Lacie d2 Quadra USB 3.0 User Manual - Page 40

LaCie d2 Quadra Quadruple Interface Hard Drive eSATA Questions & Answers page 39 7. eSATA Questions & Answers ■ What is eSATA? Your LaCie d2 Quadra Hard Drive uses the latest in SATA technology, allowing interface (or bus) transfer rates of up to 1.5Gb/s. SATA technology was originally developed to serve as an internal interface, delivering improved performance to internal connections. Soon after, eSATA, a connector that can be used for SATA I as well as SATA II, was developed, allowing for the use of shielded cables outside the PC. eSATA technology was developed to be rugged and durable. eSATA connectors do not have the "L" shaped design of other SATA connectors. In addition, the guide features are vertically offset and reduced in size to prevent the use of unshielded internal cables in external applications. Initial Serial ATA technology removed the performance bottleneck of the Parallel ATA specification, and follows a clearly defined road map to greater and greater data transfer rates and feature improvements. Deriving its name from the way that it transmits signals, in a single stream, or serially, Serial ATA operates in a point-to-point topology. This connectivity methodology delivers the entire available interface bandwidth to each device, allowing each device to operate at its maximum throughput, and provides direct communication between the device and the system at any time, reducing arbitration delays associated with shared bus topologies. ■ What are the key differences between SATA I and SATA II technology? For single drive configurations, SATA I, SATA II and FireWire 800 will have about the same performance. However, in a RAID0 configuration, SATA I and SATA II will allow faster transfer rates than FireWire 800, which may limit transfer rates. ■ What are the features and benefits of Serial ATA and Serial ATA II? The Serial ATA specification provides several key features that will help spur widespread implementation: • Performance: Serial ATA is a point-to-point topology, and does not have to share the bus, instead dedicating full bandwidth to the device. These dedicated links make creating a Serial ATA RAID array quick and relatively inexpensive to implement. • Easy installation and configuration: There are no device IDs, termination or master/slave conflicts, and the standard supports hot-plug connectivity. Drives can be added, upgraded or removed without having to power down the whole system. • Improved reliability: Serial ATA also uses 32-bit cyclic redundancy checking (CRC) on all transfers to ensure correct data transmissions. Due to this CRC capability, Serial ATA performs protection and recovery features at multiple levels: PHY layer, link layer and transport and software layers. • Command optimization: Serial ATA utilizes Native Command Queing (NCQ) and first party direct memory access (DMA) to intelligently order commands in an internal queue within the drive, without having to involve the host CPU. Judging its own drive head's angular and rotational position, the drive selects a data transfer from the queue that will minimize both its seek and rotational latencies. • Simplified structure: Serial ATA utilizes a more efficient signaling voltage (250mV vs. 5V for Parallel ATA), and much smaller, thinner and compact cables and connectors. Due to the simplified cabling (the reduction in the number of pins and wires), the number of fault possibilities decreases. • Seamless integration: Serial ATA maintains register and software compatibility with Parallel ATA, and