TI1 LM64 Remote diode temperature sensor Datasheet

LM64
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SNAS207A – MAY 2004 – REVISED MARCH 2013
LM64 ±1°C Remote Diode Temperature Sensor with PWM Fan Control and 5 GPIO's
Check for Samples: LM64
FEATURES
KEY SPECIFICATIONS
•
•
1
2
•
•
•
•
•
•
•
•
•
Accurately Senses Remote and Local Diode
Temperatures
Integrated PWM Fan Speed Control Output
Programmable 8-step Lookup Table for
Quieting Fans
ALERT and T_Crit Open-drain Outputs
Tachometer Input for Measuring Fan RPM
10 bit Plus Sign Remote Diode Temperature
Data Format, with 0.125°C Resolution
SMBus 2.0 Compatible Interface, Supports
TIMEOUT
5 General Purpose Input/Output pins
5 General Purpose Default input pins
24-pin WQFN Package
APPLICATIONS
•
•
•
•
•
•
Computer Processor Thermal Management
Graphics Processor Thermal Management
Voltage Regulator Modules
Electronic Instrumentation
Power Supplies
Projectors
•
•
Remote Diode Temperature Accuracy
(includes quantization error)
– Ambient Temp
– 30°C to 50°C
– 0°C to 85°C
– Diode Temp
– 120°C to 140°C
– 25°C to 140°C
– Max Error
– ±1.0°C (max)
– ±3.0°C (max)
Local Temp Accuracy (includes quantization
error)
– Ambient Temp 25°C to 125°C
– Max Error ±3.0°C (max)
Power Supply Requirements
– Supply DC Voltage 3.0 V to 3.6 V
– Supply DC Current 1.1 mA (typ)
DESCRIPTION
The LM64 is a remote diode temperature sensor with
PWM fan control. The LM64 accurately measures its
own temperature and that of a remote diode. The
LM64 remote temperature accuracy is factory
trimmed for a MMBT3904 diode-connected transistor
with a 16°C offset for high temperatures. TACTUAL
DIODE JUNCTION = TLM64 + 16°C
The LM64 features a PWM, open-drain, fan control
output, 5 GPIO (General Purpose Input/Output) and 5
GPD (General Purpose Default) pins. The 8-step
Lookup Table allows for a non-linear fan speed vs.
temperature transfer function often used to quiet
acoustic fan noise.
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2004–2013, Texas Instruments Incorporated
LM64
SNAS207A – MAY 2004 – REVISED MARCH 2013
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6
1
2
3
4
5
GPIO2
GPIO3
PWM
VDD
D+
D7
GPIO1
Connection Diagram
8
24
9
23
10
22
GPD5
T_Crit
GPD4
N/C
LM64
N/C
GPD3
11
21
12
20
GPD2
N/C
A0
GPD1
19
18
GPIO4
GPIO5
17
SMBDAT
ALERT
GND
16
SMBCLK
15
14
TACH
13
Figure 1. 24-pin WQFN Package
Pin Descriptions
Pin
Name
Input/Output
1
GPIO1
Digital Input/
Open-Drain Output
General Purpose Open-Drain Digital Output or Digital Input. Typical pull-up resistor is
10 kΩ to VDD.
2
GPIO2
Digital Input/
Open-Drain Output
General Purpose Open-Drain Digital Output or Digital Input. Typical pull-up resistor is
10 kΩ to VDD.
3
GPIO3
Digital Input/
Open-Drain Output
General Purpose Open-Drain Digital Output or Digital Input. Typical pull-up resistor is
10 kΩ to VDD.
4
PWM
Open-Drain
Digital Output
Open-Drain Digital Output. Connect to fan drive circuitry. The power-on default for this
pin is low (pin 4 pulled to ground).
5
VDD
Power Supply Input
Connect to a low-noise +3.3 ± 0.3 VDC power supply, and bypass to GND with a 0.1
µF ceramic capacitor in parallel with a 100 pF ceramic capacitor. A bulk capacitance of
10 µF needs to be in the vicinity of the LM64's VDD pin.
6
D+
Analog Input
Connect to the anode (positive side) of the remote diode. A 2.2 nF ceramic capacitor
must be connected between pins 6 and 7.
7
D-
Analog Input
Connect to the cathode (negative side) of the remote diode. A 2.2 nF ceramic capacitor
must be connected between pins 6 and 7.
8
T_Crit
Open-Drain
Digital Output
Open-Drain Digital Output. Typical pull-up resistor is 3 kΩ to VDD.
9
N/C
N/A
No Connection.
10
N/C
N/A
No Connection.
11
N/C
N/A
No Connection.
12
A0
Digital Input
13
GND
Ground
14
ALERT
Open-Drain
Digital Output
15
TACH
Digital Input
16
SMBDAT
Digital Input/
Open-Drain Output
17
SMBCLK
Digital Input
GPIO5
Digital Input/
Open-Drain Output
18
2
Function and Connection
SMBus Address Select pin. If High, the SMBus address is 0x4E or, if Low, the SMBus
address is 0x18. Typical pull-up resistor is 10 kΩ to VDD.
This is the analog and digital ground return.
This pin is an open-drain ALERT Output. Typical pull-up resistor is 3 kΩ to VDD.
This pin is a digital tachometer input. Typical pull-up resistor is 3 kΩ to VDD.
This is the bi-directional SMBus data line. Typical pull-up resistor is 1.5 kΩ to VDD.
This is the SMBus clock input. Typical pull-up resistor is 1.5 kΩ to VDD.
General Purpose Open-Drain Digital Output or Digital Input. Typical pull-up resistor is
10 kΩ to VDD.
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Pin Descriptions (continued)
Pin
Name
Input/Output
19
GPIO4
Digital Input/
Open-Drain Output
Function and Connection
20
GPD1
Digital Input
General Purpose Default Input Pin. Typical pull-up resistor is 10 kΩ to VDD. Always
connect to a logical High or Low level.
21
GPD2
Digital Input
General Purpose Default Input Pin. Typical pull-up resistor is 10 kΩ to VDD. Always
connect to a logical High or Low level.
22
GPD3
Digital Input
General Purpose Default Input Pin. Typical pull-up resistor is 10 kΩ to VDD. Always
connect to a logical High or Low level.
23
GPD4
Digital Input
General Purpose Default Input Pin. Typical pull-up resistor is 10 kΩ to VDD. Always
connect to a logical High or Low level.
24
GPD5
Digital Input
General Purpose Default Input Pin. Typical pull-up resistor is 10 kΩ to VDD. Always
connect to a logical High or Low level.
General Purpose Open-Drain Digital Output or Digital Input. Typical pull-up resistor is
10 kΩ to VDD.
