Abstract: Systems, apparatuses and methods may provide for technology to improve a workout experience of a user by determining an emotional state of the user, identifying a workout route based on the emotional state of the user, and outputting the workout route via a user interface device. Additionally, determining the emotional state of the user may include inferring emotions from one or more sensor information or user speech information. In one example, the sensor information includes one or more of blood pressure signals, heart rate signals or sweat measurement signals and the user speech information includes one or more of words used in an input utterance or a prosody of the input utterance.

Abstract: Systems, apparatuses and methods may provide for technology to improve a workout experience of a user by determining an emotional state of the user, identifying a workout route based on the emotional state of the user, and outputting the workout route via a user interface device. Additionally, determining the emotional state of the user may include inferring emotions from one or more sensor information or user speech information. In one example, the sensor information includes one or more of blood pressure signals, heart rate signals or sweat measurement signals and the user speech information includes one or more of words used in an input utterance or a prosody of the input utterance.

Abstract: Systems, apparatuses and methods may provide for technology to improve a workout experience of a user by determining an emotional state of the user, identifying a workout route based on the emotional state of the user, and outputting the workout route via a user interface device. Additionally, determining the emotional state of the user may include inferring emotions from one or more sensor information or user speech information. In one example, the sensor information includes one or more of blood pressure signals, heart rate signals or sweat measurement signals and the user speech information includes one or more of words used in an input utterance or a prosody of the input utterance.

Abstract: The system may include data gathering circuitry to collect audio, video, and biometric data generated by a speaker during a presentation. All or a portion of the collected audio, video, and biometric data may be stored or otherwise retained on one or more storage devices. All or a portion of the collected audio, video, and biometric data may be forwarded to the presentation analysis circuitry. The presentation analysis circuitry detects at least one of: an audio presentation event; a video presentation event; or a biometric presentation event based at least in part on the collected audio, video, and biometric data received from the data gathering circuitry. The presentation analysis circuitry forwards the detected audio presentation event; a video presentation event; or a biometric presentation event to the presenter feedback circuitry. The presenter feedback circuitry generates feedback for presentation to the speaker.

Abstract: A true random number generator including a transistor, a first voltage source, a second voltage source, and a comparator. The transistor has a first electrode, a second electrode, and a third electrode. Two of the electrodes are electrically connected by a channel of conductive nanomaterial. The first voltage source is electrically connected to the first electrode and the second voltage source is electrically connected to the second electrode. The comparator is electrically connected to the third electrode and is configured to classify a measured electrical property at the third electrode as either HIGH or LOW based on a comparison of the measured electrical property with a reference value. The measured electrical property varies over time due to random telegraph signals (RTSs) due to defects in the transistor.

Abstract: A true random number generator including a transistor, a first voltage source, a second voltage source, and a comparator. The transistor has a first electrode, a second electrode, and a third electrode. Two of the electrodes are electrically connected by a channel of conductive nanomaterial. The first voltage source is electrically connected to the first electrode and the second voltage source is electrically connected to the second electrode. The comparator is electrically connected to the third electrode and is configured to classify a measured electrical property at the third electrode as either HIGH or LOW based on a comparison of the measured electrical property with a reference value. The measured electrical property varies over time due to random telegraph signals (RTSs) due to defects in the transistor.

Abstract: A system includes a very low frequency (VLF) antenna connected to a circuit that has a high pass filter and a low pass filter. The circuit is configured for noise reduction and frequency localization of detected VLF signals. A receiver is configured to receive filtered VLF signals output by the circuit and to separate desired signals for processing. A display is configured to provide a user with visual feedback based at least in part on an even signature extracted by a digital signal processor (DSP).

Abstract: A method to create an electromagnetic Doppler surface comprising the steps of using an array of conductive elements, wherein the conductive elements mechanically move in individual orbits, and wherein the conductive elements are configured to combine and form a Doppler surface; using mechanical, phase-induced motion as a mechanism by which to move the conductive elements in individual orbits; creating a surface with a controllable Doppler return using two-dimensional motion.

Abstract: A reconfigurable metamaterial apparatus, having a metamaterial structure capable of focusing incoming radiation, the incoming radiation having at least one of a normal incoming radiation and an off-axis incoming radiation. The metamaterial structure has a matrix frame structure and an array of elements disposed in relation to the matrix frame structure. The array has a refractive index gradient profile. Each element has a material with a specific refractive index corresponding to its location in the array; and each element has an alterability feature for facilitating selectively altering its refractive index. The alterability feature has at least one of an interchangeability feature and a tunability feature. The refractive index gradient profile is at least one of tunable and optimizable for at least one parameter of focal stength and frequency, whereby undesirable signals from the incoming radiation are wave-guidable for areal dissipation, and whereby delicate equipment is protectable.

Abstract: A method involves using one or more software programs to stress a powered electronic device in a test environment to induce controlled electromagnetic emissions from the powered electronic device, using the controlled electromagnetic emissions to generate an emission profile of the powered electronic device operating under stress, monitoring spurious electromagnetic emissions of the powered electronic device in an operational environment, and comparing the spurious electromagnetic emissions of the powered electronic device in the operational environment with the emission profile of the powered electronic device to determine that the powered electronic device is operating under stress in the operational environment.

