Abstract: Voltage and current mode reconfigurable nth-order filters (RNOFs) fabricated in a 0.18 ?m CMOS process are disclosed. The RNOFs utilize an inverse-follow-the-leader-feedback (IFLF) signal path with summed outputs, resulting in a follow-the-leader-feedback-summed-outputs (FLF-SO) filter topology. The FLF-SO filter uses multi-output current amplifiers (CAs). Inverse-follow-the-leader-feedback-summed-outputs (IFLF-SO) and inverse-follow-the-leader-feedback-distributed-outputs (IFLF-DI) structures are realized by employing 3n+4 transconductance amplifiers (TCAs) for voltage mode processing and two TCAs for current mode signals. A plurality of programmable current division networks (CDNs) tune a digitally controlled current follower (DCCF). A multi-output Digitally Controlled Current Amplifier (MDCCA) controls gain by providing independent filter coefficient control. Forward path output gains are set to unity. Alternatively, a multi-output digitally controlled CCII block (MDCCCII) uses CCII in the first stage.

Abstract: The fully integrated DC offset compensation servo feedback loop is an integrator that measures the output signal DC component, and then feeds back and subtracts the measured DC component from the input signal. A larger integrator time constant lowers the high pass corner frequency, which must be very small in order to minimize the loss of the low frequency component of the desired signals. The large time constant is achieved on an integrated circuit by the use of a class-AB fully differential opamp in conjunction with an R-2R ladder as a circuit element to accomplish an integrated large time constant integrator. The R-2R ladder is configured as a digitally programmable resistor.

Abstract: Voltage and current mode reconfigurable nth-order filters (RNOFs) fabricated in a 0.18 ?m CMOS process are disclosed. The RNOFs utilize an inverse-follow-the-leader-feedback (IFLF) signal path with summed outputs, resulting in a follow-the-leader-feedback-summed-outputs (FLF-SO) filter topology. The FLF-SO filter uses multi-output current amplifiers (CAs). Inverse-follow-the-leader-feedback-summed-outputs (IFLF-SO) and inverse-follow-the-leader-feedback-distributed-outputs (IFLF-DI) structures are realized by employing 3n+4 transconductance amplifiers (TCAs) for voltage mode processing and two TCAs for current mode signals. A plurality of programmable current division networks (CDNs) tune a digitally controlled current follower (DCCF). A multi-output Digitally Controlled Current Amplifier (MDCCA) controls gain by providing independent filter coefficient control. Forward path output gains are set to unity. Alternatively, a multi-output digitally controlled CCII block (MDCCCII) uses CCII in the first stage.

Abstract: The dual mode receiver channel select filter includes a filter for a dual mode Bluetooth/Wireless Local Area Network (WLAN) receiver portion of a BT/WLAN transceiver. The filter is a 4th order complex filter and is digitally programmable and reconfigurable. Implemented as the channel select filter for dual-mode receivers, the filter adopts low-IF for Bluetooth and zero-IF for WLAN (IEEE 802.11b). It is based on simple active elements, such as current and voltage followers. The center frequency is digitally tuned through programming active current division networks (CDNs).

Abstract: The digitally programmable active-RC filter provides an active-RC filter having programmable time constants. An inherently linear current division network (CDN) provides the programmable time constants while preserving a high linearity property of the active-RC filter. Using this approach, wide tuning characteristics are achieved. The programmable active-RC filter uses two op-amps per integrator. Cross-coupling two of the units configured with I and Q inputs provides the reconfigurable filter with a complex bandpass and normal lowpass response. One embodiment is formed as a fourth-order filter fabricated in a standard 0.18 ?m CMOS process. The complex and lowpass filters achieve in-band spurious-free dynamic ranges (SFDRs) of about 70 dB and 71 dB for bandwidths of 1 MHz and 5.5 MHz, respectively.

Abstract: The dual mode receiver channel select filter includes a filter for a dual mode Bluetooth/Wireless Local Area Network (WLAN) receiver portion of a BT/WLAN transceiver. The filter is a 4th order complex filter and is digitally programmable and reconfigurable. Implemented as the channel select filter for dual-mode receivers, the filter adopts low-IF for Bluetooth and zero-IF for WLAN (IEEE 802.11b). It is based on simple active elements, such as current and voltage followers. The center frequency is digitally tuned through programming active current division networks (CDNs).

Abstract: The digitally programmable high-order filter uses simple active elements, namely DCCAs and VBs, with the help of R-2R ladders to realize several nth-order filters, ‘n+3’ DCCAs and ‘n’ VBs may be used, and can provide programmability to either the filter's numerator coefficients or to the denominator coefficients. The digitally programmable high-order filter may include R-2R ladders in its negative feedback loops, resulting in a filter in which all coefficients are programmable.

Abstract: The low frequency notch filter integrated circuit is implemented in a relatively small silicon area and with high linearity, thereby promoting the utilization of very large-scale integration (VLSI) techniques in biomedical instrumentation. The filter circuit utilizes R-2R ladders providing area saving of approximately 120:1. R-2R ladders function as digitally programmable resistors in a biquad configured Operational Amplifier filter circuit. Integrator loop topologies are used in the filter circuit. The preferred topology utilizes a Tow-Thomas circuit, which can be designed for the prerequisite gain and Q independently selecting two resistors. In addition, the three op amps in the Tow-Thomas topology have their non-inverting input grounded, and therefore their inverting inputs will be held ideally at virtual ground. These feature permits the use of op amps with small common mode input range.