vectors in the merge candidate list is equal to the maximum number of block vectors in the merge candidate list. inserting a block vector of a left neighboring block of a current block into an initial merge candidate list of the current block, when the left neighboring block is available and the left neighboring block is using IBC mode; inserting a block vector of an above neighboring block of the current block into the merge candidate list, when the above neighboring block is available, the above neighboring block is using IBC mode and the block vector of the above neighboring block is not same as the block vector of the left neighboring block; inserting a block vector of last candidate in a history based motion vector predictor, HMVP, list into the merge candidate list, when the block vector of the above neighboring block is not same as the block vector of the last candidate in the HMVP list and when the block vector of the left neighboring block is not same as the block vector of the last candidate in the HMVP list; inserting one by one block vectors of other candidates in the HMVP list into the merge candidate list without pruning, until a number of block vectors in the merge candidate list is equal to a maximum number of block vectors in the merge candidate list or until the block vectors of all the candidates in the HMVP list are inserted into the merge candidate list, wherein the pruning means comparing whether two merge candidates in the merge candidate list are same, wherein if the maximum number of block vectors in the merge candidate list is reached, the last block vector in the merge candidate list of the current block is a block vector of one of the other candidates in the HMVP list; and wherein if all the candidates in the HMVP list are inserted into the merge candidate list and the number of block vectors in the merge candidate list is less than the maximum number of block vectors in the merge candidate list, one or more zeros are inserted into the merge candidate list until the number of block vectors in the merge candidate list is equal to the maximum number of block vectors in the merge candidate list.
The adjustable scanning acoustic microscope sample fixture <REFNUM> of any of claims 1 to 6, wherein the first horizontal bar <REFNUM> is movable between the first end and the second end of the frame <REFNUM> and optionally wherein one or more of the first side bar, the second side bar, the first horizontal bar <REFNUM> , and the second horizontal bar <REFNUM> comprises one or more markings corresponding to different sample types for configuring the adjustable fixture to hold at least one of the different sample types.
A metal foil with resin, comprising: a metal foil; and a semi-cured resin composition layer that is provided on or above the metal foil, and that comprises a semi-cured product of the epoxy resin composition according to any one of claims 10 to 13. a metal foil; and a semi-cured resin composition layer that is provided on or above the metal foil, and that comprises a semi-cured product of the epoxy resin composition according to any one of claims 10 to 13.
The method of claim 3 wherein a chrominance quantization parameter is a function of a luminance quantization parameter.
The method of claim 1 or claim 2, wherein the first virtual object <REFNUM> is represented by a first thumbnail representation, the second virtual object <REFNUM> is represented by a second thumbnail representation, and the group virtual object <REFNUM> is represented by a stacked thumbnail representation in which (i) the first thumbnail representation and the second thumbnail representation are automatically aligned to generate the stacked thumbnail representation and (ii) the first thumbnail representation is in a top position of the stacked thumbnail representation in response to detecting that the first virtual object <REFNUM> was interacted with and virtually positioned over the second virtual object <REFNUM> .
The machine according to the preceding claim, wherein the first, inside wall <REFNUM> forms part of a first element and the second, outside wall <REFNUM> forms part of a second element, the first element being insertable into the second element.