Abstract: An apparatus, system, and method are provided for a vertical two-terminal nanotube or microtube device configured to capture and generate energy, to store electrical energy, and to integrate these functions with power management circuitry. The vertical device can include a column disposed in a template material extending from one side of the template material to the other side of the template material. Further, the device can include a first material disposed within the column, a second material disposed within the column, and a third material disposed in the column. A variety of configurations, variations, and modifications are provided.

Abstract: Systems, apparatuses and methods may provide for technology to improve a workout experience of a user by determining an emotional state of the user, identifying a workout route based on the emotional state of the user, and outputting the workout route via a user interface device. Additionally, determining the emotional state of the user may include inferring emotions from one or more sensor information or user speech information. In one example, the sensor information includes one or more of blood pressure signals, heart rate signals or sweat measurement signals and the user speech information includes one or more of words used in an input utterance or a prosody of the input utterance.

Abstract: Technologies for interpreting an input from a user of a compute device are disclosed. The compute device may capture input data from, for example, a microphone. The compute device is configured to recognize the speech in the input data, and determines one or more semantic interpretations of the input data. The compute device ranks the semantic interpretations, and selects and applies one of the semantic interpretations. In ranking the semantic interpretations, the compute device may consider factors such as the dialogue history and the dialogue coherence of the semantic interpretations, as well as the confidence of how well each semantic interpretation matches the input data.

Abstract: The present invention is a method of controlling the perforation of crystalline grains in a layer of material. The first step of the method creates at least one crystalline layer composed of multiple grains and at least one grain boundary. Next, a material covers the grain boundaries to create a protective, reinforcing coating on the crystalline layer. Finally, an etching process creates perforations in the grains while the grain boundaries are protected from etching by the coating.

Abstract: An apparatus, system, and method are provided for a vertical two-terminal nanotube or microtube device configured to capture and generate energy, to store electrical energy, and to integrate these functions with power management circuitry. The vertical device can include a column disposed in a template material extending from one side of the template material to the other side of the template material. Further, the device can include a first material disposed within the column, a second material disposed within the column, and a third material disposed in the column. A variety of configurations, variations, and modifications are provided.

Abstract: The present invention is a method of controlling the perforation of crystalline grains in a layer of material. The first step of the method creates at least one crystalline layer composed of multiple grains and at least one grain boundary. Next, a material covers the grain boundaries to create a protective, reinforcing coating on the crystalline layer. Finally, an etching process creates perforations in the grains while the grain boundaries are protected from etching by the coating.

Abstract: An apparatus, system, and method are provided for a vertical two-terminal nanotube device configured to capture and generate energy, to store electrical energy, and to integrate these functions with power management circuitry. The vertical nanotube device can include a column disposed in an anodic oxide material extending from a first distal end of the anodic oxide material to a second distal end of the anodic oxide material. Further, the vertical nanotube device can include a first material disposed within the column, a second material disposed within the column, and a third material disposed between the first material and the second material. The first material fills the first distal end of the column and extends to the second distal end of the column along inner walls of the column. The second material fills the first distal end of the column and extends to the second distal end of the column within the first material.

Abstract: An apparatus, system, and method are provided for a lateral two-terminal nanotube device configured to capture and generate energy, to store electrical energy, and to integrate these functions with power management circuitry. The lateral nanotube device can include a substrate, an anodic oxide material disposed on the substrate, and a column disposed in the anodic oxide material extending from one distal end of the anodic oxide material to another end of the anodic oxide material. The lateral nanotube device further can include a first material disposed within the column, and a second material disposed within the column. The first material fills a distal end of the column and gradiently decreases towards another distal end of the column along inner walls of the column. The second material fills the another distal end of the column and gradiently decreases towards the distal end of the column within the first material.

Abstract: An apparatus, system, and method are provided for a vertical two-terminal nanotube device configured to capture and generate energy, to store electrical energy, and to integrate these functions with power management circuitry. The vertical nanotube device can include a column disposed in an anodic oxide material extending from a first distal end of the anodic oxide material to a second distal end of the anodic oxide material. Further, the vertical nanotube device can include a first material disposed within the column, a second material disposed within the column, and a third material disposed between the first material and the second material. The first material fills the first distal end of the column and extends to the second distal end of the column along inner walls of the column. The second material fills the first distal end of the column and extends to the second distal end of the column within the first material.

Abstract: An apparatus, system, and method are provided for a lateral two-terminal nanotube device configured to capture and generate energy, to store electrical energy, and to integrate these functions with power management circuitry. The lateral nanotube device can include a substrate, an anodic oxide material disposed on the substrate, and a column disposed in the anodic oxide material extending from one distal end of the anodic oxide material to another end of the anodic oxide material. The lateral nanotube device further can include a first material disposed within the column, and a second material disposed within the column. The first material fills a distal end of the column and gradiently decreases towards another distal end of the column along inner walls of the column. The second material fills the another distal end of the column and gradiently decreases towards the distal end of the column within the first material.