ADT7476AARQZ 查看數據表(PDF) - ON Semiconductor
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ADT7476AARQZ Datasheet PDF : 67 Pages
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ADT7476A
Programming TRANGE
TRANGE defines the distance between TMIN and 100%
PWM. For the ADT7467, ADT7468 and ADT7473,
TRANGE is effectively a slope. For the ADT7475
andADT7476A, TRANGE is no longer a slope, but defines
the temperature region where the PWM output linearly
ramps from PWMMIN to 100% PWM.
PWM = 100%
PWMMAX
PWMMIN
PWM = 0%
TRANGE
TMIN
Figure 46. TRANGE
Programming the Automatic Fan Speed Control Loop
To understand the automatic fan speed control loop more
efficiently, it is recommended to use the ADT7476A
evaluation board and software while reading this section.
This section provides the system designer with an
understanding of the automatic fan control loop and
provides step-by-step guidance on effectively evaluating
and selecting critical system parameters. To optimize the
system characteristics, the designer needs to give some
thought to system configuration, including the number of
fans, where they are located, and what temperatures are
being measured in the particular system.
The mechanical or thermal engineer who is tasked with
the system thermal characterization should also be involved
at the beginning of the system development process.
Manual Fan Control Overview
In unusual circumstances, it can be necessary to manually
control the speed of the fans. Because the ADT7476A has an
SMBus interface, a system can read back all necessary
voltage, fan speed, and temperature information, and use
this information to control the speed of the fans by writing
to the PWM current duty cycle register (0x30, 0x31, and
0x32) of the appropriate fan. Bits [7:5] of the PWMx
configuration registers (0x5C, 0x5D, 0x5E) are used to set
fans up for manual control.
THERM Operation in Manual Mode
In manual mode, if the temperature increases above the
programmed THERM temperature limit, the fans
automatically speed up to maximum PWM or 100% PWM,
whichever way the appropriate fan channel is configured.
Automatic Fan Control Overview
The ADT7476A can automatically control the speed of
fans based on the measured temperature. This is done
independently of CPU intervention once initial parameters
are set up.
The ADT7476A has a local temperature sensor and two
remote temperature channels that can be connected to a CPU
on-chip thermal diode (available on Intel Pentium class and
other CPUs). These three temperature channels can be used
as the basis for automatic fan speed control to drive fans
using pulse-width modulation (PWM).
Automatic fan speed control reduces acoustic noise by
optimizing fan speed according to accurately measured
temperature. Reducing fan speed can also decrease system
current consumption. The automatic fan speed control mode
is very flexible due to the number of programmable
parameters, including TMIN and TRANGE. The TMIN and
TRANGE values for a temperature channel and, therefore, for
a given fan, are critical, because they define the thermal
characteristics of the system. The thermal validation of the
system is one of the most important steps in the design
process, so these values should be selected carefully.
Figure 47 gives a top-level overview of the automatic fan
control circuitry on the ADT7476A. From a systems-level
perspective, up to three system temperatures can be
monitored and used to control three PWM outputs. The three
PWM outputs can be used to control up to four fans. The
ADT7476A allows the speed of four fans to be monitored.
Each temperature channel has a thermal calibration block,
allowing the designer to individually configure the thermal
characteristics of each temperature channel. For example,
designers can decide to run the CPU fan when CPU
temperature increases above 60°C and a chassis fan when
the local temperature increases above 45°C.
At this stage, the designer has not assigned these thermal
calibration settings to a particular fan drive (PWM) channel.
The right side of Figure 47 shows fan-specific controls. The
designer has individual control over parameters such as
minimum PWM duty cycle, fan speed failure thresholds,
and even ramp control of the PWM outputs. Automatic fan
control, then, ultimately allows graceful fan speed changes
that are less perceptible to the system user.
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