The method of claim 1, wherein the 5GC further comprises a Unified Data Management, UDM, Network Slice Selection Function, NSSF, the method further comprising: sending (S11), from the UE to the RAN, a registration request, the registration request comprising one or a combination of registration parameters: requested slice selection information, cell ID and/or a subscriber ID; selecting (S12), at the RAN, an AMF based on the registration parameters; sending (S13), from the RAN to the selected AMF, the registration request including the requested slice selection information, cell ID, and/or subscriber ID; performing (S4), at the selected AMF, authentication/security together with the UDM; retrieving (S5), at the selected AMF, from the UDM or from local configuration at the AMF, subscriber information including slice selection subscription data, wherein the slice selection subscription data indicates slice or slices a subscriber is allowed to access identified by slice selection information; checking, at the selected AMF, whether slice selection is needed and, if slice selection is needed, retrieving (S6), from the NSSF, UDM or from local configuration at the AMF, slice selection information, and based on the information retrieved from local configuration, the NSSF, UDM and/or the received requested slice selection information, determining (S7A) a served slice or served slices that the UE will be allowed to access by the 5GS, wherein the served slice or slices are identified by slice selection information; determining (S14A), at the AMF, slice frequency restrictions information that needs to be retrieved based on the slice selection information of the served slices and creating a request based on the determined slice frequency restrictions information; sending (S14B), by the AMF to the functional entity, the request for slice frequency restrictions information; sending (S15), from the functional entity to the AMF, a message comprising the requested slice frequency restrictions information; sending (S16), from the AMF to the RAN, a registration response including the slice frequency restrictions information for the served slice or served slices served to the UE; and forwarding (S17), from the RAN to the UE, the registration response. sending (S11), from the UE to the RAN, a registration request, the registration request comprising one or a combination of registration parameters: requested slice selection information, cell ID and/or a subscriber ID; selecting (S12), at the RAN, an AMF based on the registration parameters; sending (S13), from the RAN to the selected AMF, the registration request including the requested slice selection information, cell ID, and/or subscriber ID; performing (S4), at the selected AMF, authentication/security together with the UDM; retrieving (S5), at the selected AMF, from the UDM or from local configuration at the AMF, subscriber information including slice selection subscription data, wherein the slice selection subscription data indicates slice or slices a subscriber is allowed to access identified by slice selection information; checking, at the selected AMF, whether slice selection is needed and, if slice selection is needed, retrieving (S6), from the NSSF, UDM or from local configuration at the AMF, slice selection information, and based on the information retrieved from local configuration, the NSSF, UDM and/or the received requested slice selection information, determining (S7A) a served slice or served slices that the UE will be allowed to access by the 5GS, wherein the served slice or slices are identified by slice selection information; determining (S14A), at the AMF, slice frequency restrictions information that needs to be retrieved based on the slice selection information of the served slices and creating a request based on the determined slice frequency restrictions information; sending (S14B), by the AMF to the functional entity, the request for slice frequency restrictions information; sending (S15), from the functional entity to the AMF, a message comprising the requested slice frequency restrictions information; sending (S16), from the AMF to the RAN, a registration response including the slice frequency restrictions information for the served slice or served slices served to the UE; and forwarding (S17), from the RAN to the UE, the registration response.
The method of claim 1, wherein the time gap is a function of a configuration indicating whether a first symbol of the uplink data transmission is reserved for a demodulation reference signal, DMRS.
The method of claim 1, wherein in 2), the down-sampled images are converted to the grayscale images by the following equation: Gray = 0.30 × R + 0.59 × G + 0.11 × B; wherein R, G and B represent information values of red color, green color and blue color, respectively.
The horse riding training aid as claimed in claim 1, further comprising resiliently deformable means for supporting at least part of the weight of the dummy horse <REFNUM> , or a spring.
The medical tube <REFNUM> of any one of claims 1 to 7, wherein the spirally wound bead <REFNUM> has a cross-sectional width of approximately 1mm in a direction parallel to the longitudinal axis <REFNUM> of the medical tube <REFNUM> and a cross-sectional height of approximately 1 mm in a direction perpendicular to the longitudinal axis <REFNUM> of the medical tube <REFNUM> , and/or wherein the spirally wound film <REFNUM> has a thickness of about 0.05mm to 1mm.
Rotor according to Claim 6, characterized in that at least one curved edge which adjoins a filled region of the flux barrier <REFNUM> bends into the filled region of the flux barrier <REFNUM> .
