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The System Management Bus (abbreviated to SMBus or SMB) is a single-ended simple two-wire bus for the purpose of lightweight communication. Most commonly it is found in computer motherboards for communication with the power source for ON/OFF instructions.

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It is derived from I²C for communication with low-bandwidth devices on a motherboard, especially power related chips such as a laptop's rechargeable battery subsystem (see Smart Battery System). Other devices might include temperature, fan or voltage sensors, lid switches, clock generator, and RGB lighting. PCI add-in cards may connect to an SMBus segment.

A device can provide manufacturer information, indicate its model/part number, save its state for a suspend event, report different types of errors, accept control parameters and return status. The SMBus is generally not user configurable or accessible. Although SMBus devices usually can't identify their functionality, a new PMBus coalition has extended SMBus to include conventions allowing that.

The SMBus was defined by Intel and Duracell in 1994.[1] It carries clock, data, and instructions and is based on Philips' I²C serial bus protocol. Its clock frequency range is 10 kHz to 100 kHz. (PMBus extends this to 400 kHz.) Its voltage levels and timings are more strictly defined than those of I²C, but devices belonging to the two systems are often successfully mixed on the same bus.[citation needed]

SMBus is used as an interconnect in several platform management standards including: ASF, DASH, IPMI.

SMBus is used to access DRAM configuration information as part of serial presence detect. SMBus has grown into a wide variety of system enumeration use cases other than power management.

SMBus/I²C Interoperability[edit]

While SMBus is derived from I²C, there are several major differences between the specifications of the two busses in the areas of electricals, timing, protocols and operating modes.[2][3][4][5]

Electrical[edit]

Input Voltage (VIL and VIH)[edit]

When mixing devices, the I²C specification defines the input levels to be 30% and 70% of the supply voltage VDD,[4]:9 which may be 5 V, 3.3 V, or some other value. Instead of relating the bus input levels to VDD, SMBus defines them to be fixed at 0.8 and 2.1 V. SMBus 2.0 supports VDD ranging from 3 to 5 V.SMBus 3.0 supports VDD ranging from 1.8 to 5 V.

Sink Current (IOL)[edit]

SMBus 2.0 defines a ‘High Power' class that includes a 4 mA sink current that cannot be driven by I²C chips unless the pull-up resistor is sized to I²C-bus levels.

NXP devices have a higher power set of electrical characteristics than SMBus 1.0. The main difference is the current sink capability with VOL = 0.4 V.

  • SMBus low power = 350 μA
  • SMBus high power = 4 mA
  • I²C-bus = 3 mA

SMBus ‘high power' devices and I²C-bus devices will work together if the pull-up resistor is sized for 3 mA.

Frequency (FMAX and FMIN)[edit]

The SMBus clock is defined from 10–100 kHz while I²C can be 0–100 kHz, 0–400 kHz, 0–1 MHz and 0–3.4 MHz, depending on the mode. This means that an I²C bus running at less than 10 kHz will not be SMBus compliant since the SMBus devices may time out. Many SMBus devices will however support lower frequencies.

SMBus 3.0 adds 400 kHz and 1 MHz bus speeds.

Timing[edit]

  • SMBus defines a clock low time-out, TIMEOUT of 35 ms. I²C does not specify any timeout limit.
  • SMBus specifies TLOW:SEXT as the cumulative clock low extend time for a slave device. I²C does not have a similar specification.
  • SMBus specifies TLOW:MEXT as the cumulative clock low extend time for a master device. Again I²C does not have a similar specification.
  • SMBus defines both rise and fall time of bus signals. I²C does not.
  • The SMBus time-out specifications do not preclude I²C devices co-operating reliably on the SMBus. It is the responsibility of the designer to ensure that I²C devices are not going to violate these bus timing parameters.

Protocols[edit]

ACK and NACK usage[edit]

There are the following differences in the use of the NACK bus signaling:In I²C, a slave receiver is allowed to not acknowledge the slave address, if for example it's unable to receive because it's performing some real time task. SMBus requires devices to acknowledge their own address always, as a mechanism to detect a removable device's presence on the bus (battery, docking station, etc.)

I²C specifies that a slave device, although it may acknowledge its own address, may decide, some time later in the transfer, that it cannot receive any more data bytes. I²C specifies that the device may indicate this by generating the not acknowledge on the first byte to follow.

Other than to indicate a slave's device-busy condition, SMBus also uses the NACK mechanism to indicate the reception of an invalid command or datum. Since such a condition may occur on the last byte of the transfer, it is required that SMBus devices have the ability to generate the not acknowledge after the transfer of each byte and before the completion of the transaction. This is important because SMBus does not provide any other resend signaling. This difference in the use of the NACK signaling has implications on the specific implementation of the SMBus port, especially in devices that handle critical system data such as the SMBus host and the SBS components.

SMBus protocols[edit]

Each message transaction on SMBus follows the format of one of the defined SMBus protocols. The SMBus protocols are a subset of the data transfer formats defined in the I²C specifications. I²C devices that can be accessed through one of the SMBus protocols are compatible with the SMBus specifications. I²C devices that do not adhere to these protocols cannot be accessed by standard methods as defined in the SMBus and Advanced Configuration and Power Interface (ACPI) specifications.

