All-optical packet address and payload separation

“…Two preamble bits are also included at the start of each tag to assist the clock recovery process in each hop. Further, singlebit guardbands are inserted between each tag and payload as required by the all-optical tag extraction subsystem [18]. In order to investigate the cascadeability of the approach, the switching matrix was assumed to be a strictly nonblocking 8 × 8 switch, where the optical packet propagates through three cascaded 1 × 2 optical switching elements.…”

“…6. The incoming optical packet and the recovered packet clock stream enter the tag extraction gate that consists of an SOA-MZI gate configured as a Boolean AND gate [18]. The temporal synchronization of the two signals is such that the first optical tag (tag #1) lies outside the switching window defined by the recovered packet clock.…”

“…These optical logic elements are suitable for a high-speed signal processing and they have already been established as the fundamental building blocks of all-optical switching nodes [11]. In this context, all-optical gates have been used as core elements performing a diversity of network functionalities, such as wavelength conversion [12], data regeneration [13], [14], clock recovery [15], [16], header from payload separation [17], [18], header matching [7], and data recovery [19].…”

ARTEMIS: 40-gb/s all-optical self-routing node and network architecture employing asynchronous bit and packet-level optical signal processing

“…Two preamble bits are also included at the start of each tag to assist the clock recovery process in each hop. Further, singlebit guardbands are inserted between each tag and payload as required by the all-optical tag extraction subsystem [18]. In order to investigate the cascadeability of the approach, the switching matrix was assumed to be a strictly nonblocking 8 × 8 switch, where the optical packet propagates through three cascaded 1 × 2 optical switching elements.…”

“…6. The incoming optical packet and the recovered packet clock stream enter the tag extraction gate that consists of an SOA-MZI gate configured as a Boolean AND gate [18]. The temporal synchronization of the two signals is such that the first optical tag (tag #1) lies outside the switching window defined by the recovered packet clock.…”

“…These optical logic elements are suitable for a high-speed signal processing and they have already been established as the fundamental building blocks of all-optical switching nodes [11]. In this context, all-optical gates have been used as core elements performing a diversity of network functionalities, such as wavelength conversion [12], data regeneration [13], [14], clock recovery [15], [16], header from payload separation [17], [18], header matching [7], and data recovery [19].…”

ARTEMIS: 40-gb/s all-optical self-routing node and network architecture employing asynchronous bit and packet-level optical signal processing

“…The input label is extracted by means of a label extraction circuit and processed at the XOR-based DGD monitor in order to estimate the PMD introduced by the fiber. The subsystem responsible for separating the label from the payload is based on a packet clock recovery circuit and an additional high-speed SOA-MZI optical gate configured to perform a simple Boolean AND operation [Bin02]. This subsystem was explained in more detail in Chapter 3.…”

“…From now on, let us suppose that packet switching nodes have the capability of detecting the position of the packet for synchronization issues. As an example, in Chapter 3 it has been presented how the packet node can recover the packet clock and extract the monitoring-field [Bin02].…”

Optical performance monitoring in optical packet-switched networks

All‐optical multi‐wavelength header recognition using superimposed Bragg gratings based correlators