GPD1
GPD2
GPD3
GPD4
GPD5
Simplified Block Diagram
GPIO5
LM64
GPIO4
GPIO
Registers
Internal Diode
GPIO3
GPIO2
D+
D-
GPIO1
Diode
Bias and
Control
6' ADC
Tachometer
Detection
SMBDAT
SMBCLK
A0
2 - Wire
Serial
Interface
SMBus
Address
Temp Reading,
Temp Limit,
Hysteresis, and
Temp Sensor
Filter Registers
Comparators
Status and Status
Mask Registers
ALERT Control
Logic
TACH
T_Crit
ALERT
PWM
PWM Fan Control
Registers
PWM Fan Control
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Typical Application
VDD
R1
R2
R3
R4
R5
R6
R7
R8
S5
S4
S3
S2
R9 R10 R11 R12 R13 R14
C1
C2
C3
S1
GPD5
GPD4
GPD3
GPD2
GPD1
Fan V+
24
23
22
21
20
C4
GPIO1
1
19 GPIO4
GPIO2
2
18 GPIO5
GPIO3
3
PWM
4
16 SMBDAT
VDD
5
15 TACH
D+
6
14
D-
7
13 GND
10
11
12
SMBCLK
To SMBus
interface
control
circuitry
ALERT
VDD
R15
R16
R17
Fan V-
N/C
A0
9
N/C
8
T_CRIT
Q1
N/C
C6
17
LM64
C5
A0
Thermal Diode
on-board
Processor Die
T_CRIT
Q2
R18
R1 - R10; R15 = 10 k:
C1 = 10 PF electrolytic
R11, R12 = 1.5 k:
C2, C5 = 0.1 PF ceramic
Q2 = MMBT3904
R13, R14, R16 = 3 k:
C3 = 100 pF ceramic
S1 - S5 = SPST Switch
R17 = 430:
C4 = 2.2 PF electrolytic
R18 = 10:
C6 = 2.2 nF ceramic
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
4
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Absolute Maximum Ratings (1) (2) (3)
−0.3 V to 6.0 V
Supply Voltage, VDD
Voltage on SMBDAT, SMBCLK,
−0.5 V to 6.0 V
ALERT, T_Crit, PWM Pins
−0.3 V to (VDD + 0. 3 V)
Voltage on Other Pins
Input Current, D− Pin
±1 mA
Input Current at All Other Pins
Package Input Current
(4)
5 mA
(4)
30 mA
Package Power Dissipation
SMBDAT, ALERT, T_Crit, PWM pins
See
Output Sink Current
10 mA
−65°C to +150°C
Storage Temperature
ESD Susceptibility (6)
(5)
Human Body Model
2000 V
Machine Model
200 V
SMT Soldering Information
See AN-1187 (SNOA401Q), "Leadless Leadframe Package" for information on SMT Assembly using LLP Packages.
(1)
(2)
(3)
(4)
(5)
(6)
All voltages are measured with respect to GND, unless otherwise noted.
Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for
which the device is functional, but do not guarantee performance limits. For guaranteed specifications and test conditions, see the
Electrical Characteristics. The guaranteed specifications apply only for the test conditions listed. Some performance characteristics may
degrade when the device is not operated under the listed test conditions.
If Military/Aerospace specified devices are required, please contact the TI Sales Office/Distributors for availability and specifications.
When the input voltage (VIN) at any pin exceeds the power supplies (VIN < GND or VIN > V+), the current at that pin should be limited to
5 mA. Parasitic components and/or ESD protection circuitry are shown in the Table 1, for the LM64's pins, by an "X" when it exists. Care
should be taken not to forward bias the parasitic diode, D1, present on pins D+ and D−. Doing so by more than 50 mV may corrupt
temperature measurements.
See AN-1187 SNOA401 for Thermal Resistance Junction-to-Ambient Temperature.
Human body model, 100 pF discharged through a 1.5 kΩ resistor. Machine model, 200 pF discharged directly into each pin. See
Figure 3 for the ESD Protection Input Structure.
Operating Ratings (1) (2)
0°C ≤ TA ≤ +85°C
LM64 Operating Temperature Range
25°C ≤ TD ≤ +140°C
Remote Diode Temperature Range
TMIN ≤ TA ≤ TMAX
Electrical Characteristics
Supply Voltage Range (VDD)
(1)
(2)
+3.0 V to +3.6 V
Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for
which the device is functional, but do not guarantee performance limits. For guaranteed specifications and test conditions, see the
Electrical Characteristics. The guaranteed specifications apply only for the test conditions listed. Some performance characteristics may
degrade when the device is not operated under the listed test conditions.
All voltages are measured with respect to GND, unless otherwise noted.
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DC Electrical Characteristics
TEMPERATURE-TO-DIGITAL CONVERTER CHARACTERISTICS
The following specifications apply for VDD = 3.0 VDC to 3.6 VDC, and all analog source impedance RS = 50 Ω unless
otherwise specified in the conditions. Boldface limits apply for TA = TMIN to TMAX; all other limits TA = +25°C.
Parameter
Typical
Conditions
(1)
Limits
(2)
Units
(Limits)
Temperature Error using a diode-connected
MMBT3904 transistor. TD is the Remote Diode
Junction Temperature.
TD = TLM64 + 16°C
TA = +30°C to
+50°C
TD = +120°C to
+140°C
±1
°C (max)
TA = +0°C to
+85°C
TD = +25°C to
+140°C
±3
°C (max)
Temperature Error Using the Local Diode
TA = +25°C to +125°C
±3
°C (max)
(3)
±1
Remote Diode Resolution
11
Local Diode Resolution
Bits
0.125
°C
8
Bits
1
Conversion Time of All Temperatures
Fastest Setting
31.25
D− Source Voltage
(VD+ − VD−) = +0.65 V; High Current
Low Current
(2)
(3)
ms (max)
315
µA (max)
0.7
160
Diode Source Current
(1)
°C
34.4
13
V
110
µA (min)
20
µA (max)
7
µA (min)
“Typicals” are at TA = 25°C and represent most likely parametric norm. They are to be used as general reference values not for critical
design calculations.
Limits are guaranteed to TI's AOQL (Average Outgoing Quality Level).
Local temperature accuracy does not include the effects of self-heating. The rise in temperature due to self-heating is the product of the
internal power dissipation of the LM64 and the thermal resistance. See AN-1187 (SNOA401) for the thermal resistance to be used in the
self-heating calculation.
Operating Electrical Characteristics
Conditions
Parameter
ALERT, T_Crit and PWM Output Saturation Voltage
Typ
(1)
ALERT, T_Crit
PWM
IOUT
4 mA
6 mA
IOUT
6 mA
(1)
(2)
(3)
6
(3)
(2)
0.4
0.55
Power-On-Reset Threshold Voltage
Supply Current
Limits
SMBus Inactive, 16 Hz
Conversion Rate
1.1
STANDBY Mode
320
Units
V (max)
2.4
V (max)
1.8
V (min)
2.0
mA (max)
µA
“Typicals” are at TA = 25°C and represent most likely parametric norm. They are to be used as general reference values not for critical
design calculations.
Limits are guaranteed to TI's AOQL (Average Outgoing Quality Level).
The supply current will not increase substantially with an SMBus transaction.
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AC Electrical Characteristics
The following specifications apply for VDD = 3.0 VDC to 3.6 VDC, and all analog source impedance RS = 50Ω unless
otherwise specified in the conditions. Boldface limits apply for TA = TMIN to TMAX; all other limits TA= +25°C.
Limits
(2)
Units
(Limit)
Fan Control Accuracy
±10
% (max)
Fan Full-Scale Count
65535
(max)
Symbol
Parameter
Conditions
Typical
(1)
TACHOMETER ACCURACY
Fan Counter Clock Frequency
90
kHz
Fan Count Update Frequency
1.0
Hz
FAN PWM OUTPUT
Frequency Accuracy
(1)
(2)
±10
% (max)
“Typicals” are at TA = 25°C and represent most likely parametric norm. They are to be used as general reference values not for critical
design calculations.
Limits are guaranteed to TI's AOQL (Average Outgoing Quality Level).
Digital Electrical Characteristics
Symbol
(1)
(2)
Parameter
Conditions
Typical
Limits
(1)
Units
(Limit)
(2)
VIH
Logical High Input Voltage
2.1
V (min)
VIL
Logical Low Input Voltage
0.8
V (max)
IIH
Logical High Input Current
VIN = VDD
0.005
+10
µA (max)
IIL
Logical Low Input Current
VIN = GND
−0.005
−10
µA (max)
CIN
Digital Input Capacitance
20
pF
“Typicals” are at TA = 25°C and represent most likely parametric norm. They are to be used as general reference values not for critical
design calculations.
Limits are guaranteed to TI's AOQL (Average Outgoing Quality Level).
SMBus Logical Electrical Characteristics
The following specifications apply for VDD = 3.0 VDC to 3.6 VDC, and all analog source impedance RS = 50 Ω unless
otherwise specified in the conditions. Boldface limits apply for TA = TMIN to TMAX; all other limits TA = +25°C.