The method of claim 14, wherein: the thermal response of the sample <REFNUM> to the heating is measured with the sensor element <REFNUM> in contact with a first region <REFNUM> on the sample <REFNUM> ; and a further thermal response of the sample <REFNUM> to the heating is measured using a further sensor element <REFNUM> in contact with a second region <REFNUM> on the sample <REFNUM> , the second region <REFNUM> being separate from the first region <REFNUM> and optionally on an opposite side of the sample <REFNUM> to the first region <REFNUM> . the thermal response of the sample <REFNUM> to the heating is measured with the sensor element <REFNUM> in contact with a first region <REFNUM> on the sample <REFNUM> ; and a further thermal response of the sample <REFNUM> to the heating is measured using a further sensor element <REFNUM> in contact with a second region <REFNUM> on the sample <REFNUM> , the second region <REFNUM> being separate from the first region <REFNUM> and optionally on an opposite side of the sample <REFNUM> to the first region <REFNUM> .
The optical system of Claim 1, wherein a diameter of the primary mirror ranges from 3% to 8% of an effective focal length.
A method comprising: cutting <REFNUM> a plurality of blade elements <REFNUM> , wherein at least one dimension of each of the plurality of blade elements is different than a corresponding dimension of each other blade element of the plurality of blade elements; aligning <REFNUM> each of the plurality of cut blade elements to form a stacked blade <REFNUM> , wherein the alignment of the plurality of cut blade elements further defines a profile of the stacked blade, and wherein a leading edge of the stacked blade comprises a at least a portion of a leading edge from each of the plurality of cut blade elements, wherein a first cut blade element <REFNUM> of the plurality of cut blade elements comprises a first alignment feature, and a second cut blade element <REFNUM> of the plurality of cut blade elements comprises a second alignment feature <REFNUM> that is configured to couple to the first alignment feature; and coupling <REFNUM> the plurality of blade elements to a hub <REFNUM> . cutting <REFNUM> a plurality of blade elements <REFNUM> , wherein at least one dimension of each of the plurality of blade elements is different than a corresponding dimension of each other blade element of the plurality of blade elements; aligning <REFNUM> each of the plurality of cut blade elements to form a stacked blade <REFNUM> , wherein the alignment of the plurality of cut blade elements further defines a profile of the stacked blade, and wherein a leading edge of the stacked blade comprises a at least a portion of a leading edge from each of the plurality of cut blade elements, wherein a first cut blade element <REFNUM> of the plurality of cut blade elements comprises a first alignment feature, and a second cut blade element <REFNUM> of the plurality of cut blade elements comprises a second alignment feature <REFNUM> that is configured to couple to the first alignment feature; and coupling <REFNUM> the plurality of blade elements to a hub <REFNUM> .
The data transmission method of claim 7, wherein in response to determining that a policy comprised in the compression strategy changes, the data transmission method further comprises: sending an update request message to the sending end, wherein the update request message carries a policy number corresponding to the changed policy and a content of a new policy.
The system of claim 1, wherein the controller <REFNUM> is programmed to: - store a preselected minimum level of confidence in an energy storage device state measurement; - calculate a level of confidence in a measurement obtained from a last state measurement of the energy storage device <REFNUM> ; - compare the measurement of the last energy storage device state measurement with the preselected minimum level of confidence; and - disconnect the energy storage device <REFNUM> to enable the updated state measurement of the energy storage device <REFNUM> based at least in part on the comparison. - store a preselected minimum level of confidence in an energy storage device state measurement; - calculate a level of confidence in a measurement obtained from a last state measurement of the energy storage device <REFNUM> ; - compare the measurement of the last energy storage device state measurement with the preselected minimum level of confidence; and - disconnect the energy storage device <REFNUM> to enable the updated state measurement of the energy storage device <REFNUM> based at least in part on the comparison.
The method of claim 5, wherein in the step of preparing the quercetin mother solution, the solvent is dimethyl sulfoxide.
A pharmaceutical composition comprising as an active ingredient the antisense oligomer according to any one of claims 1 to 11, or a pharmaceutically acceptable salt or hydrate thereof for use in the treatment of muscular dystrophy in a patient.
