Overview
The 1394b PHY core includes all functionality needed to meet the AS5643 protocol, and provides a complete IP solution for the PHY layer of the 1394b. The 1394b core includes all functionality needed to meet the 1394b and AS5643 support specification, including: comma alignment, 8b/10b encode/decode, primitive decode, scrambling, port state machine, connection manager, arbitration controller, elastic FIFO, and phase FIFO.
At the physical layer, the core of 1394b is built for connecting to FPGA/ASIC embedded SERDES, discrete SERDES parts, or general-purpose IO with AS5643 performance protocol. The Link Layer interface of 1394b PHY IP’s core provides the industry standard PHY-Link interface. This PHY-Link interface connects directly to New Wave Design’s Link Layer IP cores, discrete Link Layer integrated circuits, or to custom logic developed by the end user.
This core is targeted towards Mil1394 aerospace and defense applications and has been used on a wide range of FPGA devices at varying operating rates. The core comes with test-benches and example code, making design integration a straightforward task.
Learn more about Firewire IP core
It's a common misconception that IEEE 1394 links are limited to 4.5 m in length. This perception is no doubt caused by the statement found in the IEEE 1394 standard that all three types of cables (4-, 6-, and 9-pin) have "a suggested maximum length of 4.5 m." The 1394 standard goes on to point out that longer length cables are possible, but this has been largely overlooked and misunderstood. Additionally, IEEE 1394-2008 contains several clauses that specify long-haul media, which can support much longer distances.
Time to market is most important criteria for survival in the IC design industry. For this one should produce low cost good quality silicon in lesser time. In order to achieve this, design should be validated well before tape out in application area ecosystem and all software should be ready before silicon comes in the lab. This objective can be achieved by porting design and test environment to the emulator. This paper deals with art of skillfully porting a SoC on to emulator, architecting virtual evaluation board (EVB) and benefits of using emulation.
Eric Esteve, IPnest
While IEEE 1394/Firewire is a popular and proven standard familiar to many system designers, there is still the potential to make design errors that can compromise performance. Here are some tips for avoiding such problems
To address the bandwidth limitations of the USB 2.0 interface, the USB Implementers Forum (USB-IF) released the SuperSpeed USB 3.0 specifications in November 2008. The USB 3.0 specification provides a maximum bandwidth of up to 5Gbps while limiting power consumption. In this white paper we present the features of the USB 3.0 protocol, discuss the new usage models it enables and compare it with some of the existing interface standards popular in the market today.
Serial Advanced Technology Attachment (SATA) has become the dominant interface for internal storage in desktops, notebooks and consumer electronics devices.