Symbol
Parameter
Conditions
Typical
(1)
Limits
(2)
Units
(Limit)
SMBDAT OPEN-DRAIN OUTPUT
VOL
Logic Low Level Output Voltage
IOL = 4 mA
IOH
High Level Output Current
VOUT = VDD
0.03
0.4
V (max)
10
µA (max)
SMBDAT, SMBCLK INPUTS
VIH
Logical High Input Voltage
2.1
V (min)
VIL
Logical Low Input Voltage
0.8
V (max)
VHYST
(1)
(2)
Logic Input Hysteresis Voltage
400
mV
“Typicals” are at TA = 25°C and represent most likely parametric norm. They are to be used as general reference values not for critical
design calculations.
Limits are guaranteed to TI's AOQL (Average Outgoing Quality Level).
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SMBus Digital Switching Characteristics
Unless otherwise noted, these specifications apply for VDD = +3.0 VDC to +3.6 VDC, CL (load capacitance) on output lines =
80 pF. Boldface limits apply for TA = TJ; TMIN ≤ TA ≤ TMAX; all other limits TA = TJ = +25°C, unless otherwise noted. The
switching characteristics of the LM64 fully meet or exceed the published specifications of the SMBus version 2.0. The
following parameters are the timing relationships between SMBCLK and SMBDAT signals related to the LM64. They adhere
to but are not necessarily the same as the SMBus bus specifications.
Symbol
Parameter
Conditions
Limits
(1)
Units
(Limit)
10
100
kHz (min)
kHz (max)
fSMB
SMBus Clock Frequency
tLOW
SMBus Clock Low Time
From VIN(0) max to VIN(0) max
4.7
µs (min)
tHIGH
SMBus Clock High Time
From VIN(1) min to VIN(1) min
4.0
50
µs (min)
µs (max)
tR
SMBus Rise Time
See
(2)
1
µs (max)
tF
SMBus Fall Time
See
(3)
0.3
µs (max)
tOF
Output Fall Time
CL = 400 pF, IO = 3 mA
250
ns (max)
tTIMEOUT
SMBData and SMBCLK Time Low for Reset of
Serial Interface See (4)
25
35
ms (min)
ms (max)
tSU:DAT
Data In Setup Time to SMBCLK High
250
ns (min)
tHD:DAT
Data Out Hold Time after SMBCLK Low
300
930
ns (min)
ns (max)
tHD:STA
Hold Time after (Repeated) Start Condition. After
this period the first clock is generated.
4.0
µs (min)
tSU:STO
Stop Condition SMBCLK High to SMBDAT Low
(Stop Condition Setup)
100
ns (min)
tSU:STA
SMBus Repeated Start-Condition Setup Time,
SMBCLK High to SMBDAT Low
4.7
µs (min)
tBUF
SMBus Free Time between Stop and Start
Conditions
4.7
µs (min)
(1)
(2)
(3)
(4)
Limits are guaranteed to TI's AOQL (Average Outgoing Quality Level).
The output rise time is measured from (VIL max - 0.15 V) to (VIH min + 0.15 V).
The output fall time is measured from (VIH min + 0.15 V) to (VIL min - 0.15 V).
Holding the SMBData and/or SMBCLK lines Low for a time interval greater than tTIMEOUT will reset the LM64’s SMBus state machine,
therefore setting SMBDAT and SMBCLK pins to a high impedance state.
tLOW
tR
tF
VIH
SMBCLK
VIL
tBUF
tHD;STA
tHIGH
tHD;DAT
tSU;STA
tSU;DAT
tSU;STO
VIH
SMBDAT
VIL
P
S
P
Figure 2. SMBus Timing Diagram for SMBCLK and SMBDAT Signals
8
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Table 1.
Pin Name
D6
R1
SNP
GPIO1
Pin #
1
D1
D2
D3
D4
D5
X
X
X
GPIO2
2
X
X
X
GPIO3
3
X
X
X
PWM
4
X
X
X
VDD
5
D+
6
X
X
D−
7
X
X
T_Crit
8
A0
12
ALERT
14
TACH
ESD CLAMP
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
15
X
X
X
SMBDAT
16
X
X
X
SMBCLK
17
GPIO5
18
X
X
X
GPIO4
19
X
X
X
GPD1
20
X
GPD2
21
X
GPD3
22
X
GPD4
23
X
GPD5
24
X
X
X
V+
D1
D3
D5
I/O
D2
SNP
ESD
Clamp
SNP = NMOS Snapback
R1
D4
D6
GND
Figure 3. ESD Protection Input Structure
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FUNCTIONAL DESCRIPTION
The LM64 Remote Diode Temperature Sensor with Integrated Fan Control incorporates a ΔVBE-based
temperature sensor using a Local or Remote diode and a 10-bit plus sign ΔΣ ADC (Delta-Sigma Analog-to-Digital
Converter). The pulse-width modulated (PWM) open-drain output, with a pull-up resistor, can drive a switching
transistor to modulate the fan. The LM64 can measure the fan speed on the pulses from the fan’s open-collector
tachometer output, pulled up by a 1.5 kΩ resistor to VDD. The ALERT open-drain output will be pulled low under
certain conditions descibed in the sections below. The T_Crit open-drain output will be pulled low when the
T_Crit setpoint temperature limit is exceeded. This behaves as a typical comparator function without any
latching.
The LM64's two-wire interface is compatible with the SMBus Specification 2.0 . For more information the reader
is directed to www.smbus.org.
In the LM64, digital comparators are used to compare the measured Local Temperature (LT) to the Local High
Setpoint user-programmable temperature limit register. The measured Remote Temperature (RT) is digitally
compared to the Remote High Setpoint (RHS), the Remote Low Setpoint (RLS), and the Remote T_CRIT
Setpoint (RCS) user-programmable temperature limits. An ALERT output will occur when the measured
temperature is: (1) higher than either the High Setpoint or the T_CRIT Setpoint, or (2) lower than the Low
Setpoint. The ALERT Mask register allows the user to prevent the generation of these ALERT outputs.
The temperature hysteresis is set by the value placed in the Hysteresis Register (TH).
The LM64 may be placed in a low power Standby mode by setting the Standby bit found in the Configuration
Register. In the Standby mode continuous conversions are stopped. In Standby mode the user may choose to
allow the PWM output signal to continue, or not, by programming the PWM Disable in Standby bit in the
Configuration Register.
The Local Temperature reading and setpoint data registers are 8-bits wide. The format of the 11-bit remote
temperature data is a 16-bit left justified word. Two 8-bit registers, high and low bytes, are provided for each
setpoint as well as the temperature reading. Two Remote Temperature Offset (RTO) Registers: High Byte and
Low Byte (RTOHB and RTOLB) may be used to correct the temperature readings by adding or subtracting a
fixed value based on a different non-ideality factor of the thermal diode if different from the graphics processor
thermal diode. See Diode Non_Ideality.
CONVERSION SEQUENCE
The LM64 takes approximately 31.25 ms to convert the Local Temperature (LT), Remote Temperature (RT), and
to update all of its registers. The Conversion Rate may be modified using the Conversion Rate Register. When
the conversion rate is modified a delay is inserted between conversions, the actual conversion time remains at
31.25 ms. Different Conversion Rates will cause the LM64 to draw different amounts of supply current as shown
in Figure 4.
2600
SUPPLY CURRENT (PA
2300
2000
1700
1400
1100
800
500
200
0.01
0.1
1.0
10
100
CONVERSION RATE (Hz)
Figure 4. Supply Current vs Conversion Rate
10
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THE ALERT OUTPUT
When the ALERT Mask bit in the Configuration register is written as zero the ALERT interrupts are enabled.
The LM64's ALERT pin is versatile and can produce three different methods of use to best serve the system
designer: (1) as a temperature comparator (2) as a temperature-based interrupt flag, and (3) as part of an
SMBus ALERT System. The three methods of use are further described below. The ALERT and interrupt
methods are different only in how the user interacts with the LM64.