The method of claim 9, further comprising: determining differences between the first expected phase differences and the measured phase differences; generating a first probability for each of the geographic regions based on the differences; determining second differences between the second expected phase differences and the measured second phase differences; generating a second probability for each of the geographic regions based on the second differences; and aggregating first and second probabilities corresponding to common regions, wherein the estimating of the location of the first wireless device is based on the aggregated probabilities, and for example further comprising determining a region having a highest aggregated probability, wherein the estimating of the location of the first wireless device is based on the determining, for example further comprising weighting each of the plurality of geographic regions based on their respective probabilities, wherein the estimating of the location of the first wireless device is based on the weighted plurality of regions. determining differences between the first expected phase differences and the measured phase differences; generating a first probability for each of the geographic regions based on the differences; determining second differences between the second expected phase differences and the measured second phase differences; generating a second probability for each of the geographic regions based on the second differences; and aggregating first and second probabilities corresponding to common regions, wherein the estimating of the location of the first wireless device is based on the aggregated probabilities, and for example further comprising determining a region having a highest aggregated probability, wherein the estimating of the location of the first wireless device is based on the determining, for example further comprising weighting each of the plurality of geographic regions based on their respective probabilities, wherein the estimating of the location of the first wireless device is based on the weighted plurality of regions.
A sensor <REFNUM> for intercepting radioelectric signals, characterized in that it is suitable for analyzing radar emissions (RAD) and communication emissions (COM), and in that it includes: - a reception stage <REFNUM> , common and capable of digitizing an incident radioelectric signal; - a primary analysis processing stage <REFNUM> , common and capable of preprocessing the digitized signal so as to determine a plurality of primary characteristics of the incident radioelectric signal; and - a secondary analysis processing stage <REFNUM> , including a processing chain <REFNUM> for analyzing the preprocessed digitized signal dedicated to communication emissions (COM), and a processing chain <REFNUM> for analyzing the preprocessed digitized signal dedicated to radar emissions (RAD), the primary analysis processing stage <REFNUM> including a discrimination module <REFNUM> adapted for applying the preprocessed digitized signal at the input of the chain <REFNUM> dedicated to communication emissions (COM) and/or at the input of the chain <REFNUM> dedicated to radar emissions (RAD), based on primary characteristics determined for the incident radioelectric signal. - a reception stage <REFNUM> , common and capable of digitizing an incident radioelectric signal; - a primary analysis processing stage <REFNUM> , common and capable of preprocessing the digitized signal so as to determine a plurality of primary characteristics of the incident radioelectric signal; and - a secondary analysis processing stage <REFNUM> , including a processing chain <REFNUM> for analyzing the preprocessed digitized signal dedicated to communication emissions (COM), and a processing chain <REFNUM> for analyzing the preprocessed digitized signal dedicated to radar emissions (RAD),
The control device according to any one of claims 1 to 6, wherein based on a speed at which at least one generator connectable to the AC power system changes output of the at least one generator, the frequency control unit is configured to set a time period for which the frequency of the power source, resulting from varying the frequency of the power source, is maintained.
The window and door <REFNUM> according to claim 10 and comprising said closing device according to claim 7, wherein said cavity <REFNUM> is at least partly fashioned in a housing seat <REFNUM> of an edge surface <REFNUM> of said frame <REFNUM> adapted to receive said striker <REFNUM> .
A method for the manufacture of an a,β-unsaturated ketone, which method comprises oxidizing an alkene having -CH 2 - adjacent a carbon-carbon double bond to a,β-unsaturated ketone by passing air or oxygen through a solution of the hydrocarbon containing a catalyst consisting of N-hydroxyphthalimide (NHPI) and cobalt diacetate tetrahydrate at standard temperature and pressure during a period of at least 12 hours.
Method according to any of claims 1 to 5, characterized in that the current supply pressure (p sys ) and the value of the switch-on pressure (p cut-on ) and the value for the cut-off pressure (p cut-off ) or the value for the corrected cut-off pressure (p cut-off_c ) of the compressor <REFNUM> are displayed in a display instrument <REFNUM> , and in that , when a reduced cut-off pressure value (p cut-off_c ) is present, an associated warning light <REFNUM> is illuminated and/or an acoustic warning signal is output.
