Abstract: A signal level detect circuit configured to assess an input signal with varying amplitude signal levels and to generate an indicator signal includes an input circuit configured to receive the input signal and to process the input signal, the input circuit including a first node on which the input signal is sampled; a comparator configured to compare the processed input signal to a signal level threshold and generate a comparator output signal; and an active discharge circuit configured to provide a first discharge current to the first node in response to the comparator output signal. The comparator output signal changes from a low output state to a high output state in response to the comparator input signal, and the active discharge circuit generates the first discharge current to discharge the sampled input signal on the first node after the comparator output signal changes to the high output state.

Abstract: A signal level detect circuit configured to assess an input signal with varying amplitude signal levels and to generate an indicator signal includes an input circuit configured to receive the input signal and to process the input signal, the input circuit including a first node on which the input signal is sampled; a comparator configured to compare the processed input signal to a signal level threshold and generate a comparator output signal; and an active discharge circuit configured to provide a first discharge current to the first node in response to the comparator output signal. The comparator output signal changes from a low output state to a high output state in response to the comparator input signal, and the active discharge circuit generates the first discharge current to discharge the sampled input signal on the first node after the comparator output signal changes to the high output state.

Abstract: A transmission line equalizer includes multiple signal paths connected in parallel between an equalizer input signal and an output amplifier where each signal path has a network implementing a specific frequency dependent response and each signal path implements current gain amplification with one or more of the signal paths having a variable gain programmed through a time invariant, DC programming signal. Furthermore, one or more of the signal paths implements linear-to-nonlinear signal transformations and compensating nonlinear-to-linear signal transformations to generate linearized output signals at the one or more signal paths. The equalizer further includes the output amplifier summing output signals from the multiple signal paths to generate an equalized output signal. In operation, the gain of the one or more signal paths is varied to establish the relative proportions of the output signals generated by each signal path and summed at the output amplifier.

Abstract: A transmission line equalizer includes multiple signal paths connected in parallel between an equalizer input signal and an output amplifier where each signal path has a network implementing a specific frequency dependent response and each signal path implements current gain amplification with one or more of the signal paths having a variable gain programmed through a time invariant, DC programming signal. Furthermore, one or more of the signal paths implements linear-to-nonlinear signal transformations and compensating nonlinear-to-linear signal transformations to generate linearized output signals at the one or more signal paths. The equalizer further includes the output amplifier summing output signals from the multiple signal paths to generate an equalized output signal. In operation, the gain of the one or more signal paths is varied to establish the relative proportions of the output signals generated by each signal path and summed at the output amplifier.

Abstract: A circuit is described for automatically adjusting a phase of an input register load clock to be synchronized with transitions of data bits forming an n-bit word. The circuit detects the first transition of a data bit in the n-bit word. The circuit then time-shifts the input clock, to generate a shifted clock, so that a triggering edge of the shifted clock occurs sometime after generation of the transition detect signal, such as in the middle third of a data cycle. Shifting the input clock may be performed by multiplying the input clock to generate a plurality of sub-clock cycles and selecting one of the sub-clock cycles as the start of the shifted clock cycle. The parallel data are applied to inputs of input registers clocked using the shifted clock as the load clock. Thus, the load clock occurs at an optimum time near the middle of a data cycle.

Abstract: A circuit is described for automatically adjusting a phase of an input register load clock to be synchronized with transitions of data bits forming an n-bit word. The circuit detects the first transition of a data bit in the n-bit word. The circuit then time-shifts the input clock, to generate a shifted clock, so that a triggering edge of the shifted clock occurs sometime after generation of the transition detect signal, such as in the middle third of a data cycle. Shifting the input clock may be performed by multiplying the input clock to generate a plurality of sub-clock cycles and selecting one of the sub-clock cycles as the start of the shifted clock cycle. The parallel data are applied to inputs of input registers clocked using the shifted clock as the load clock. Thus, the load clock occurs at an optimum time near the middle of a data cycle.