The remote temperature (RT) reading is associated with a T_CRIT Setpoint Register, and both local and remote
temperature (LT and RT) readings are associated with a HIGH setpoint register (LHS and RHS). The RT is also
associated with a LOW setpoint register (RLS). At the end of every temperature reading a digital comparison
determines whether that reading is above its HIGH or T_CRIT setpoint or below its LOW setpoint. If so, the
corresponding bit in the ALERT Status Register is set. If the ALERT mask bit is low, any bit set in the ALERT
Status Register, with the exception of Busy or Open, will cause the ALERT output to be pulled low. Any
temperature conversion that is out of the limits defined in the temperature setpoint registers will trigger an
ALERT. Additionally, the ALERT Mask Bit must be cleared to trigger an ALERT in all modes.
The three different ALERT modes will be discussed in the following sections.
ALERT Output as a Temperature Comparator
When the LM64 is used in a system in which does not require temperature-based interrupts, the ALERT output
could be used as a temperature comparator. In this mode, once the condition that triggered the ALERT to go low
is no longer present, the ALERT is negated (Figure 5). For example, if the ALERT output was activated by the
comparison of LT > LHS, when this condition is no longer true, the ALERT will return HIGH. This mode allows
operation without software intervention, once all registers are configured during set-up. In order for the ALERT to
be used as a temperature comparator, the Comparator Mode bit in the Remote Diode Temperature Filter and
Comparator Mode Register must be asserted. This is not the power-on default state.
TEMPERATURE
Remote High Limit
RDTS Measurement
LM64 ALERT Pin
Status Register: RTDS High
TIME
Figure 5. ALERT Output as Temperature Comparator Response Diagram
ALERT Output as an Interrupt
The LM64's ALERT output can be implemented as a simple interrupt signal when it is used to trigger an interrupt
service routine. In such systems it is desirable for the interrupt flag to repeatedly trigger during or before the
interrupt service routine has been completed. Under this method of operation, during the read of the ALERT
Status Register the LM64 will set the ALERT Mask bit in the Configuration Register if any bit in the ALERT
Status Register is set, with the exception of Busy and Open. This prevents further ALERT triggering until the
master has reset the ALERT Mask bit, at the end of the interrupt service routine. The ALERT Status Register bits
are cleared only upon a read command from the master (see Figure 5) and will be re-asserted at the end of the
next conversion if the triggering condition(s) persist(s). In order for the ALERT to be used as a dedicated
interrupt signal, the Comparator Mode bit in the Remote Diode Temperature Filter and Comparator Mode
Register must be set low. This is the power-on default state. The following sequence describes the response of a
system that uses the ALERT output pin as an interrupt flag:
1. Master senses ALERT low.
2. Master reads the LM64 ALERT Status Register to determine what caused the ALERT.
3. LM64 clears ALERT Status Register, resets the ALERT HIGH and sets the ALERT Mask bit in the
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Configuration Register.
4. Master attends to conditions that caused the ALERT to be triggered. The fan is started, setpoint limits are
adjusted, etc.
5. Master resets the ALERT Mask bit in the Configuration Register.
TEMPERATURE
Remote High Limit
LM64
ALERT pin
RDTS Measurement
ALERT mask set in
response to reading of
status register by master
End of Temperature
conversion
Status Register: RTDS High
TIME
Figure 6. ALERT Output as an Interrupt Temperature Response Diagram
ALERT Output as an SMBus ALERT
An SMBus alert line is created when the ALERT output is connected to: (1) one or more ALERT outputs of other
SMBus compatible devices, and (2) to a master. Under this implementation, the LM64's ALERT should be
operated using the ARA (Alert Response Address) protocol. The SMBus 2.0 ARA protocol, defined in the SMBus
specification 2.0, is a procedure designed to assist the master in determining which part generated an interrupt
and to service that interrupt.
The SMBus alert line is connected to the open-drain ports of all devices on the bus, thereby AND'ing them
together. The ARA method allows the SMBus master, with one command, to identify which part is pulling the
SMBus alert line LOW. It also prevents the part from pulling the line LOW again for the same triggering condition.
When an ARA command is received by all devices on the bus, the devices pulling the SMBus alert line LOW: (1)
send their address to the master and (2) release the SMBus alert line after acknowledgement of their address.
The SMBus Specifications 1.1 and 2.0 state that in response to and ARA (Alert Response Address) “after
acknowledging the slave address the device must disengage its ALERT pulldown”. Furthermore, “if the host still
sees ALERT low when the message transfer is complete, it knows to read the ARA again.” This SMBus
“disengaging ALERT requirement prevents locking up the SMBus alert line. Competitive parts may address the
“disengaging of ALERT” differently than the LM64 or not at all. SMBus systems that implement the ARA protocol
as suggested for the LM64 will be fully compatible with all competitive parts.
The LM64 fulfills “disengaging of ALERT” by setting the ALERT Mask Bit in the Configuration Register after
sending out its address in response to an ARA and releasing the ALERT output pin. Once the ALERT Mask bit is
activated, the ALERT output pin will be disabled until enabled by software. In order to enable the ALERT the
master must read the ALERT Status Register, during the interrupt service routine and then reset the ALERT
Mask bit in the Configuration Register to 0 at the end of the interrupt service routine.
The following sequence describes the ARA response protocol.
1. Master senses SMBus alert line low
2. Master sends a START followed by the Alert Response Address (ARA) with a Read Command.
3. Alerting Device(s) send ACK.
4. Alerting Device(s) send their address. While transmitting their address, alerting devices sense whether their
address has been transmitted correctly. (The LM64 will reset its ALERT output and set the ALERT Mask bit
once its complete address has been transmitted successfully.)
5. Master/slave NoACK
6. Master sends STOP
7. Master attends to conditions that caused the ALERT to be triggered. The ALERT Status Register is read and
fan started, setpoints adjusted, etc.
12
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8. Master resets the ALERT Mask bit in the Configuration Register.
The ARA, 000 1100, is a general call address. No device should ever be assigned to this address.
The ALERT Configuration bit in the Remote Diode Temperature Filter and Comparator Mode Register must be
set low in order for the LM64 to respond to the ARA command.
The ALERT output can be disabled by setting the ALERT Mask bit in the Configuration Register. The power-on
default is to have the ALERT Mask bit and the ALERT Configuration bit low.
TEMPERATURE
Remote High Limit
RDTS Measurement
LM64
ALERT Pin
ALERT mask set in
response to ARA
from master
Status Register: Remote High
TIME
Figure 7. ALERT Output as an SMBus ALERT Temperature Response Diagram
SMBus INTERFACE
Since the LM64 operates as a slave on the SMBus, the SMBCLK line is an input and the SMBDAT line is bidirectional. The LM64 never drives the SMBCLK line and it does not support clock stretching. The LM64 has two
hardware-selectable 7-bit slave addresses. The user may input a logical High or Low on the A0 Address pin to
select one of the two pre-programmed SMBus slave addresses. The options are as follows:
A0
Pin
SMBus
Address
0x[Hex]
SMBus Slave Address Bits
A6
A5
A4
A3
A2
A1
A0
0
18
0
0
1
1
0
0
0
1
4E
1
0
0
1
1
1
0
POWER-ON RESET (POR) DEFAULT STATES
For information on the POR default states see LM64 REGISTER MAP IN FUNCTIONAL ORDER.
TEMPERATURE DATA FORMAT
Temperature data can only be read from the Local and Remote Temperature registers. The High, Low and
T_CRIT setpoint registers are Read/Write.
Remote temperature data is represented by an 11-bit, two's complement word with a Least Significant Bit (LSB)
equal to 0.125°C. The data format is a left justified 16-bit word available in two 8-bit registers. Some examples of
temperature conversions are shown below.
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Table 2. Actual vs. LM64 Remote Temperature Conversion (1)
(1)
Actual Remote Diode
Temperature,°C
LM64 Remote Diode
Temperature Register, °C
Binary Results in LM64 Remote
Temperature Register
Hex Remote
Temperature Register
120
+104
0110 1000 0000 0000
6800h
125
+109
0110 1101 0000 0000
6D00h
126
+110
0110 1110 0000 0000
6E00h
130
+114
0111 0010 0010 0000
7200h
135
+119
0111 0111 0000 0000
7700h
140
+124
0111 1100 0000 0000
7C00h
Output is 11-bit two's complement word. LSB = 0.125 °C.
