Abstract: An apparatus for providing an indication of device to device communication capability may include a processor and a memory storing executable instructions. In response to execution of the instructions by the processor, the apparatus may perform at least receiving an indication with respect to status of an application or a request by the application, determining availability of a device to device connection associated with peer communication, and providing a notification to the application indicative of the availability of the device to device connection to the peer. A corresponding method and computer program product are also provided.

Abstract: In accordance with an example embodiment of the present invention, a method is disclosed that comprises measuring a first link quality of a first link based at least in part on a first power value; measuring a second link quality of a second link based at least in part on a second power value; and determining a suitable device-to-device (D2D) mode for a D2D connection based at least in part on the first link quality, the second link quality, and one or more D2D user equipment (UE) constraints.

Abstract: The invention relates to a method for controlling and/or regulating an industrial process for producing or processing products, wherein a physicomathematical model of the industrial process is formed, with which control parameters for controlling or regulating the industrial process are calculated during the production or processing of the product, a number of measurement values is detected, and the model is corrected with a number of primary correction factors, the number of primary correction factors being equal to the number of measurement values. The method is characterized in that the model is corrected with a number of secondary correction factors, such as with a correction factor reflecting the speed of the phase conversion in the rolling mill to be cooled, and in that the number of all correction factors is greater than the number of all measurement values, wherein at least the secondary correction factors are calculated numerically.

Abstract: A method for providing mobile device configuration may include a processor and a memory storing executable instructions that in response to execution by the processor cause the apparatus to at least perform at least receiving, remote from a mobile terminal, indications of configuration information defining appearance related features for a display of the mobile terminal, enabling provision of feedback to a user of the mobile terminal regarding the appearance related features, and providing the configuration information to the mobile terminal. A corresponding method and computer program product are also provided.

Abstract: A method for providing an information organization mechanism may include receiving indications of event occurrences related to applications associated with a device and combining, within the device, selected ones of the indications in an event log. The event log may include indications related to at least one external event and at least one internal event. The method may further include providing notification of the selected indications via display of at least a portion of the event log. An apparatus and computer program product corresponding to the method are also provided.

Abstract: Direct shaft power measurements of rotating machinery, including a magnetic encoding system for the shaft, having at least one conducting member having a first end and a second end which is disposed proximate the shaft with a gap between the member and the shaft. There is a pair of electrodes proximate each end of said conducting member, wherein the electrodes are electrically coupled to the shaft. One of the electrodes is electrically coupled to the second end of the conductor member. An encoding source is electrically coupled to the first end of the conducting member and electrically coupled to the other electrode, wherein unipolar current pulses from said encoding source are applied to the electrodes and the conducting member, thereby creating sectional encoded polarized magnetic regions in the shaft.

Abstract: Direct shaft power measurements of rotating machinery, including a magnetic encoding system for the shaft, having at least one conducting member having a first end and a second end which is disposed proximate the shaft with a gap between the member and the shaft. There is a pair of electrodes proximate each end of said conducting member, wherein the electrodes are electrically coupled to the shaft. One of the electrodes is electrically coupled to the second end of the conductor member. An encoding source is electrically coupled to the first end of the conducting member and electrically coupled to the other electrode, wherein unipolar current pulses from said encoding source are applied to the electrodes and the conducting member, thereby creating sectional encoded polarized magnetic regions in the shaft.

Abstract: A steel volume is modeled in a computer by means of a plurality of volume elements. The state of the steel volume at a given time comprises, for each volume element, characteristic quantities of an enthalpy existing at said time in the respective volume element and percentages, in which the steel is available in the respective volume element at the time in austenite, ferrite and cementite phases. For at least one volume element, the computer determines the time gradient of the characteristic quantities by resolving thermal conductivity and phase transition equations. One of the characteristic quantities is a locally invariable mean interstitial element concentration within the volume element in the austenite phase thereof.

