Systems and methods for communicating information related to a wearable device are disclosed. Exemplary information includes audio information.

According to one embodiment, an information collection system comprises a transmitter, a receiver, and a processor. The transmitter emits a signal. The receiver receives the signal. The processor calculates a distance between the transmitter and the receiver from a strength of the signal received by the receiver. The processor calculating the distance between the transmitter and the receiver from the strength of the signal for each of the signals received during a first interval, and using an average distance as the distance between the transmitter and the receiver, the average distance being obtained by averaging the plurality of calculated distances.

According to one embodiment, an information collection system comprises a transmitter, a receiver, and a processor. The transmitter emits a signal. The receiver receives the signal. The processor calculates a distance between the transmitter and the receiver from a strength of the signal received by the receiver. The processor calculating the distance between the transmitter and the receiver from the strength of the signal for each of the signals received during a first interval, and using an average distance as the distance between the transmitter and the receiver, the average distance being obtained by averaging the plurality of calculated distances.

A radio frequency (RF) device includes a spatial orientation sensor and logic circuit configured to determine spatial orientation of the RF device relative to a reference position or relative to a RF transmitter. In particular, the RF device determines a distance between the RF receiver and the RF transmitter based on a received signal strength of the signal and a determined spatial orientation of the RF device, by determining an orientation compensation value from a stored orientation compensation profile and determining a resulting compensated received signal strength. The RF device is thereby able to determine distance in an orientationally-invariant manner.

A remote control system for a vehicle having an onboard vehicle controller for controlling vehicle functions and a mobile radio remote control, connected to the vehicle controller in a signal-transmitting manner, for remotely controlling the vehicle functions according to a location of the radio remote control relative to the vehicle. The vehicle controller and the radio remote control each have at least one antenna for wireless signal transmission between the vehicle controller and the radio remote control. The antenna of the radio remote control has a direction-dependent antenna characteristic. At least one spatial position of the antenna of the radio remote control can be determined automatically by a position sensor device of the radio remote control, and an automatic determination of a distance or spatial location of the radio remote control relative to the vehicle can be processed according to the determined spatial position of the antenna.

A method includes estimating distances between a user device and an access point based on a series of FTM ranging bursts exchanged between the user device and the access point. The method also includes calculating a variance of the estimated distances and in response to determining that the variance exceeds a threshold, instructing the user device to perform an action that reduces the variance. Other embodiments include a device that performs this method.

A method includes estimating distances between a user device and an access point based on a series of FTM ranging bursts exchanged between the user device and the access point. The method also includes calculating a variance of the estimated distances and in response to determining that the variance exceeds a threshold, instructing the user device to perform an action that reduces the variance. Other embodiments include a device that performs this method.

Examples disclosed herein relate to determining a scale associated with received signal strength indicators (RSSIs). In one example, a computing device receives access point (AP) RSSIs. The RSSIs are determined at APs. The APs are associated with coordinate information. In one example, records are maintained for AP reference pairs. Each AP RSSI can be determined at one AP with reference to another AP. In one example, the computing device determines a scale associated with each record.

A system includes a transmitter for use in conjunction with a horizontal directional drilling system that transmits a multi-bit symbol stream that characterizes sensor symbols for receipt by an aboveground portable device. The portable device receives the symbol stream for aboveground recovery of the sensor signals. The transmitter can precisely place the symbol frequencies at least to avoid a noise environment, as well as to avoid powerline harmonics, and can utilize wave shaping for transmitted symbols at least to provide for transmission power control, spectral content control and wideband antenna matching. The receiver can measure the noise environment to identify the symbol frequencies used by the transmitter. The noise can be scanned at an incremental resolution across a wide frequency bandwidth for display or automatic symbol frequency selection.

A system for locating a mobile device emitting a radio frequency signal. A wireless access point device of a wireless local area network is configured to communicatively connect to a wide area network. The system comprises a first access device for wirelessly communicatively detecting a first signal strength of the radio frequency signal in relation to the first access device, a media access control (MAC) address, and a first timestamp of the first signal strength, of the mobile device; a second access device for wirelessly communicatively detecting a second signal strength of the radio frequency signal in relation to the second access device, the MAC address, and a second timestamp of the second signal strength, of the mobile device; a third access device for wirelessly communicatively detecting a third signal strength of the radio frequency signal in relation to the third access device, the MAC address, and a third timestamp of the third signal strength, of the mobile device.