Top layer according to claim 6, characterized in that the structure <REFNUM> , preferably on the top side <REFNUM> of the layer composite <REFNUM> and/or the top layer <REFNUM> , has a maximum depth <REFNUM> of up to 1 mm, preferably up to 0.5 mm, more preferably between 0.05 mm to 0.2 mm, and/or in that the structure <REFNUM> on the bottom side <REFNUM> of the layer composite <REFNUM> and/or of the top layer <REFNUM> has a maximum height <REFNUM> of at most 100 μm, preferably at most 90 μm, further preferably between 30 μm to 90 μm, and/or that the top layer <REFNUM> has a thickness <REFNUM> of at least 0.1 mm, preferably between 0.1 and 0.4 mm, more preferably between 0.2 and 0.3 mm. in that the structure <REFNUM> on the bottom side <REFNUM> of the layer composite <REFNUM> and/or of the top layer <REFNUM> has a maximum height <REFNUM> of at most 100 μm, preferably at most 90 μm, further preferably between 30 μm to 90 μm, and/or that the top layer <REFNUM> has a thickness <REFNUM> of at least 0.1 mm, preferably between 0.1 and 0.4 mm, more preferably between 0.2 and 0.3 mm.
Method in accordance with claim 6, wherein the new interest point <REFNUM> is defined by - selecting one of the sub-regions <REFNUM> , preferring those containing fewer interest points <REFNUM> over those containing more interest points <REFNUM> , - randomly selecting a point of the sub-region <REFNUM> , - if the point does not comply with one or more predetermined suitability conditions, repeating the previous step or steps until the point does comply with the one or more predetermined suitability conditions, - defining the last selected point as the new interest point <REFNUM> . - selecting one of the sub-regions <REFNUM> , preferring those containing fewer interest points <REFNUM> over those containing more interest points <REFNUM> , - randomly selecting a point of the sub-region <REFNUM> , - if the point does not comply with one or more predetermined suitability conditions, repeating the previous step or steps until the point does comply with the one or more predetermined suitability conditions, - defining the last selected point as the new interest point <REFNUM> .
Use of an apparatus as defined in any one of claims 1 to 7, to carry out a process on a suspension.
Milking device according to Claim 3, wherein the plurality of feeding troughs are substantially evenly distributed over the inner edge.
The array substrate <REFNUM> according to claim 4, wherein the touch control connection lines <REFNUM> in each of the second touch control columns <REFNUM> are sequentially arranged along the direction from the first side portion <REFNUM> to the second side portion <REFNUM> .
The method of claim 9, wherein one transmission of a block of physical data divided over two consecutive timeslots has a first portion scheduled within a first timeslot including the top resource unit, and a second portion within a second timeslot including the base resource unit.
