Abstract: On-hoard equipment in a motor vehicle includes a C-V2X communication device receiving a first signal from road side equipment having a known position. The C-V2X communication device transmits a second signal having content that is dependent upon a length of time in which the first signal traveled from the road side equipment to the C-V2X communication device. A GPS device is communicatively coupled to the C-V2X communication device and receives the second signal from the C-V2X communication device. The GPS device estimates a position of the vehicle. The estimating is dependent upon the second signal from the C-V2X communication device.

Abstract: On-board equipment in a motor vehicle includes a C-V2X communication device receiving a first signal from road side equipment having a known position. The C-V2X communication device transmits a second signal having content that is dependent upon a length of time in which the first signal traveled from the road side equipment to the C-V2X communication device. A GPS device is communicatively coupled to the C-V2X communication device and receives the second signal from the C-V2X communication device. The GPS device estimates a position of the vehicle. The estimating is dependent upon the second signal from the C-V2X communication device.

Abstract: On-board equipment for a motor vehicle includes a DSRC radio receiving a signal from road side equipment. The signal has an accurate frequency in accordance with GPS time. A GPS receiver is communicatively coupled to the DSRC radio. The on-board equipment determines the error in the GPS receiver clock or time and provides the GPS receiver with the time error. The determining of the GPS receiver time error is dependent upon the accurate frequency in the air-borne RSE signal. The GPS time error or compensation is dependent upon the GPS accurate time.

Abstract: The disclosed embodiments relate to a communication device (200) that implements a subset of feature choices selected from a complete set of feature choices. An exemplary embodiment comprises at least one common hardware component (210) common to any subset of feature choices, and a base (102) that is adapted to accommodate installation of at least one optional hardware component (221) associated with at least one feature of the complete set of feature choices.

Abstract: A method of manufacturing a radio frequency receiver module includes supporting a baseband processor on a base. A feature choice for the module is determined. The feature choice includes an antenna type, an RF type, or a stack type. An optional hardware component is selectively installed or omitted on the base dependent upon the determined feature choice.

Abstract: There is disclosed an electrostatic discharge (ESD) protection device and method. An electronic device (100) that employs an exemplary embodiment of the present invention comprises an electronic component (106) having a signal input conductor (302). An exemplary ESD protection circuit (200) includes a spark gap (204) in series with a high pass quarter wave transformer (208). The exemplary ESD protection circuit (200) is adapted to discharge an ESD pulse from the signal input conductor (302) of the electronic component (106) to a ground plane (304) via the spark gap (204) and/or the high pass quarter wave transformer (208).

Abstract: A method of operating a radio having a plurality of station preset pushbuttons includes assigning to the preset pushbuttons a first group of radio frequencies associated with a first country. A spectrum of radio frequencies is scanned. A signal quality metric is measured for each of the scanned frequencies. A country of origin is determined for each of the scanned frequencies. A country in which the radio is disposed is ascertained dependent upon the measuring step and the determining step. If the country in which the radio is disposed is different from the first country, then either the preset pushbuttons are automatically re-assigned to a second group of radio frequencies associated with the country in which the radio is disposed, or a user is provided with an option to re-assign the preset pushbuttons to the second group of radio frequencies.

Abstract: There is disclosed an electrostatic discharge (ESD) protection device and method. An electronic device (100) that employs an exemplary embodiment of the present invention comprises an electronic component (106) having a signal input conductor (302). An exemplary ESD protection circuit (200) includes a spark gap (204) in series with a high pass quarter wave transformer (208). The exemplary ESD protection circuit (200) is adapted to discharge an ESD pulse from the signal input conductor (302) of the electronic component (106) to a ground plane (304) via the spark gap (204) and/or the high pass quarter wave transformer (208).

Abstract: An input signal (IN) is filtered (605) to remove aliases and a switched capacitor network (610) undersamples this signal to provide a downconverted, near-baseband signal. An amplifier (615) adjusts the amplitude of this signal to match a digitizer (620). The digitized output is converted into first phase and second phase signals which are then filtered (640) and decimated (645) to further reduce the sampling rate. The downconverted first and second phase signals, rather than higher frequency signals, control the gain function (AGC) for the amplifier (615). The switched capacitor network (610) provides for both tuning and downconversion of the desired signal to a lower frequency for further processing, thus reducing the frequency and power requirements of an associated amplifier and analog-to-digital converter (digitizer).

Abstract: An input signal (IN) is filtered (605) to remove aliases and a switched capacitor network (610) undersamples this signal to provide a downconverted, near-baseband signal. An amplifier (615) adjusts the amplitude of this signal to match a digitizer (620). The digitized output is converted into first phase and second phase signals which are then filtered (640) and decimated (645) to further reduce the sampling rate. The downconverted first and second phase signals, rather than higher frequency signals, control the gain function (AGC) for the amplifier (615). The switched capacitor network (610) provides for both tuning and downconversion of the desired signal to a lower frequency for further processing, thus reducing the frequency and power requirements of an associated amplifier and analog-to-digital converter (digitizer).