Table 3. Actual vs. Remote T_Crit Setpoint Example
Actual Remote Diode T_Crit
Setpoint,°C
Remote T_CRIT
High Setpoint, °C
Binary Remote T_CRIT
High Setpoint Value
Hex Remote T_CRIT High
Setpoint Value
126
+110
0110 1110
6Eh
Local Temperature data is represented by an 8-bit, two's complement byte with an LSB equal to 1°C:
Digital Output
Temperature
Binary
Hex
+125°C
0111 1101
7D
+25°C
0001 1001
19
+1°C
0000 0001
01
0°C
0000 0000
00
−1°C
1111 1111
FF
−25°C
1110 0111
E7
−55°C
1100 1001
C9
OPEN-DRAIN OUTPUTS, INPUTS, AND PULL-UP RESISTORS
The SMBDAT, ALERT, T_Crit, GPIO and PWM open-drain outputs and the GPD, TACH, and A0 inputs are
pulled-up by pull-up resistors to VDDas suggested in the table below.
Pin Name
(1)
14
Pin Number
Suggested Pull-up Resistor
Range
Typical
SMBCLK
17
1 kΩ to 2 kΩ
1.5 kΩ
SMBDAT
16
1 kΩ to 2 kΩ
1.5 kΩ
ALERT
14
1 kΩ to 5 kΩ
3 kΩ
T_Crit
8
1 kΩ to 5 kΩ
3 kΩ
A0
12
5 kΩ to 20 kΩ
10 kΩ
GPIOx
1-3;18,19
5 kΩ to 20 kΩ
10 kΩ
GPDx
20-24
5 kΩ to 20 kΩ
10 kΩ
PWM
4
TACH
15
See
(1)
1 kΩ to 5 kΩ
See
(1)
3 kΩ
Depends on the fan drive circuitry connected to this pin. In the absence of fan control circuitry use a 1
kΩ pull-up resistor to VDD.
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DIODE FAULT DETECTION
The LM64 can detect fault conditions caused by the remote diode. If the D+ pin is detected to be shorted to VDD,
or open: (1) the Remote Temperature High Byte (RTHB) register is loaded with 127°C, (2) the Remote
Temperature Low Byte (RTLB) register is loaded with 0, and (3) the OPEN bit (D2) in the status register is set.
Therefore, if the Remote T_CRIT setpoint register (RCS): (1) is set to a value less than +127°C and (2) the
ALERT Mask is disabled, then the ALERT output pin will be pulled low. If the Remote High Setpoint High Byte
(RHSHB) is set to a value less than +127°C and (2) the ALERT Mask is disabled, then the ALERT and T_Crit
outputs will be pulled low. The OPEN bit by itself will not trigger an ALERT.
If the D+ pin is shorted to either ground or D−, then the Remote Temperature High Byte (RTHB) register is
loaded with −128°C (1000 0000) and the OPEN bit in the ALERT Status Register will not be set. A temperature
reading of −128°C indicates that D+ is shorted to either ground or D-. If the value in the Remote Low Setpoint
High Byte (RLSHB) Register is more than −128°C and the ALERT Mask is Disabled, ALERT will be pulled low.
COMMUNICATING WITH THE LM64
Each data register in the LM64 falls into one of four types of user accessibility:
1. Read Only
2. Write Only
3. Read/Write same address
4. Read/Write different address
A Write to the LM64 is comprised of an address byte and a command byte. A write to any register requires one
data byte.
Reading the LM64 Registers can take place after the requisite register setup sequence takes place. See LM64
Required Initial Fan Control Register Sequence.
The data byte has the Most Significant Bit (MSB) first. At the end of a read, the LM64 can accept either
Acknowledge or No-Acknowledge from the Master. Note that the No-Acknowledge is typically used as a signal
for the slave indicating that the Master has read its last byte.
DIGITAL FILTER
The LM64 incorporates a user-configured digital filter to suppress erroneous Remote Temperature readings due
to noise. The filter is accessed in the Remote Diode Temperature Filter and Comparator Mode Register. The
filter can be set according to the following table.
Level 2 is maximum filtering.
Table 4. Digital Filter
Selection Table
D2
D1
Filter
0
0
No Filter
0
1
Level 1
1
0
Level 1
1
1
Level 2
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50
No Filter
TEMPERATURE (°C)
45
40
Filter Level 1
35
Filter Level 2
30
25
0
5
10
15
20
25
NUMBER OF SAMPLES
Figure 8. Step Response of the Digital Filter
50
TEMPERATURE (°C)
45
No Filter
40
Filter Level 1
35
Filter Level 2
30
25
0
5
10
15
20
25
NUMBER OF SAMPLES
Figure 9. Impulse Response of the Digital Filter
45
LM64
with
Filter Off
43
TEMPERATURE (oC)
41
39
37
35
LM64
with
Filter On
33
31
29
27
25
0
50
100
150
200
SAMPLE NUMBER
The Filter on and off curves were purposely offset to better show noise performance.
Figure 10. Digital Filter Response in an Intel Pentium 4 processor System
FAULT QUEUE
The LM64 incorporates a Fault Queue to suppress erroneous ALERT triggering . The Fault Queue prevents false
triggering by requiring three consecutive out-of-limit HIGH, LOW, or T_CRIT temperature readings. See
Figure 11. The Fault Queue defaults to OFF upon power-up and may be activated by setting the RDTS Fault
Queue bit in the Configuration Register to a 1.
16
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TEMPERATURE
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RDTS Measurement
Status Register: RTDS High
n
n+1
n+2
n+3
n+4
n+5
SAMPLE NUMBER
Figure 11. Fault Queue Temperature Response Diagram
ONE-SHOT REGISTER
The One-Shot Register is used to initiate a single conversion and comparison cycle when the device is in
standby mode, after which the data returns to standby. This is not a data register. A write operation causes the
one-shot conversion. The data written to this address is irrelevant and is not stored. A zero will always be read
from this register.
SERIAL INTERFACE RESET
In the event that the SMBus Master is reset while the LM64 is transmitting on the SMBDAT line, the LM64 must
be returned to a known state in the communication protocol. This may be done in one of two ways:
1. When SMBDAT is Low, the LM64 SMBus state machine resets to the SMBus idle state if either SMBData or
SMBCLK are held Low for more than 35 ms (tTIMEOUT). All devices are to timeout when either the SMBCLK or
SMBDAT lines are held Low for 25 ms – 35 ms. Therefore, to insure a timeout of all devices on the bus,
either the SMBCLK or the SMBData line must be held Low for at least 35 ms.
2. With both SMBDAT and SMBCLK High, the master can initiate an SMBus start condition with a High to Low
transition on the SMBDAT line. The LM64 will respond properly to an SMBus start condition at any point
during the communication. After the start the LM64 will expect an SMBus Address address byte.
LM64 Registers
The following pages include: LM64 REGISTER MAP IN HEXADECIMAL ORDER a Register Map in Hexadecimal
Order, which shows a summary of all registers and their bit assignments, LM64 REGISTER MAP IN
FUNCTIONAL ORDER, a Register Map in Functional Order, and LM64 INITIAL REGISTER SEQUENCE AND
REGISTER DESCRIPTIONS IN FUNCTIONAL ORDER, a detailed explanation of each register. Do not address
the unused or manufacturer’s test registers.
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LM64 REGISTER MAP IN HEXADECIMAL ORDER
The following is a Register Map grouped in hexadecimal address order. Some address locations have been left
blank to maintain compatibility with LM86. Addresses in parenthesis are mirrors of “Same As” address for
backwards compatibility with some older software. Reading or writing either address will access the same 8-bit
register.
