Windows Xp Sp3 Bak Lite 3 Sata 1 Link High Quality

So: I have 2 years old laptop Asus X555LAB, initially bought with pre-installed Windows 8, which was subsequently upgraded to Windows 10 and worked for 2 years without any problems. However, 2 weeks ago, laptop started to experience Blue Screens with message: Critical Process Died; that's all I could see really and Event Log didn't show much more. I tried to recover windows using Windows 10 Recovery Disc, then to reinstall completely, but to no avail --> same Blue Screen kept occurring.

There's an oops above which is (likely) the relevant error, but you've to scroll up a bit to see it.

Otherwise it's not clear from either the screenshot or the journal tail that you posted (don't copy out of the pager) whether the link is actually supposed to be active.

Windows Xp Sp3 Bak Lite 3 Sata 1 Link

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Thanks! I will trying messing around with some kernel params to see if I can get more useful output. In the meantime, here's the most recent succesful boot:

I see a few "SATA link down"s, so you're probably right that that isn't the cause of the problem.

Yesterday my system didn't boot anymore after updating the system. I got a lot of sata errors. Then I looked into my bios setup and last bios update was 2018 (shame on me). I updated my bios and the system booted again.

SATA Link Power Management (LPM) puts the physical layer (PHY) of the SATA link into a power saving state. SATA Link Power Management is independent of the power state of the hard disk or SSD. This is controlled at the ATA protocol level and, in the case of hard disks for example, leads to a spinning down of the data carrier in order to save power. SATA LPM has led to a significant reduction in the overall power consumption of the SATA subsystem, both in the platform controller hub (SATA controller in the chipset or CPU) and in the SATA device itself. However, LPM is not compatible with hot-plug

SATA link power management requires cooperation between the host and the device. Both the host and the device can request the link to change to a low-power state. The appropriate host or device must then accept or reject the request to change the link state. Each of these methods provides energy savings in isolation. However, maximum energy savings are achieved when both procedures are used.

Enabled Link Power Management places the SATA link in a neutral logical state. Because the signal lines are in a neutral logical state, it is impossible for an AHCI host controller to detect when a SATA device has been removed from the bus.

One of the problems associated with the transmission of data at high speed over electrical connections is described as noise, which is due to electrical coupling between data circuits and other circuits. As a result, the data circuits can both affect other circuits and be affected by them. Designers use a number of techniques to reduce the undesirable effects of such unintentional coupling. One such technique used in SATA links is differential signaling. This is an enhancement over PATA, which uses single-ended signaling. The use of fully shielded, dual coax conductors, with multiple ground connections, for each differential pair[49] improves isolation between the channels and reduces the chances of lost data in difficult electrical environments.

Standardized in 2004, eSATA (e standing for external) provides a variant of SATA meant for external connectivity. It uses a more robust connector, longer shielded cables, and stricter (but backward-compatible) electrical standards. The protocol and logical signaling (link/transport layers and above) are identical to internal SATA. The differences are:

U.2, formerly known as SFF-8639. Like M.2, it carries a PCI Express electrical signal, however U.2 uses a PCIe 3.0 4 link providing a higher bandwidth of 32 Gbit/s in each direction. In order to provide maximum backward compatibility the U.2 connector also supports SATA and multi-path SAS.[81]

The physical layer defines SATA's electrical and physical characteristics (such as cable dimensions and parasitics, driver voltage level and receiver operating range), as well as the physical coding subsystem (bit-level encoding, device detection on the wire, and link initialization).

Physical transmission uses differential signaling. The SATA PHY contains a transmit pair and receive pair. When the SATA-link is not in use (example: no device attached), the transmitter allows the transmit pins to float to their common-mode voltage level. When the SATA-link is either active or in the link-initialization phase, the transmitter drives the transmit pins at the specified differential voltage (1.5 V in SATA/I).

SATA physical coding uses a line encoding system known as 8b/10b encoding. This scheme serves multiple functions required to sustain a differential serial link. First, the stream contains necessary synchronization information that allows the SATA host/drive to extract clocking. The 8b/10b encoded sequence embeds periodic edge transitions to allow the receiver to achieve bit-alignment without the use of a separately transmitted reference clock waveform. The sequence also maintains a neutral (DC-balanced) bitstream, which lets transmit drivers and receiver inputs be AC-coupled. Generally, the actual SATA signalling is half-duplex, meaning that it can only read or write data at any one time.

