Abstract: A method for machining ribs or grooves on a workpiece including a shaft (7) and an air or gas axial bearing (24) attached to the shaft or forming a part of the shaft. The workpiece is rotated about a longitudinal axis of a centrifugal compressor. All of the ribs or grooves are obtained at once by the machining tool on a workpiece portion driven such that it rotates, by moving the workpiece or the tool holder in a longitudinal direction, the machining tool moving back and forth with a machining position in contact with the workpiece and a position wherein it is not in contact with the workpiece from the beginning to the end of the workpiece portion. Reciprocating motions of the machining tool are synchronised with the sinusoidal program, as well as with the desired, programmed arrangement of the ribs or grooves to be produced on the workpiece portion.

Abstract: Systems, devices and methods are provided for determining injury risk and athletic readiness based on user movement data, including movement variability data. Generally, a sensor device, such as a force plate, is provided for sensing certain characteristics of a user movement. A computing device coupled to the sensor device can be configured to receive sensor data indicative of the characteristics of the user movement, process and extract information from the sensor data, and transmit the processed sensor data to a server system. The remote server system can be configured to store, aggregate and update the processed sensor data in a database, and can also generate one or more normalized scores correlating to the user movement. The normalized scores can indicate to a user a susceptibility to injury and/or a readiness towards return to normal activity.

Abstract: A method for training athletes is disclosed. The method comprises: calculating an athletic signature for an athlete comprising normalized values for the concentric net vertical impulse (CON-IMP), the average eccentric rate of force development (ECC-RFD), and the average vertical concentric force (CON-VF) for the athlete; analyzing the athletic signature; and assigning at least one training block to the athlete based on the analysis of the athletic signature.

Abstract: A device suitable for the detection and/or characterization of target particles in a fluid is disclosed. The device comprises: at least one heating element for heating and/or measuring a temperature, the heating element comprising a core comprising at least one electrically conducting portion, an electric isolating layer provided at a surface of the core and electrically isolates the core from the sample, and a plurality of binding sites at/to which target particles can bind. The device further comprising a processing means configured to measure an electric output of the least one heating element, a change of the electric output of the at least one heating element and/or its heating power and for deriving, based thereon, a characteristic of the target particles.

Abstract: A method for training athletes is disclosed. The method comprises: calculating an athletic signature for an athlete comprising normalized values for the concentric net vertical impulse (CON-IMP), the average eccentric rate of force development (ECC-RFD), and the average vertical concentric force (CON-VF) for the athlete; analyzing the athletic signature; and assigning at least one training block to the athlete based on the analysis of the athletic signature.

Abstract: Systems, devices and methods are provided for determining injury risk and athletic readiness based on athletic movement data. Generally, a sensor device, such as a force plate, is provided for sensing certain characteristics of an athletic movement. A local computing device coupled to the sensor device can be configured to receive sensor data indicative of the characteristics of the athletic movement, process and extract information from the sensor data, and transmit the processed sensor data to a remote server system. The remote server system can be configured to store, aggregate and update the processed sensor data in a database, and can also generate one or more normalized scores correlating to the athletic movement. The normalized scores can indicate to a user a susceptibility to injury and/or a readiness towards return to play.

Abstract: A method for training athletes is disclosed. The method comprises: calculating an athletic signature for an athlete comprising normalized values for the concentric net vertical impulse (CON-IMP), the average eccentric rate of force development (ECC-RFD), and the average vertical concentric force (CON-VF) for the athlete; analyzing the athletic signature; and assigning at least one training block to the athlete based on the analysis of the athletic signature.

Abstract: Wearable computing devices adapted to be worn on the feet are provided for acquiring, validating and analyzing athletic movement data. Generally, the wearable computing devices can include one or more processors, a memory, and one or more sensors for sensing certain characteristics of an athletic movement. A local computing device is provided for receiving data from the wearable computing device that is indicative of the characteristics of the athletic movement, extracting selected portions from the data, and transmitting the selected portions to a remote server system. The remote server system can be configured to store, aggregate and update a data in a database, and generate one or more normalized values and/or interventions associated with the athletic movement. The normalized values may indicate to the user a susceptibility to injury, progression towards return to play or propensity for success with respect to a sport.

Abstract: A device suitable for the detection and/or characterization of target particles in a fluid is disclosed. The device comprises: at least one heating element for heating and/or measuring a temperature, the heating element comprising a core comprising at least one electrically conducting portion, an electric isolating layer provided at a surface of the core and electrically isolates the core from the sample, and a plurality of binding sites at/to which target particles can bind. The device further comprising a processing means configured to measure an electric output of the least one heating element, a change of the electric output of the at least one heating element and/or its heating power and for deriving, based thereon, a characteristic of the target particles.

Abstract: The present disclosure relates to a method for characterizing and identifying a bioparticle. The method comprises introducing the sample to a substrate having a surface comprising a plurality of binding sites whereon bioparticles can be bound, determining, for at least one temperature, data representative for the interface thermal resistance of the surface of the substrate sufficiently long to include the detachment process of the bioparticles, and deriving, for the at least one temperature, a bioparticle retention time and/or detachment rate from the data representative for the interface thermal resistance data. The present disclosure also relates to a bio-sensing device suitable for the detection and/or characterization of target bioparticles.

