Abstract: Creating a low-bandwidth channel in a high-bandwidth channel. By taking advantage of extra bandwidth in a high-bandwidth channel, a low-bandwidth channel is created by inserting extra packets. When an inter-packet gap of the proper duration is detected, the extra packet is inserted and any incoming packets on the high-bandwidth channel are stored in an elastic buffer. Observing inter-packet gaps, minimal latency is introduced in the high-bandwidth channel when there is no extra packet in the process of being sent, and the effects of sending a packet on the low-bandwidth channel are absorbed and distributed among other passing traffic.

Abstract: Creating a low-bandwidth channel in a high-bandwidth channel. By taking advantage of extra bandwidth in a high-bandwidth channel, a low-bandwidth channel is created by inserting extra packets. When an inter-packet gap of the proper duration is detected, the extra packet is inserted and any incoming packets on the high-bandwidth channel are stored in an elastic buffer. Observing inter-packet gaps, minimal latency is introduced in the high-bandwidth channel when there is no extra packet in the process of being sent, and the effects of sending a packet on the low-bandwidth channel are absorbed and distributed among other passing traffic.

Abstract: Creating a low-bandwidth channel in a high-bandwidth channel. By taking advantage of extra bandwidth in a high-bandwidth channel, a low-bandwidth channel is created by inserting extra packets. When an inter-packet gap of the proper duration is detected, the extra packet is inserted and any incoming packets on the high-bandwidth channel are stored in an elastic buffer. Observing inter-packet gaps, minimal latency is introduced in the high-bandwidth channel when there is no extra packet in the process of being sent, and the effects of sending a packet on the low-bandwidth channel are absorbed and distributed among other passing traffic.

Abstract: A circuit and method for receiving digital signals are disclosed. The circuit includes an input connected to a communications channel over which a digital signal is communicated and operates a plurality of multiple decision circuits at a frequency that is a fraction of the bit rate of the digital signal. A feedback and/or equalizer circuit receives the output of the decision circuits and applies a feedback signal to the input of the decision circuits that is representative of a combination of output signals of the decision circuits. The result is seen to improve the noise margin for correctly interpreting signals communicated over a communications channel having a low-pass characteristic.

Abstract: A circuit and method for receiving digital signals are disclosed. The circuit includes an input connected to a communications channel over which a digital signal is communicated and operates a plurality of multiple decision circuits at a frequency that is a fraction of the bit rate of the digital signal. A feedback and/or equalizer circuit receives the output of the decision circuits and applies a feedback signal to the input of the decision circuits that is representative of a combination of output signals of the decision circuits. The result is seen to improve the noise margin for correctly interpreting signals communicated over a communications channel having a low-pass characteristic.

Abstract: An analog-to-digital converter (ADC) (112) for sampling high speed video signals includes Pre-amplifiers (502, 504, 506) electrically coupled to Post-amplifiers (508, 510, 512) that are electrically coupled to output latches (514, 517, 519, 521, 523, 525, and 527). A sampling clock signal (116) clocks the output latches (514, 517, 519, 521, 523, 525, and 527) to sample an input analog electronic signal to provide a digital representation thereof. The ADC (112) includes an auto-zeroing function to cancel bias voltages at the Post-amplifiers (508, 510, 512) during a video signal horizontal blanking time period. The ADC (112) includes a bit dithering function by alternating sets of reference voltages into the Pre-amplifiers (502, 504, 506) increasing bit resolution. The ADC (112) includes wired interconnect interpolation between the Pre-amplifiers (502, 504, 506) and Post-amplifiers (508, 510, 512) and between the Post-amplifiers (508, 510, 512) and the output latches (514, 517, 519, 521, 523, 525, and 527).

Abstract: An analog-to-digital converter (500) for sampling high speed video signals includes a first input (502) for receiving an electronic signal, a sampling clock input (547) for receiving a sampling clock signal, and first and second sampling circuits. The first sampling circuit is arranged in a differential circuit arrangement, and is electrically connected to the first input (502) and to the sampling clock input (547) and is responsive to the sampling clock signal, for sampling the electronic signal to provide a pair of boundary reference voltage signals (706, 708, 710, 712) that bound the voltage of the sampled electronic signal, and further to convert the sampled electronic signal to provide the most significant bits (554) of a digital representation of the electronic signal at times indicated by the sampling clock signal.

Abstract: An analog-to-digital converter (500) for sampling high speed video signals includes a first input (502) for receiving an electronic signal, a sampling clock input (547) for receiving a sampling clock signal, and first and second sampling circuits. The first sampling circuit is arranged in a differential circuit arrangement, and is electrically connected to the first input (502) and to the sampling clock input (547) and is responsive to the sampling clock signal, for sampling the electronic signal to provide a pair of boundary reference voltage signals (706, 708, 710, 712) that bound the voltage of the sampled electronic signal, and further to convert the sampled electronic signal to provide the most significant bits (554) of a digital representation of the electronic signal at times indicated by the sampling clock signal.