An axial compressor <REFNUM> comprising: a tubular casing <REFNUM> ; a drive shaft <REFNUM> extending in axially rotatable manner inside the central cavity <REFNUM> of said casing <REFNUM> coaxial to the latter; a number of annular blade rows <REFNUM> spaced along and stably fixed to the drive shaft <REFNUM> ; and a number of annular vane rows <REFNUM> stably fixed to the peripheral wall <REFNUM> of said casing <REFNUM> intercalated to the annular blade rows <REFNUM> ; the compressor <REFNUM> being additionally provided with at least one bleed cavity <REFNUM> formed within the peripheral wall <REFNUM> of said casing <REFNUM> , and a corresponding bleeding slot <REFNUM> which is formed in the peripheral wall <REFNUM> to put said bleed cavity <REFNUM> into direct communication with the central cavity <REFNUM> of said casing <REFNUM> ; the compressor <REFNUM> additionally comprising at least one air deflector member <REFNUM> which is located inside the bleed cavity <REFNUM> , and is adapted to divert/guide the airflow (f) of compressed air entering and/or circulating inside the bleed cavity <REFNUM> for reducing the air turbulence area inside the bleed cavity <REFNUM> ; the compressor <REFNUM> being characterized in that said at least one air deflector member <REFNUM> is located inside the bleed cavity <REFNUM> adjacent to said annular bleeding slot <REFNUM> , and is designed to guide/divert said airflow (f) towards the air outlet/s <REFNUM> of the bleed cavity <REFNUM> , so as to reduce the size of the vortices that the airflow (f) forms while flowing out of the bleed cavity <REFNUM> via the corresponding air outlet/s <REFNUM> ; said at least one air deflector member <REFNUM> being provided with a circumferentially-arranged flap portion <REFNUM> that rises from the inner surface of the bleed cavity <REFNUM> to form a ramp or slope for the airflow (f) that has an arched profile so as to smoothly turn the velocity vector of said airflow (f) in direction of the air outlets <REFNUM> ; said flap portion <REFNUM> having, on its front face, a number of protruding fins <REFNUM> which are spaced side-by-side to one another in a circumferential direction. the compressor <REFNUM> being additionally provided with at least one bleed cavity <REFNUM> formed within the peripheral wall <REFNUM> of said casing <REFNUM> , and a corresponding bleeding slot <REFNUM> which is formed in the peripheral wall <REFNUM> to put said bleed cavity <REFNUM> into direct communication with the central cavity <REFNUM> of said casing <REFNUM> ; the compressor <REFNUM> additionally comprising at least one air deflector member <REFNUM> which is located inside the bleed cavity <REFNUM> , and is adapted to divert/guide the airflow (f) of compressed air entering and/or circulating inside the bleed cavity <REFNUM> for reducing the air turbulence area inside the bleed cavity <REFNUM> ; the compressor <REFNUM> being characterized in that said at least one air deflector member <REFNUM> is located inside the bleed cavity <REFNUM> adjacent to said annular bleeding slot <REFNUM> , and is designed to guide/divert said airflow (f) towards the air outlet/s <REFNUM> of the bleed cavity <REFNUM> , so as to reduce the size of the vortices that the airflow (f) forms while flowing out of the bleed cavity <REFNUM> via the corresponding air outlet/s <REFNUM> ; said at least one air deflector member <REFNUM> being provided with a circumferentially-arranged flap portion <REFNUM> that rises from the inner surface of the bleed cavity <REFNUM> to form a ramp or slope for the airflow (f) that has an arched profile so as to smoothly turn the velocity vector of said airflow (f) in direction of the air outlets <REFNUM> ; said flap portion <REFNUM> having, on its front face, a number of protruding fins <REFNUM> which are spaced side-by-side to one another in a circumferential direction.
The system of claim 7, wherein the vibrators <REFNUM> configured to impart low frequency signals are clustered within the array.
The drilling system of any one of the preceding claims, further comprising an outer drill rod drive chuck <REFNUM> removably coupled to the outer drill rod drive shaft assembly.
The method as claimed in claim 7, characterized in that the at least one roller row <REFNUM> is fully occupied with rollers to improve the dimensional accuracy of the rolling bearing rings <REFNUM> during the hard rolling.
The wall hook according to one or more of the preceding claims, characterized in that the wall hook <REFNUM> has an axial securing means <REFNUM> of the hook element <REFNUM> on the screw shaft <REFNUM> .
The actuator assembly <REFNUM> as claimed in claim 1 or 2, wherein the static portion <REFNUM> comprises at least one key feature <REFNUM> that fits with a corresponding key feature <REFNUM> formed on the moveable portion <REFNUM> , plural end-stop surfaces <REFNUM> being formed on the or each key feature <REFNUM> of the static portion <REFNUM> .
The image sensor <REFNUM> according to any one of Claims 1 through 6, wherein: the second circuit layer <REFNUM> includes a capacitance adjustment unit <REFNUM> having a third capacitor <REFNUM> that is connected in parallel with the second capacitor <REFNUM> .