Abstract: A virus detection mechanism is described in which virus detection is provided by a network integrated protection (NIP) adapter. The NIP adapter checks incoming media data prior to it being activated by a computing device. The NIP adapter operates independently of a host processor to receive information packets from a network. This attribute of independence allows NIP anti-virus (AV) techniques to be “always on” scanning incoming messages and data transfers. By being independent of but closely coupled to the host processor, complex detection techniques, such as using check summing or pattern matching, can be efficiently implemented on the NIP adapter without involving central processor resources and time consuming mass storage accesses. The NIP adapter may be further enhanced with a unique fading memory (FM) facility to allow for a flexible and economical implementation of polymorphic virus detection.

Abstract: A digitally programmable analog receive-side channel equalizer includes N identical zero-positioning (ZP) circuit pairs in a cascade, where the transfer function of one ZP circuit of each pair exhibits a positive zero and the transfer function of the other ZP circuit exhibits a negative zero. By digitally controlling tunable capacitors within the pairs, the equalizer's frequency response and gain can be adjusted, while a controllable (e.g., constant) group delay is maintained. The number of blocks in the cascade can be selected, and each block independently configured, to optimally compensate for high-frequency losses in a wide range of transmission environments. One implementation involves a T-block cascade with output taps that feed a T:1 output selector such that the output of the overall equalizer can be selected to be any one of these taps corresponding to a programmable equalizer of effective length N where N≦T.