18
Register
0x[HEX]
Register
Name
00
DATA BITS
D7
D6
D5
D4
D3
D2
D1
D0
Local
Temperatur
e
LT7
LT6
LT5
LT4
LT3
LT2
LT1
LT0
01
Rmt Temp
MSB
RTHB±
RTHB14
RTHB13
RTHB12
RTHB11
RTHB10
RTHB9
RTHB8
02
ALERT
Status
BUSY
LHIGH
0
RHIGH
RLOW
RDFA
RCRIT
TACH
03
Configuratio
n
ALTMSK
STBY
PWMDIS
0
0
ALT/TCH
TCRITOV
FLTQUE
04
Conversion
Rate
0
0
0
0
CONV3
CONV2
CONV1
CONV0
05
Local High
Setpoint
LHS7
LHS6
LHS5
LHS4
LHS3
LHS2
LHS1
LHS0
06
[Reserved]
07
Rmt High
Setpoint
MSB
RHSHB15
RHSHB14
RHHBS13
RHSHB12
RHSHB11
RHSHB10
RHSHB9
RHSHB8
08
Rmt Low
Setpoint
MSB
RLSHB15
RLSHB14
RLSHB13
RLSHB12
RLHBS11
RLSHB10
RLSHB9
RLSHB8
(09)
Same as 03
(0A)
Same as 04
(0B)
Same as 05
0C
[Reserved]
(0D)
Same as 07
(0E)
Same as 08
Not Used
Not Used
0F
One Shot
10
Rmt Temp
LSB
RTLB7
RTLB6
Write Only. Write command triggers one temperature conversion cycle.
RTLB5
0
0
0
0
0
11
Rmt Temp
Offset MSB
RTOHB15
RTOHB14
RTOHB13
RTOHB12
RTOHB11
RTOHB10
RTOHB9
RTOHB8
12
Rmt Temp
Offset LSB
RTOLB7
RTOLB6
RTOLB5
0
0
0
0
0
13
Rmt High
Setpoint
LSB
RHSLB7
RHSLB6
RHSLB5
0
0
0
0
0
14
Rmt Low
Setpoint
LSB
RLSLB7
RLSLB6
RLSLB5
0
0
0
0
0
15
[Reserved]
16
ALERT
Mask
ALTMSK3
1
ALTMSK1
ALTMSK0
17
[Reserved]
Not Used
18
[Reserved]
Not Used
19
Rmt TCRIT
Setpoint
RCS7
RCS6
RCS5
RCS4
RCS3
RCS2
RCS1
RCS0
1A
General
Purpose
Input
0
0
0
GPI5
GPI4
GPI3
GPI2
GPI1
Not Used
1
ALTMSK6
1
ALTMSK4
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Register
0x[HEX]
Register
Name
1B
General
Purpose
Output
1C–1F
[Reserved]
DATA BITS
D7
D6
D5
D4
D3
D2
D1
D0
0
0
0
GPO5
GPO4
GPO3
GPO2
GPO1
RTH2
RTH1
RTH0
Not Used
20
[Reserved]
21
Rmt TCRIT
Hysteresis
Not Used
22–2F
[Reserved]
Not Used
30–3F
[Reserved]
Not Used
40–45
[Reserved]
46
Tach Count
LSB
TCLB5
TCLB4
TCLB3
TCLB2
TCLB1
TCLB0
TEDGE1
TEDGE0
47
Tach Count
MSB
TCHB13
TCHB12
TCHB11
TCHB10
TCHB9
TCHB8
TCHB7
TCHB6
48
Tach Limit
LSB
TLLB7
TLLB6
TLLB5
TLLB4
TLLB3
TLLB2
Not Used
Not Used
49
Tach Limit
MSB
TLHB15
TLHB14
TLHB13
TLHB12
TLHB11
TLHB10
TLHB9
TLHB8
4A
PWM and
RPM
0
0
PWPGM
PWOUT±
PWCKSL
0
TACH1
TACH0
4B
Fan SpinUp Config
0
0
SPINUP
SPNDTY1
SPNDTY0
SPNUPT2
SPNUPT1
SPNUPT0
4C
PWM Value
0
0
PWVAL5
PWVAL4
PWVAL3
PWVAL2
PWVAL1
PWVAL0
4D
PWM
Frequency
0
0
0
PWMF4
PWMF3
PWMF2
PWMF1
PWMF0
4E
[Reserved]
4F
Lookup
Table
Hystersis
0
0
0
LOOKH4
LOOKH2
LOOKH1
LOOKH0
50–5F
Lookup
Table
60–BE
[Reserved]
BF
Rmt Diode
Temp Filter
RTH7
RTH6
RTH5
RTH4
RTH3
Not Used
Not Used
LOOKH3
Lookup Table of up to 8 PWM and Temp Pairs in 8-bit Registers
Not Used
0
0
0
0
0
RDTF1
RDTF0
ALTCOMP
C0–FD
[Reserved]
FE
Manufactur
er’s ID
0
0
0
0
Not Used
0
0
0
1
FF
Stepping/Di
e Rev. ID
0
1
0
1
0
0
0
1
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LM64 REGISTER MAP IN FUNCTIONAL ORDER
The following is a Register Map grouped in Functional Order. Some address locations have been left blank to
maintain compatibility with LM86. Addresses in parenthesis are mirrors of named address. Reading or writing
either address will access the same 8-bit register. The Fan Control and Configuration Registers are listed first, as
there is a required order to setup these registers first and then setup the others. The detailed explanations of
each register will follow the order shown below. POR = Power-On-Reset.
Register
[HEX]
Register Name
Read/Write
POR Default
[HEX]
FAN CONTROL REGISTERS
4A
PWM and RPM
R/W
20
4B
Fan Spin-Up Configuration
R/W
3F
4D
PWM Frequency
4C
R/W
17
Read Only
(R/W if Override Bit is Set)
00
Lookup Table
R/W
See Table
Lookup Table Hysteresis
R/W
04
R/W
00
PWM Value
50–5F
4F
CONFIGURATION REGISTER
03 (09)
Configuration
TACHOMETER COUNT AND LIMIT REGISTERS
46
Tach Count LSB
Read Only
N/A
47
Tach Count MSB
Read Only
N/A
48
Tach Limit LSB
R/W
FF
49
Tach Limit MSB
R/W
FF
LOCAL TEMPERATURE AND LOCAL SETPOINT REGISTERS
00
Local Temperature
Read Only
N/A
05 (0B)
Local High Setpoint
R/W
46 (70°)
REMOTE DIODE TEMPERATURE AND SETPOINT REGISTERS
01
Remote Temperature MSB
Read Only
N/A
10
Remote Temperature LSB
Read Only
N/A
11
Remote Temperature Offset MSB
R/W
00
12
Remote Temperature Offset LSB
R/W
00
07 (0D)
Remote High Setpoint MSB
R/W
46 (70°C)
13
Remote High Setpoint LSB
R/W
00
08 (0E)
Remote Low Setpoint MSB
R/W
00 (0°C)
14
Remote Low Setpoint LSB
R/W
00
19
Remote TCRIT Setpoint
R/W
55 (85°C)
21
Remote TCRIT Hys
R/W
0A (10°C)
BF
Remote Diode Temperature Filter
R/W
00
R/W
08
Write Only
N/A
CONVERSION AND ONE-SHOT REGISTERS
04 (0A)
0F
Conversion Rate
One-Shot
ALERT STATUS AND MASK REGISTERS
02
ALERT Status
Read Only
N/A
16
ALERT Mask
R/W
A4
ID REGISTERS
FE
Manufacturer's ID
Read Only
01
FF
Stepping/Die Rev. ID
Read Only
51
GENERAL PURPOSE REGISTERS
1A
(1)
20
General Purpose Input
Read Only
See
(1)
For Register 0x1A the Power-On-Reset for the five LSB's are the logic states present on the 5 GPIOx pins.
