Abstract: Passive gate bias network topologies are implemented for stacked FET switch structures, which improve the settling time and low cut-off frequency for both DC and non-DC operation. DC capable stacked switch bias structures provide gate and bulk bias voltages, using input DC voltages, which are coupled to the gate terminals and the bulk terminals of the stacked switches. The DC coupling can be achieved using resistors, or a combination of resistors and diodes. An exemplary SPST switch includes a series stacked switch in combination with a shunt stacked switch, which can be controlled between alternating states. For low cut-off frequency improvement structures, an input signal is coupled to the gate terminals and bulk terminals of the switches in the stacked switches, using a DC block capacitor and resistors. The low cut-off of the bulk can be improved by connecting the bulk terminal of one switch to the opposite polarity switch.

Abstract: Mechanisms for evaluating amplitude for current pulses provided to a transimpedance amplifier (TIA) for current levels beyond the linear range of the TIA where clipping circuit(s) may limit the input voltage of the TIA are disclosed. In one aspect, an example TIA arrangement includes a clipping arrangement that includes multiple clipping circuits. Each clipping circuit can be biased by different bias voltages such that the different clipping circuits are activated at different input current amplitudes. Different clipping circuits can have different impedances, which can result in different recovery time characteristics. With the multiple clipping circuits in clipping arrangements discussed herein, a saturated dynamic range of a TIA can be divided into sub-regions and different pulse widening characteristics for each region may be defined, which may enable determination of amplitude for current pulses provided to the TIA even for current levels beyond the linear range of the TIA.

Abstract: Laser driver designs that aim to reduce or eliminate the problem of fault laser firing are disclosed. Various laser driver designs presented herein are based on providing a current dissipation path that is configured to start providing a resistance for dissipating at least a portion, but preferably substantially all, of the negative current from the laser diode. Dissipating at least a portion of the negative current may decrease the unintentional increase of the voltage at the input to the laser diode and, therefore, reduce the likelihood that fault laser firing will occur. A control logic may be used to control the timing of when the current dissipation path is activated (i.e., provides the resistance to dissipate the negative current from the laser diode) and when it is deactivated.

Abstract: Passive gate bias network topologies are implemented for stacked FET switch structures, which improve the settling time and low cut-off frequency for both DC and non-DC operation. DC capable stacked switch bias structures provide gate and bulk bias voltages, using input DC voltages, which are coupled to the gate terminals and the bulk terminals of the stacked switches. The DC coupling can be achieved using resistors, or a combination of resistors and diodes. An exemplary SPST switch includes a series stacked switch in combination with a shunt stacked switch, which can be controlled between alternating states. For low cut-off frequency improvement structures, an input signal is coupled to the gate terminals and bulk terminals of the switches in the stacked switches, using a DC block capacitor and resistors. The low cut-off of the bulk can be improved by connecting the bulk terminal of one switch to the opposite polarity switch.

Abstract: Laser driver designs that aim to reduce or eliminate the problem of fault laser firing are disclosed. Various laser driver designs presented herein are based on providing a current dissipation path that is configured to start providing a resistance for dissipating at least a portion, but preferably substantially all, of the negative current from the laser diode. Dissipating at least a portion of the negative current may decrease the unintentional increase of the voltage at the input to the laser diode and, therefore, reduce the likelihood that fault laser firing will occur. A control logic may be used to control the timing of when the current dissipation path is activated (i.e., provides the resistance to dissipate the negative current from the laser diode) and when it is deactivated.

Abstract: Mechanisms for evaluating amplitude for current pulses provided to a transimpedance amplifier (TIA) for current levels beyond the linear range of the TIA where clipping circuit(s) may limit the input voltage of the TIA are disclosed. In one aspect, an example TIA arrangement includes a clipping arrangement that includes multiple clipping circuits. Each clipping circuit can be biased by different bias voltages such that the different clipping circuits are activated at different input current amplitudes. Different clipping circuits can have different impedances, which can result in different recovery time characteristics. With the multiple clipping circuits in clipping arrangements discussed herein, a saturated dynamic range of a TIA can be divided into sub-regions and different pulse widening characteristics for each region may be defined, which may enable determination of amplitude for current pulses provided to the TIA even for current levels beyond the linear range of the TIA.