Abstract: Equalization circuits and methods are implemented for a variety of applications. According to one such application, a transmitting device wirelessly communicates using an antenna. The device has a transmission circuit that is configured and arranged to transmit a first wireless signal using magnetic coupling between the antenna and a remote device, the coupling occurring over a wireless medium. A receiver circuit of the transmitting device is configured and arranged to receive a second wireless signal that is from the antenna and that represents the first wireless signal as modified by the coupling occurring over the wireless medium. An error circuit of the device is configured and arranged to generate an error signal by comparing the first wireless signal to the second wireless signal. An equalizer circuit of the device is configured and arranged to pre-code the first wireless signal with coding that compensates for inter-symbol interference by compensating for the error signal.

Abstract: A symbol clock recovery circuit is provided for a data communication system using coherent demodulation. The symbol clock recovery circuit comprises an analog-to-digital converter comprising a first input for receiving a coherent-detected baseband analog signal derived from a carrier signal, a second input for receiving an adapted symbol clock signal, and an output for outputting a digital signal comprising a frame having a preamble with at least two symbols. The symbol clock recovery circuit comprises further a phase shifting unit comprising a first input for receiving a symbol clock signal derived from the carrier signal, and a timing detector, comprising a first input for receiving the digital signal from the analog-to-digital converter and an output for providing a signal comprising information about an optimum sample phase to the phase shifting unit.

Abstract: The present invention relates to a gigitaol phaselocked loop DPLL (300, 400) having a phase-to-digital P2D (60) with an enhanced bang-bang phase detector BBPD. Such a P2D (60) comprises a BBPD (62), an additional digital circuit (200) including a sign detector (210), a counter (220) and a mapping function (230), and a summer block (64). During the locking process, the BBPD (62) may-output a repeating value, namely a string of data bits of same polarity value either “+1” or “?1”. The polarity sign is detected by the sign detector (210), and the data string length is determined by the counter (220) that is reset to zero whenever the BBPD output changes sign. The mapping function (230) is configured for mapping the data string length in input to the phase correction level in output Its output is added to that of the BBPD (62) through the summer block (64), such that the phase correction level is increased to enhance the locking process whenever a data string is detected.

Abstract: An oscillation signal with a selectable frequency is generated with a phase locked loop (10, 12, 14). The oscillator (10) of the loop receives a feedback signal, to which an offset is added in order to reduce transient effects when a frequency modification is made. A first and second offset control value are used to control the offset successively. The first offset control value is controlled by a combination of the frequency settings before and after the modification. The second offset control value is controlled by the frequency settings after the modification. The first and second offset control values are used to control an offset of applying to a frequency control signal of an oscillator (10) of the phase locked loop (10, 12, 14). The offset controlled by the first control offset value is applied during a predetermined time interval before the offset controlled by the second control offset value is applied.

Abstract: The invention proposes a smart card which comprises a digital signal processing receiver that can automatically identify the type of a smart card reader based on the error vector magnitude of signals received from the reader. The digital signal processing receiver is able to reconfigure itself at runtime in order to optimally minimize its power consumption in dependence on the type of reader it is communicating with. Furthermore, the invention proposes a new preamble structure that comprises a basic part and an optional additional part.

Abstract: The present invention proposes a control loop for receiving a reference signal r(t) and generating an output signal c(t) based on the reference signal r(t). The control loop comprises a subtracting element(320), a correcting element(330,350), a control path(340) and a storage element(360). The subtracting element(320) generates a difference signal d(t) including a difference between the reference signal r(t) and the output signal c(t). The correcting element (330,350) generates an adjusting signal b(t) based on the difference signal d(t). The control path(340) generates the output signal c(t) based on the adjusting signal b(t). And the storage element (360) stores at least one internal state of at least the correcting element(330,350) and applies the stored internal state to at least the correcting element(330,350) based on an instruction signal i(t).

Abstract: A frequency hopping receiver circuit has a frequency converter (12) and a hopping control circuit (14) coupled to the frequency converter (12), and configured to control frequency hopping of the received frequency, by controlling changes in frequency shift applied by the frequency converter (12). The frequency change is applied in combination with a temporary reduction in conversion gain of the frequency converter (12) during the change in frequency shift. The frequency converter may contain a mixer (122), a local oscillator circuit (120) and a controllable amplifier (124) coupled between the input of the frequency converter (12) and the mixer (122) or between the mixer (122) and the output of the frequency converter (12), or between the local oscillator circuit (120) and the local oscillator input of the mixer (122).