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Register
[HEX]
1B
Register Name
Read/Write
General Purpose Output
POR Default
[HEX]
R/W
See
(2)
[RESERVED] REGISTERS—NOT USED
(2)
06
Not Used
N/A
N/A
0C
Not Used
N/A
N/A
15
Not Used
N/A
N/A
17
Not Used
N/A
N/A
18
Not Used
N/A
N/A
1C–1F
Not Used
N/A
N/A
20
Not Used
N/A
N/A
22–2F
Not Used
N/A
N/A
30–3F
Not Used
N/A
N/A
40–45
Not Used
N/A
N/A
4E
Not Used
N/A
N/A
60–BE
Not Used
N/A
N/A
C0–FD
Not Used
N/A
N/A
For Register 0x1B the Power-On-Reset for the five LSB's are the logic states present on the 5 GPDx pins.
LM64 INITIAL REGISTER SEQUENCE AND REGISTER DESCRIPTIONS IN FUNCTIONAL ORDER
The following is a Register Map grouped in functional and sequence order. Some address locations have been
left blank to maintain compatibility with LM86. Addresses in parenthesis are mirrors of named address for
backwards compatibility with some older software. Reading or writing either address will access the same 8-bit
register.
LM64 Required Initial Fan Control Register Sequence
Important! The BIOS must follow the sequence below to configure the following Fan Registers for the LM64
before using any of the Fan or Tachometer or PWM registers:
[Register]HEX and Setup Instructions (1)
Step
(1)
1
[4A] Write bits 0 and 1; 3 and 4. This includes tach settings if used, PWM internal clock select (1.4 kHz or 360 kHz) and PWM
Output Polarity.
2
[4B] Write bits 0 through 5 to program the spin-up settings.
3
[4D] Write bits 0 through 4 to set the frequency settings. This works with the PWM internal clock select.
4
Choose, then write, only one of the following:
A. [4F–5F] the Lookup Table, or
B. [4C] the PWM value bits 0 through 5.
5
If Step 4A, Lookup Table, was chosen and written then write [4A] bit 5 = 0.
All other registers can be written at any time after the above sequence.
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LM64 REGISTER DESCRIPTIONS IN FUNCTIONAL ORDER
Fan Control Registers
Address
Hex
Read/
Write
Bit
s
POR
Value
Name
Description
4AHEX PWM AND RPM REGISTER
7:6
4A
R/W
00
These bits are unused and always set to 0.
PWM
Program
0: the PWM Value (register 4C) and the Lookup Table (50–5F) are read-only. The
PWM value (0 to 100%) is determined by the current remote diode temperature and
the Lookup Table, and can be read from the PWM value register.
1: the PWM value (register 4C) and the Lookup Table (Register 50–5F) are
read/write enabled. Writing the PWM Value register will set the PWM output. This is
also the state during which the Lookup Table can be written.
5
1
4
0
PWM
Output
Polarity
3
0
PWM Clock
Select
if 0, the master PWM clock is 360 kHz
if 1, the master PWM clock is 1.4 kHz.
2
0
[Reserved]
Always write 0 to this bit.
Tachometer
Mode
00: Traditional tach input monitor, false readings when under minimum detectable
RPM.
01: Traditional tach input monitor, FFFF reading when under minimum detectable
RPM.
10: Most accurate readings, FFFF reading when under minimum detectable RPM.
11: Least effort on programmed PWM of fan, FFFF reading when under minimum
detectable RPM.
Note: If the PWM Clock is 360 kHz, mode 00 is used regardless of the setting of
these two bits.
1:0
00
0: the PWM output pin will be 0 V for fan OFF and open for fan ON.
1: the PWM output pin will be open for fan OFF and 0 V for fan ON.
4BHEX FAN SPIN-UP CONFIGURATION REGISTER
7:6
5
4B
R/W
4:3
2:0
0
1
11
111
These bits are unused and always set to 0
Fast
Tachometer
Spin-Up
PWM
Spin-Up
Duty Cycle
PWM
Spin-Up
Time
If 0, the fan spin-up uses the duty cycle and spin-up time, bits 0–4.
If 1, the LM64 sets the PWM output to 100% until the spin-up times out (per bits 0–2)
or the minimum desired RPM has been reached (per the Tachometer Setpoint
setting) using the tachometer input, whichever happens first. This bit overrides the
PWM Spin-Up Duty Cycle register (bits 4:3)—PWM output is always 100%.
If PWM Spin-Up Time (bits 2:0) = 000, the Spin-Up cycle is bypassed, regardless of
the state of this bit.
00: Spin-Up cycle bypassed (no Spin-Up), unless Fast Tachometer Terminated SpinUp (bit 5) is set.
01: 50%
10: 75%–81% Depends on PWM Frequency. See Applications Notes.
11: 100%
000:
001:
010:
011:
100:
101:
110:
111:
Spin-Up cycle bypassed (No Spin-Up)
0.05 seconds
0.1 s
0.2 s
0.4 s
0.8 s
1.6 s
3.2 s
4DHEX FAN PWM FREQUENCY REGISTER
7:5
4D
22
R/W
4:0
000
10111
These bits are unused and always set to 0
PWM
Frequency
The PWM Frequency = PWM_Clock / 2n, where PWM_Clock = 360 kHz or 1.4 kHz
(per the PWM Clock Select bit in Register 4A), and n = value of the register. Note: n
= 0 is mapped to n = 1. See the Applications Notes at the end of this datasheet.
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Address
Hex
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Read/
Write
Bit
s
POR
Value
Name
Description
4CHEX PWM VALUE REGISTER
7:6
4C
Read
(Write
only if
reg 4A 5:0
bit 5 =
1.)
00
000000
These bits are unused and always set to 0
PWM
Value
If PWM Program (register 4A, bit 5) = 0 this register is read only and reflects the
LM64’s current PWM value from the Lookup Table.
If PWM Program (register 4A, bit 5) = 1, this register is read/write and the desired
PWM value is written directly to this register, instead of from the Lookup Table, for
direct fan speed control.
This register will read 0 during the Spin-Up cycle.
See Application Notes section at the end of this datasheet for more information
regarding the PWM Value and Duty Cycle in %.
50HEX to 5FHEX LOOKUP TABLE (7 Bits for Temperature and 6 Bits for PWM for each Temperature/PWM Pair)
50
51
52
53
54
55
56
57
58
59
5A
5B
5C
5D
5E
5F
7
0
6:0
0x7F
7:6
00
5:0
0x3F
7
0
6:0
0x7F
7:6
00
5:0
0x3F
7
0
6:0
0x7F
7:6
00
5:0
0x3F
7
0
6:0
0x7F
Read. 7:6
(Write
only if 5:0
reg 4A 7
bit 5 =
1.)
6:0
00
0x3F
0
0x7F
7:6
00
5:0
0x3F
7
0
6:0
0x7F
7:6
00
5:0
0x3F
7
0
6:0
0x7F
7:6
00
5:0
0x3F
7
0
6:0
0x7F
7:6
00
5:0
0x3F
Lookup Table
Temperature
Entry 1
This bit is unused and always set to 0.
Lookup Table
PWM Entry 1
These bits are unused and always set to 0.
Lookup Table
Temperature
Entry 2
This bit is unused and always set to 0.
Lookup Table
PWM Entry 2
These bits are unused and always set to 0.
Lookup Table
Temperature
Entry 3
This bit is unused and always set to 0.
Lookup Table
PWM Entry 3
These bits are unused and always set to 0.
Lookup Table
Temperature
Entry 4
This bit is unused and always set to 0.
Lookup Table
PWM Entry 4
These bits are unused and always set to 0.
Lookup Table
Temperature
Entry 5
This bit is unused and always set to 0.
Lookup Table
PWM Entry 5
These bits are unused and always set to 0.
Lookup Table
Temperature
Entry 6
This bit is unused and always set to 0.
Lookup Table
PWM Entry 6
These bits are unused and always set to 0.
Lookup Table
Temperature
Entry 7
This bit is unused and always set to 0.
Lookup Table
PWM Entry 7
These bits are unused and always set to 0.
Lookup Table
Temperature
Entry 8
This bit is unused and always set to 0.
