Abstract: A biasing circuit is presented. The biasing circuit includes a primary biasing circuit, a replica circuit and an amplifier. The primary circuit provides a biasing voltage and a primary voltage. The biasing voltage is the output of the biasing circuit. The replica biasing circuit provides a replica voltage. The replica biasing circuit includes a first resistive element said first resistive element having a resistive characteristics; a first current source said first current source having the first resistive element for generating a current as a function of the first resistive element; a first node to couple to receive the first current source to generate the replica voltage at the first node; a second current source; a second node to coupled to receive the second current source, and a second resistive element coupled between the first noted and the second node, said second resistive element having substantially similar resistive characteristics to that of the first resistive element.

Abstract: A slew-rate controlled driver circuit in an integrated circuit fabricated in a low voltage CMOS process, having an input node and an output node. A PMOS pull-up transistor is provided, having a source connected to one side of a power supply, having a gate, and having a drain connected to the output node. The PMOS transistor also has a parasitic capacitance between its gate and drain, having a value that may vary from one integrated circuit to the next from process variations and in response to varying circuit conditions. A current source generates a current having a level corresponding to the value of the parasitic capacitance, and to provide that current to the gate of the PMOS transistor. A level shifter receives an input signal having a voltage varying in a first range provides as output signal to the gate of the PMOS transistor shifted to a level suitable for the PMOS transistor.

Abstract: A slew-rate controlled driver circuit in an integrated circuit fabricated in a low voltage CMOS process, having an input node and an output node. A PMOS pull-up transistor is provided, having a source connected to one side of a power supply, having a gate, and having a drain connected to the output node. The PMOS transistor also has a parasitic capacitance between its gate and drain, having a value that may vary from one integrated circuit to the next from process variations and in response to varying circuit conditions. A current source generates a current having a level corresponding to the value of the parasitic capacitance, and to provide that current to the gate of the PMOS transistor. A level shifter receives an input signal having a voltage varying in a first range provides as output signal to the gate of the PMOS transistor shifted to a level suitable for the PMOS transistor.

Abstract: A biasing circuit is presented. The biasing circuit includes a primary biasing circuit, a replica circuit and an amplifier. The primary circuit provides a biasing voltage and a primary voltage. The biasing voltage is the output of the biasing circuit. The replica biasing circuit provides a replica voltage. The replica biasing circuit includes a first resistive element said first resistive element having a resistive characteristics; a first current source said first current source having the first resistive element for generating a current as a function of the first resistive element; a first node to couple to receive the first current source to generate the replica voltage at the first node; a second current source; a second node to coupled to receive the second current source, and a second resistive element coupled between the first noted and the second node, said second resistive element having substantially similar resistive characteristics to that of the first resistive element.

Abstract: A gate leakage insensitive current mirror circuit including an input stage, an output stage, and a pair of complementary source followers. The pair of complementary source followers is connected between the input stage and the output stage. In operation, the input stage receives an input current and the pair of complementary source followers receives a first current source and a second current source. The output stage then provides an output current. The complementary source followers form a negative feedback loop and establish a bias voltage for the input stage and the output stage as a function of the input current that is independent of gate leakage between the input stage and the output stage.

Abstract: A gate leakage insensitive current mirror circuit including an input stage, an output stage, and a pair of complementary source followers. The pair of complementary source followers is connected between the input stage and the output stage. In operation, the input stage receives an input current and the pair of complementary source followers receives a first current source and a second current source. The output stage then provides an output current. The complementary source followers form a negative feedback loop and establish a bias voltage for the input stage and the output stage as a function of the input current that is independent of gate leakage between the input stage and the output stage.

Abstract: Various systems and methods for common mode detection are disclosed. As one example, a common mode detection circuit including a differential input stage, a common mode replica stage, and an amplifier is disclosed. The differential input stage exhibits an input common mode, and includes two differential inputs. A signal from the differential input stage representing the input common mode is electrically coupled to an input of the amplifier. Another input of the amplifier is electrically coupled to the common mode replica stage, and the amplifier outputs a signal indicative of the input common mode.

Abstract: A low distortion filter circuit implementing variable gain amplification (VGA). An aspect of the present invention increases the degrees of freedom (number of components which can be independently programmed/changed to corresponding desired values) to achieve a desired combination of D.C. gain and filter characteristics (e.g., corner frequency, Q-factor, notch frequency, etc.). Such additional degrees of freedom are attained by including additional components in either on input block or a feedback block (implemented with reference to an operational amplifier), and by redesigning the other block using principles such as admittance concellation to remove the effects of such additional components. The blocks are designed such that a terminal of the programmable components is connected to a fixed/constant voltage (e.g., ground). Embodiments implementing bi-quad single amplifier with and without notch are disclosed.

Abstract: A low distortion filter circuit implementing variable gain amplification (VGA). An aspect of the present invention increases the degrees of freedom (number of components which can be independently programmed/changed to corresponding desired values) to achieve a desired combination of D.C. gain and filter characteristics (e.g., corner frequency, Q-factor, notch frequency, etc.). Such additional degrees of freedom are attained by including additional components in either an input block or a feedback block (implemented with reference to an operational amplifier), and by redesigning the other block using principles such as admittance cancellation to remove the effects of such additional components. The blocks are designed such that a terminal of the programmable components is connected to a fixed/constant voltage (e.g., ground). Embodiments implementing bi-quad single amplifier with and without notch are disclosed.