Abstract: An apparatus and a method, the apparatus comprising: a temperature compensated oscillator; satellite positioning circuitry; and a temperature sensor configured to provide a first control output to the temperature compensated oscillator and to provide a second control output to the satellite positioning circuitry.

Abstract: A method including: using both dedicated circuitry and a programmable processor system for acquisition of a communication channel; and using the dedicated circuitry for tracking the acquired communication channel while using the programmable processor system for hosting an application that uses information dependent upon data dependent on the acquired communication channel.

Abstract: There is provided a method for assisting in providing a first fix in a global positioning satellite system, the method comprising: storing of connection point association data for a network connection point, observed by a portable electronic device, for subsequent use in assisting in providing a first fix, the connection point association data providing for approximation of the position of a device at the observed network connection point by associating together connection point identifiers of the observed network connection point and one or more other network connection points to allow for positional data used for determining the position at one or more other network connection points to be used for the approximation of the position of the device at the observed network connection point.

Abstract: An apparatus and a method, the apparatus comprising: a temperature compensated oscillator; satellite positioning circuitry; and a temperature sensor configured to provide a first control output to the temperature compensated oscillator and to provide a second control output to the satellite positioning circuitry.

Abstract: There is provided a method for assisting in providing a first fix in a global positioning satellite system, the method comprising: storing of connection point association data for a network connection point, observed by a portable electronic device, for subsequent use in assisting in providing a first fix, the connection point association data providing for approximation of the position of a device at the observed network connection point by associating together connection point identifiers of the observed network connection point and one or more other network connection points to allow for positional data used for determining the position at one or more other network connection points to be used for the approximation of the position of the device at the observed network connection point.

Abstract: A dual mode device (110) comprising a communications block (120) and a satellite positioning block (130), each comprising respective Base Band (BB) blocks (123, 132) and crystals or frequency sources (122, 1312). The communications crystal (122) provides a cellular clock signal (FS1) to the satellite positioning block (130), which monitors the difference in the frequencies the crystals produce (FS1, FS2), using Vernier interpolation to gain a resolution greater than one clock cycle. The positioning crystal (1312) is used independent of the cellular crystal to demodulate satellite signals. The positioning BB (132) tracks the demodulated satellite signals compensating any errors caused by the positioning crystal signals (FS2) to the demodulation, using the information resulting from the monitoring. The communications crystal is capable to network based calibration and the positioning BB can compensate for the fluctuation thus caused in the cellular clock signal (FS1).

Abstract: A method including: using both dedicated circuitry and a programmable processor system for acquisition of a communication channel; and using the dedicated circuitry for tracking the acquired communication channel while using the programmable processor system for hosting an application that uses information dependent upon data dependent on the acquired communication channel.

Abstract: A dual mode device (110) comprising a communications block (120) and a satellite positioning block (130), each comprising respective Base Band (BB) blocks (123, 132) and crystals or frequency sources (122, 1312). The communications crystal (122) provides a cellular clock signal (FS1) to the satellite positioning block (130), which monitors the difference in the frequencies the crystals produce (FS1, FS2), using Vernier interpolation to gain a resolution greater than one clock cycle. The positioning crystal (1312) is used independent of the cellular crystal to demodulate satellite signals. The positioning BB (132) tracks the demodulated satellite signals compensating any errors caused by the positioning crystal signals (FS2) to the demodulation, using the information resulting from the monitoring. The communications crystal is capable to network based calibration and the positioning BB can compensate for the fluctuation thus caused in the cellular clock signal (FS1).