Address Resolution Protocol[edit]

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The SMBus uses I²C hardware and I²C hardware addressing, but adds second-level software for building special systems. In particular its specifications include an Address Resolution Protocol that can make dynamic address allocations.Dynamic reconfiguration of the hardware and software allow bus devices to be‘hot-plugged' and used immediately, without restarting the system. The devices are recognized automatically and assigned unique addresses. This advantage results in a plug-and-play user interface. In both those protocols there is a very useful distinction made between a System Host and all the other devices in the system that can have the names and functions of masters or slaves.

Time-out feature[edit]

SMBus has a time-out feature which resets devices if a communication takes too long.This explains the minimum clock frequency of 10 kHz to prevent locking up the bus. I²C can be a ‘DC' bus, meaning that a slave device stretches the master clock when performing some routine while the master is accessing it. This will notify to the master that the slave is busy but does not want to lose the communication. The slave device will allow continuation after its task is complete. There is no limit in the I²C-bus protocol as to how long this delay can be, whereas for an SMBus system, it would be limited to 35 ms.The SMBus protocol just assumes that if something takes too long, then it means that there is a problem on the bus and that all devices must reset in order to clear this mode. Slave devices are not then allowed to hold the clock LOW too long.

Packet Error Checking[edit]

SMBus 1.1 and later define optional Packet Error Checking (PEC). In that mode, a PEC (packet error code) byte is appended at the end of each transaction. The byte is calculated as CRC-8checksum, calculated over the entire message including the address and read/write bit. The polynomial used is x8+x2+x+1 (the CRC-8-ATMHEC algorithm, initialized to zero).[6][7][8]

SMBALERT#[edit]

The SMBus has an extra optional shared interrupt signal called SMBALERT#, which can be used by slaves to tell the host to ask its slaves about events of interest.SMBus also defines a less common 'Host Notify Protocol', providing similar notifications but passing more data and building on the I²C multi-master mode.

Support[edit]

SMBus devices are supported by FreeBSD, OpenBSD, NetBSD, DragonFly BSD, Linux, Windows 2000 and newer and Windows CE.

See also[edit]

  • Embedded controller (EC)
  • Intelligent Platform Management Interface (IPMI)
  • Low Pin Count (LPC)
  • Serial Peripheral Interface (SPI)
  • Platform Environment Control Interface (PECI)
  • Host Embedded Controller Interface (HECI)
  • Intelligent Platform Management Bus (IPMB)
  • Power Management Bus (PMBus)
  • System Management Controller (SMC)
  • Advanced Configuration and Power Interface (ACPI)

References[edit]

  1. ^'DURACELL AND INTEL ANNOUNCE 'SMART BATTERY' SPECIFICATIONS FOR PORTABLE COMPUTERS - Free Online Library'. Thefreelibrary.com. Retrieved 27 October 2017.
  2. ^'System Management Bus (SMBus) Specification Version 2.0'(PDF). smbus.org
  3. ^'System Management Bus (SMBus) Specification Version 3.0'(PDF). smbus.org
  4. ^ ab'I2C-bus specification and user manual Rev. 6'(PDF). nxp.com
  5. ^'APPLICATION NOTE 476 Comparing the I²C Bus to the SMBus'. Maxim. 2000-12-01. 090429 maxim-ic.com
  6. ^'Designing with SMBus 2.0'(PDF). Sbs-forum.org. Retrieved 27 October 2017.
  7. ^'CRC-8 Calculator'. Smbus.org. Retrieved 27 October 2017.
  8. ^'CRC-8 for SMBus'. Picbasic.co.uk. Retrieved 27 October 2017.

External links[edit]

This article is based on material taken from the Free On-line Dictionary of Computing prior to 1 November 2008 and incorporated under the 'relicensing' terms of the GFDL, version 1.3 or later.

Retrieved from 'https://en.wikipedia.org/w/index.php?title=System_Management_Bus&oldid=996120652'
5,377 downloads·Added on: November 16, 2016·Manufacturer: AMD

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The package provides the installation files for AMD PCI Bus Driver version 15.301.0.0.

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If the driver is already installed on your system, updating (overwrite-installing) may fix various issues, add new functions, or just upgrade to the available version. Take into consideration that is not recommended to install the driver on Operating Systems other than stated ones.

In order to manually update your driver, follow the steps below (the next steps):

1. Extract the .cab file to a folder of your choice
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About Chipset Driver:

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Windows OS automatically installs a generic driver that allows computers to recognize basic motherboard functions. However, to make use of all board components, appropriate chipset drivers must be applied.
If you install this package, the system will receive related information regarding the chipset. Also, this step might improve compatibility and bus transfer speeds, add various changes for sleep state behavior, power saving functionality and others, or include support for new features.
To apply this release, simply make sure your system configuration is supported by this package, get the file, run the available setup, and follow the on-screen instructions. Bear in mind that installing inappropriate chipset drivers can cause computers to malfunction.
In addition to that, do perform a system restart after you have completely applied the present release so that all changes take effect. Despite the off-chance that other OSes might be compatible, we do not recommend installing any software on platforms other than the highlighted ones.
That being said, check the supported platforms, click the download button and apply the chipset driver. Moreover, don't forget to check with our website as often as possible to stay up to date with the latest releases.

It is highly recommended to always use the most recent driver version available.
Try to set a system restore point before installing a device driver. This will help if you installed an incorrect or mismatched driver. Problems can arise when your hardware device is too old or not supported any longer.

COMPATIBLE WITH:
Windows 10 64 bit
file size:
216 KB
filename:
20880963_cc7d44ff91efb7a570c02cd9dff9afee97fb7fca.cab
CATEGORY:
Motherboard




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