Abstract: An oscillation signal with a selectable frequency is generated with a phase locked loop (10, 12, 14). The oscillator (10) of the loop receives a feedback signal, to which an offset is added in order to reduce transient effects when a frequency modification is made. A first and second offset control value are used to control the offset successively. The first offset control value is controlled by a combination of the frequency settings before and after the modification. The second offset control value is controlled by the frequency settings after the modification. The first and second offset control values are used to control an offset of applying to a frequency control signal of an oscillator (10) of the phase locked loop (10, 12, 14). The offset controlled by the first control offset value is applied during a predetermined time interval before the offset controlled by the second control offset value is applied.

Abstract: A frequency generating arrangement for generation of at least two predetermined frequencies is introduced. The arrangement comprises a phase locked loop circuit with at least two control value storage units and at least one controlled oscillator unit, wherein the control value storage units being configured to selectively output a control signal to the at least one voltage controlled oscillator unit, causing generation of one of the at least two predetermined frequencies. Frequency generating system for generation of ultra-fast hopping-frequency sequences comprises at least a first and a second frequency generating arrangement and further a controlling unit and a multiplexer unit for selectively connecting only one of the outputs of the two frequency generating arrangements with an output of the system.

Abstract: The present invention relates to a gigitaol phaselocked loop DPLL (300, 400) having a phase-to-digital P2D (60) with an enhanced bang-bang phase detector BBPD. Such a P2D (60) comprises a BBPD (62), an additional digital circuit (200) including a sign detector (210), a counter (220) and a mapping function (230), and a summer block (64). During the locking process, the BBPD (62) may-output a repeating value, namely a string of data bits of same polarity value either “+1” or “?1”. The polarity sign is detected by the sign detector (210), and the data string length is determined by the counter (220) that is reset to zero whenever the BBPD output changes sign. The mapping function (230) is configured for mapping the data string length in input to the phase correction level in output Its output is added to that of the BBPD (62) through the summer block (64), such that the phase correction level is increased to enhance the locking process whenever a data string is detected.

Abstract: A frequency-hopping arrangement comprises a basic-frequency branch (DIV1), an offset-frequency branch (DIV2, DIV3, SCC), and a controllable frequency converter (SBM, FSC). The basic-frequency branch (DIV1) receives an oscillator signal (OS) having an oscillator-signal frequency (7920 MHz). The basic-frequency branch has a frequency-division factor (/2) so as to provide a basic-frequency signal (BF) having a basic frequency (+3960 MHz) that is the oscillator-signal frequency divided by the frequency-division factor. The offset-frequency branch (DIV2, DIV3, SCC) receives the same oscillator signal (OS). The offset-frequency branch has a different frequency-division factor (/3, /5) so as to provide an offset-frequency signal (OF) having an offset frequency (+528 MHz) that is the oscillator-signal frequency divided by the different frequency-division factor.

Abstract: The present invention relates to a phase-locked-loop (PLL) circuit and a method for controlling such a PLL circuit, wherein the frequency of an input reference signal and the frequency of a feedback signal derived from an output oscillation signal are divided by a predetermined rate to thereby reduce the frequency at a phase detection means (1) of the PLL circuit. The dividing step is inhibited in response to a detection of a phase-locked-state of the PLL circuit. Thus, after phase-lock has been achieved, extra reference dividers (6) added to decrease the comparison frequency are removed from the loop to thereby enable increase in the loop bandwidths and decrease in the dividing ratio within the loop.

Abstract: Devices (1) for exchanging ultra wide band signals comprise frequency translating stages (20,30) for frequency translating signals and oscillating stages (40) for supplying main inphase/quadrature oscillation signals to the frequency translating stages (20,30). By providing the oscillating stages (40) with polyphase filters (43,44) for reducing harmonics in oscillation signals, the main oscillation signals will be sufficiently clean. The oscillating stages (40) comprise mixers (46) for converting first inphase/quadrature oscillation signals and second inphase/quadrature oscillation signals into the main oscillation signals. The polyphase filters (43,44) may be located before and after the mixers (46). Frequency selectors (45) replace prior art multiplexers located after the mixers (46).

Abstract: A phase locked loop comprising a phase detector (100) for determining a phase difference between a reference signal (Ref) and mutually phase shifted signals (I, Q) to generate frequency control signals (U, D), the phase detector (100) comprising: means (10) for obtaining a first one of said frequency control signals (U, D) by binary multiplication of the reference signal (Ref) and one of the relative phase shifted signals (I, Q); and means (20) for obtaining a second one of said frequency control signals (U, D) by binary multiplication of the relative phase shifted signals (I, Q).