Abstract: Systems, devices and methods are provided for acquiring, validating and analyzing athletic movement data. Generally, a sensor device, such as a force plate, is provided for sensing certain characteristics of an athletic movement. A local computing device coupled to the sensor device can be configured to receive sensor data indicative of the characteristics of the athletic movement, process and extract information from the sensor data, and transmit the processed sensor data to a remote server system. The remote server system can be configured to store, aggregate and update the processed sensor data in a database, and can also generate one or more normalized scores correlating to the athletic movement. The normalized scores can indicate to a user a susceptibility to injury, progression towards return to play or propensity for success with respect to a particular sport.

Abstract: The disclosure provides a frame assembly for suspending a rider from a trolley moving along a rail in a longitudinal direction. The frame assembly includes a bar fixedly mounted to the trolley transverse to the longitudinal direction. The frame assembly also includes a frame including: a horizontal segment positioned above a location for the rider; at least one vertical segment extending from the horizontal segment; and a substantially horizontal platform suspended from the vertical segment. The frame assembly also includes a pivot assembly including a first portion coupled to the trolley and a second portion coupled to the horizontal segment. The pivot assembly includes at least two axis of rotation between the first portion and the second portion. The frame assembly also includes a sway limiter connected between the bar and the horizontal segment limiting a range of movement of the pivot assembly.

Abstract: A method for training athletes is disclosed. The method comprises: calculating an athletic signature for an athlete comprising normalized values for the concentric net vertical impulse (CON-IMP), the average eccentric rate of force development (ECC-RFD), and the average vertical concentric force (CON-VF) for the athlete; analyzing the athletic signature; and assigning at least one training block to the athlete based on the analysis of the athletic signature.

Abstract: The present disclosure relates to a method for characterizing and identifying a bioparticle. The method comprises introducing the sample to a substrate having a surface comprising a plurality of binding sites whereon bioparticles can be bound, determining, for at least one temperature, data representative for the interface thermal resistance of the surface of the substrate sufficiently long to include the detachment process of the bioparticles, and deriving, for the at least one temperature, a bioparticle retention time and/or detachment rate from the data representative for the interface thermal resistance data. The present disclosure also relates to a bio-sensing device suitable for the detection and/or characterization of target bioparticles.

Abstract: A method for profiling an athlete is discloses. The method comprises storing force-time data for a population of athletes; wherein said force-time data is generated by a sensor system in respect of each of said plurality of athletes in response to the said athlete performing an athletic movement, and comprises values for a concentric net vertical impulse (CON-IMP), an average eccentric rate of force development (ECC-RFD), and an average vertical concentric force (CON-VF); performing a normalization of the force-time data for each athlete based on values of the force-time data within the population of athletes; and generating a profile comprising an athletic signature for each athlete in the population, wherein said profile comprises the normalized values for the concentric net vertical impulse (CON-IMP), the average eccentric rate of force development (ECC-RFD), and the average vertical concentric force (CON-VF) for the athlete.

Abstract: A system for analyzing athletic performance is disclosed. The system includes at least one sensor for sensing an aspect of an athletic movement for an athlete that varies during said movement an to generate sensor data corresponding thereto; and a processor for executing instructions to extract portions of the sensor data corresponding to a load phase, an explode phase, and a drive phase of the athletic movement.

Abstract: A bio-sensing device suitable for the detection and/or characterization of target bioparticles and corresponding method is described. The bio-sensing technique is based on the impact on the heat transfer resistivity value of bioparticles binding in binding cavities of a structured substrate. By sensing temperatures and determining a heat transfer resistivity value based thereon, a characteristic of the target bioparticles can be derived.

Abstract: A method an system is disclosed for the detection and/or allocation of at least one point mutation in target DNA and/or RNA duplexes. The method comprises obtaining a functionalized surface which is coated with probe DNA and/or RNA whereto target DNA and/or RNA duplexes are attached, contacting said functionalized surface to an electrolytic solution having a neutral pH in a flow cell and measuring a first impedance value within said electrolytic solution, and then adding a chemical to the electrolytic solution which is able to achieve denaturation of the target DNA and/or RNA. The method further comprises measuring a second impedance value within the flow cell after completion of the denaturation of the DNA and/or RNA target, and then obtaining a value representative for the impact of the chemical on the impedance of the electrolytic solution.

Abstract: The present disclosure relates to a biosensor device for detecting a predetermined target analyte. The device comprises a substrate. An aptamer bioreceptor for specifically binding to the predetermined target analyte is exposed at a functionalized surface of the substrate. The device also comprises a heat source for heating the substrate via a back surface thereof. The device further comprises a first temperature sensing element for sensing a temperature at the back side of the substrate and a second temperature sensing element for sensing a temperature at the functionalized side of the substrate. The device also comprises a signal processing unit for calculating a heat transfer resistivity value based on temperature values obtained from the first and the second temperature sensing element and the heating power generated by the heat source.

Abstract: A method an system is disclosed for characterizing DNA and/or RNA duplexes. The biosensing device comprises a heating element using a power and being suitable for providing thermal denaturation of target DNA and/or RNA bioparticles, a sample holder adapted for receiving a biocompatible substrate having a functionalized surface which is coated with probe DNA and/or RNA whereto target DNA and/or RNA duplexes can be attached, the sample holder further being adapted for exposing the biocompatible substrate at one side to the heating element, a first temperature sensing element for sensing a temperature at the side where the biocompatible substrate can be exposed to the heating element and a second temperature sensing element for sensing a temperature at the side opposite thereto with respect to the biocompatible substrate.