Abstract: The temperature (T) of a metal (1) can be influenced directly or indirectly by at least one actuator (2) which is actuated in accordance with a control variable (S). The control variable (S) and starting values (TA, p1A, p2A) for a temperature of the metal (1) and phase proportions in which the metal (1) is at least in a first phase or a second phase, respectively, are predetermined for a material model (5). A heat conduction equation and a transformation equation are solved in real time within the material model (5), taking account of these variables (TA, p1A, p2A) , and in this way expected values (TE, p1E, p2E) are determined for these variables. As part of the transformation equation, the Gibbs' free energies (G1, G2) of the phases of the metal (1) are determined, a transformation rate of the metal (1) from the first phase to the second phase is determined therefrom, and the expected proportions (p1E, p2E) are determined from the latter.

Abstract: The present invention concerns a computer which determines a subsequent state of a steel volume, based on an instantaneous initial state of said steel volume and at least one volumetric surface, the temporary influence quantities acting on said steel volume, by resolution of an equation of thermal condition and phase change. The states include for at least one volumetric element of the steel volume, a local distribution in concentration of a alloy element mobile in the steel, the local proportions of the modeled phases of the steel and a quantity describing a local energy content of the steel. The phases comprise austenite and another phase, generally, ferrite or cementite. In the context of the change equation, the concentration levels of the mobile alloy element, which are located on either side of the phase boundary, between the austenite and the other phase are determined by resolution of the Stephan problem.

Abstract: To determine the temperature profile (Tm(t)) of a hot-rolled material (1) in a cooling line (5), a heat conduction equation which takes the following form ? e ? t - div ? [ ? ? ( e , p ) ? · grad ? ? ? T ? ( e , p ) ] = 0 where e is the enthalpy, ? the thermal conductivity, p the degree of phase transformation, ? the density and T the temperature of the rolled material at the rolled-material location and t is the time, is solved in a cooling-line model (4).

Abstract: The temperature (T) of a metal (1) can be influenced directly or indirectly by at least one actuator (2) which is actuated in accordance with a control variable (S). The control variable (S) and starting values (TA, p1A, p2A) for a temperature of the metal (1) and phase proportions in which the metal (1) is at least in a first phase or a second phase, respectively, are predetermined for a material model (5). A heat conduction equation and a transformation equation are solved in real time within the material model (5), taking account of these variables (TA, p1A, p2A) , and in this way expected values (TE, p1E, p2E) are determined for these variables. As part of the transformation equation, the Gibbs' free energies (G1, G2) of the phases of the metal (1) are determined, a transformation rate of the metal (1) from the first phase to the second phase is determined therefrom, and the expected proportions (p1E, p2E) are determined from the latter.

Abstract: To determine the temperature profile (Tm(t)) of a hot-rolled material (1) in a cooling line (5), a heat conduction equation which takes the following form 1 ∂ e ∂ t - div ⁡ [ λ ⁡ ( e , p ) ρ · grad ⁢   ⁢ T ⁡ ( e , p ) ] = 0

Abstract: A personal computer for a handicapped person includes an input panel that is subdivided into a group of fields, with one of the fields designated as a central field for the group. Each field is, in turn, subdivided into nine elements (spaces) comprised of a neutral central element surrounded by eight output elements. Each of those eight output elements has an output character representing a respective output signal. A mark (cursor) is moved across the panel by a control stick that is manipulated by a user. The cursor is always initially located at the center element of the central field. In order to move the cursor to a desired output element, the user: (a) identifies the field in which the desired output character is located, (b) moves the cursor in a first direction to the central element of that identified field, and (c) moves the cursor by one space directly to the desired output element in a second direction oriented either orthogonally or diagonally to the first direction.

Abstract: A process for the preparation of light-colored, electrically conductive pigments based on substrates having an expansion of not more than 500 .mu.m, which pigments consist of one or more metals, metal oxides or materials containing metal oxide, silicon oxide or silicate materials and contain, if desired above one or more other metal oxide and/or silicon oxide layers, an outer layer based on halogen-doped tin oxide and/or titanium oxide.