Also, SATA uses some of the special characters defined in 8b/10b. In particular, the PHY layer uses the comma (K28.5) character to maintain symbol-alignment. A specific four-symbol sequence, the ALIGN primitive, is used for clock rate-matching between the two devices on the link. Other special symbols communicate flow control information produced and consumed in the higher layers (link and transport).

The PHY layer is responsible for detecting the other SATA/device on a cable, and link initialization. During the link-initialization process, the PHY is responsible for locally generating special out-of-band signals by switching the transmitter between electrical-idle and specific 10b-characters in a defined pattern, negotiating a mutually supported signalling rate (1.5, 3.0, or 6.0 Gbit/s), and finally synchronizing to the far-end device's PHY-layer data stream. During this time, no data is sent from the link-layer.

After the PHY-layer has established a link, the link layer is responsible for transmission and reception of Frame Information Structures (FISs) over the SATA link. FISs are packets containing control information or payload data. Each packet contains a header (identifying its type), and payload whose contents are dependent on the type. The link layer also manages flow control over the link.

When DMA data is to be transmitted and is received from the higher command layer, the transport layer appends the FIS control header to the payload, and informs the link layer to prepare for transmission. The same procedure is performed when data is received, but in reverse order. The link layer signals to the transport layer that there is incoming data available. Once the data is processed by the link layer, the transport layer inspects the FIS header and removes it before forwarding the data to the command layer.

SATA 3 Gbit/s theoretically offers a maximum bandwidth of 300 MB/s per device, which is only slightly lower than the rated speed for SCSI Ultra 320 with a maximum of 320 MB/s total for all devices on a bus.[85] SCSI drives provide greater sustained throughput than multiple SATA drives connected via a simple (i.e., command-based) port multiplier because of disconnect-reconnect and aggregating performance.[86] In general, SATA devices link compatibly to SAS enclosures and adapters, whereas SCSI devices cannot be directly connected to a SATA bus.

Just, you switched the sata port when the system was off and so was power right? Also, Intel X79 boards can have different controllers on different sata ports. So make sure to read in your manual which controller you plugged it into. Ideally you want an Intel controller, sometimes motherboards have Marvell and Asmedia controllers on the sata ports.

Hot plug is disabled for all sata, tried 3 different cables, tried resetting CMOS multiple times, still not showing ssd. My hard drive and cd drives show. I don't think I pressed the switch on the power supplies when changing sata cables

The EFI firmware version on your MacBook Pro controls these link speeds as well as many other aspects of CPU throttling, so without reverse engineering that code - it's hard to know what or why the link may re-negotiate at a different speed. In the past, Apple has released EFI firmware updates to increase SATA link speeds for third party drives when they have done the engineering to make sure it will be stable enough - even if they don't support those drives. Of course they also release updates to improve their OEM parts in terms of speed and reliability so you can monitor those link speeds as well as your actual bottlenecks and submit bug reports if you feel things are not optimally configured - especially if you have some benchmarks or other data to show that case.

Looking at your VM configuration screenshot, you have 2 SATA devices. CD/DVD is set to Autoconnect. Chances are sata0:1 is the virtual CD/DVD. You might have set to this to "Connect on Power On" and there is no CD/DVD drive present in your host computer.

2. Also when the error pops up- there is an option - 'Do not Try connect next time' - saying yes - next time when I start the error does not show up. But instead I get new message (not a error popup) - 'Printing is globally disabled... sata01....'

Just putting this here for anyone in the future that runs in to the same problem. If you exist in any form of restricted environment such as an enterprise domain with administrative restrictions enabled, you may need to run VMWare workstation as administrator to be able to access drive mappings or CD/DVD drives through a VM.

In my case I couldn't get a windows disc to be recognized by VMWare Workstation. Every time I would try to mount the disc drive it would give me the error in this thread. (Cannot connect the virtual device sata0:1 because no corresponding device is available on the host) be457b7860