Lookup Table
PWM Entry 8
These bits are unused and always set to 0.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 51.
The PWM value corresponding to the temperature limit in register 50.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 53.
The PWM value corresponding to the temperature limit in register 52.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 55.
The PWM value corresponding to the temperature limit in register 54.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 57.
The PWM value corresponding to the temperature limit in register 56.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 59.
The PWM value corresponding to the temperature limit in register 58.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 5B.
The PWM value corresponding to the temperature limit in register 5A.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 5D.
The PWM value corresponding to the temperature limit in register 5C.
If the remote diode temperature exceeds this value, the PWM output will be the value
in Register 5F.
The PWM value corresponding to the temperature limit in register 5E.
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Address
Hex
Read/
Write
Bit
s
POR
Value
www.ti.com
Name
Description
4FHEX LOOKUP TABLE HYSTERESIS
4F
R/W
7:5
000
4:0
00100
Lookup
Table
Hysteresis
These bits are unused and always set to 0
The amount of hysteresis applied to the Lookup Table. (1 LSB = 1°C).
Configuration Register
ADDRESS Read/
Hex
Write
Bits
POR
Value
Name
Description
03 (09)HEX CONFIGURATION REGISTER
7
When this bit is a 0, ALERT interrupts are enabled.
When this bit is set to a 1, ALERT interrupts are masked, and the ALERT pin is
always in a high impedance (open) state.
0
STANDBY
When this bit is a 0, the LM64 is in operational mode, converting, comparing, and
updating the PWM output continuously.
When this bit is a 1, the LM64 enters a low power standby mode.
In STANDBY, continuous conversions are stopped, but a conversion/comparison
cycle may be initiated by writing any value to register 0x0F. Operation of the
PWM output in STANDBY depends on the setting of bit 5 in this register.
5
0
PWM Disable
in STANDBY
When this bit is a 0, the LM64’s PWM output continues to output the current fan
control signal while in STANDBY.
When this bit is a 1, the PWM output is disabled (as defined by the PWM polarity
bit) while in STANDBY.
4:1
0000
6
03 (09)
ALERT
Mask
0
R/W
0
0
These bits are unused and always set to 0.
RDTS Fault
Queue
0: an ALERT will be generated if any Remote Diode conversion result is above
the Remote High Set Point or below the Remote Low Setpoint.
1: an ALERT will be generated only if three consecutive Remote Diode
conversions are above the Remote High Set Point or below the Remote Low
Setpoint.
Tachometer Count And Limit Registers
ADDRESS
Hex
Read/
Write
Bits
POR
Value
Name
Description
47HEX TACHOMETER COUNT (MSB) and 46HEX TACHOMETER COUNT (LSB) REGISTERS
(16 bits: Read LSB first to lock MSB and ensure MSB and LSB are from the same reading)
47
Read Only
7:0
N/A
Tachometer
Count (MSB)
Read Only
7:2
N/A
Tachometer
Count (MSB)
These registers contain the current 16-bit Tachometer Count,
representing the period of time between tach pulses. Note that the
16-bit tachometer MSB and LSB are reversed from the 16-bit
temperature readings
Bits:
Edges Used
00:
46
Read Only
1:0
00
Tachometer
Edge Count
Tach_Count_Multiple
Reserved - do not use
01:
2
4
10:
2
2
11:
5
1
Note: If PWM_Clock_Select = 360 kHz, then Tach_Count_Multiple
= 1 regardless of the setting of these bits.
49HEX TACHOMETER LIMIT (MSB) and 48HEX TACHOMETER LIMIT (LSB) REGISTERS
49
48
24
R/W
7:0
0xFF
Tachometer
Limit (MSB)
R/W
7:2
0xFF
Tachometer
Limit (LSB)
R/W
1:0
[Reserved]
These registers contain the current 16-bit Tachometer Count,
representing the period of time between tach pulses. Fan RPM = (f
* 5,400,000) / (Tachometer Count), where f = 1 for 2 pulses/rev
fan; f = 2 for 1 pulse/rev fan; and f = 2/3 for 3 pulses/rev fan. See
the Application Notes section for more tachometer information.
Note that the 16-bit tachometer MSB and LSB are reversed from
the 16 bit temperature readings.
Not Used.
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Local Temperature And Local High Setpoint Registers
ADDRESS Read/
Hex
Write
Bit
s
POR
Value
Name
Description
00HEX LOCAL TEMPERATURE REGISTER (8-bits)
00
Read
Only
7:0
N/A
Local Temperature Reading (8-bit)
8-bit temperature of the LM64.
05 (0B)HEX LOCAL HIGH SETPOINT REGISTER (8-bits)
05
R/W
7:0
0x46
(70°)
Local HIGH Setpoint
High Setpoint for the internal diode.
Remote Diode Temperature, Offset And Setpoint Registers
ADDRESS Read/
Hex
Write
Bits
POR
Value
Name
Read
Only
7:0
N/A
Remote Diode
Temperature
Reading (MSB)
7:5
N/A
4:0
00
01
10
Read
Only
11
R/W
12
R/W
07 (0D)
R/W
13
R/W
08 (0E)
14
R/W
R/W
Remote Diode
Temperature
Reading (LSB)
This is the MSB of the LM64 remote diode temperature value, 2’s complement.
Bit 7 is the sign bit, bit 6 has a weight 64°C, and bit 0 has a weight of 1°C. Read
this byte first. The actual remote diode temperature is 16°C higher than the
values in registers 0x01 and 0x10.
This is the LSB of the LM64 remote diode temperature value, in 2’s complement.
Bit 7 has a weight 0.5°C, bit 6 has a weight of 0.25°C, and bit 5 has a weight of
0.125°C. The actual remote diode temperature is 16°C higher than the values in
registers 0x01 and 0x10.
Always 00.
Remote
Temperature
OFFSET (MSB)
These registers contain the offset value added to, or subtracted from, the remote
diode’s reading to compensate for the different non-ideality factors of different
processors, diodes, etc. The 2’s complement value, in these registers is added to
the output of the LM64’s ADC to form the temperature reading contained in
registers 01 and 10.
7:5
00
7:5
00
4:0
00
Remote
Temperature
OFFSET (LSB)
7:0
0x46
(70°C)
Remote HIGH
Setpoint (MSB)
7:5
00
4:0
00
Remote HIGH
Setpoint (LSB)
7:0
00
(0°C)
Remote LOW
Setpoint (MSB)
7:5
00
4:0
00
Remote LOW
Setpoint (LSB)
Always 00.
Remote Diode
T_CRIT Limit
This 8-bit integer storing the T_CRIT limit is initially 85°C (101°C actual remote
T_Crit limit). This value can be changed at any time after power-up.
Remote Diode
T_CRIT
Hysteresis
8-bit integer storing T_CRIT hysteresis. T_CRIT stays activated until the remote
diode temperature goes below [(T_CRIT Limit)—(T_CRIT Hysteresis)].
19
R/W
7:0
0x55
(85°C)
21
R/W
7:0
0x0A
(10°C)
7:3
00000
2:1
00
Remote Diode
Temperature
Filter
0
0
Comparator
Mode
BF
Description
R/W
Always 00.
High setpoint temperature for remote diode. Same format as Remote
Temperature Reading (registers 01 and 10).
Always 00.
Low setpoint temperature for remote diode. Same format as Remote
Temperature Reading (registers 01 and 10).
These bits are unused and should always set to 0.
00:
01:
10:
11:
Filter
Filter
Filter
Filter
Disabled
Level 1 (minimal filtering, same as 10)
Level 1 (minimal filtering, same as 01)
Level 2 (maximum filtering)
0: the ALERT pin functions as an Interrupt or ARA mode.
1: the ALERT pin behaves as a comparator, asserting itself when an ALERT
condition exists, de-asserting itself when the ALERT condition goes away.
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ALERT Status And Mask Registers
ADDRESS Read/
Hex
Write
Bits
POR
Value
Name
Description
02HEX ALERT STATUS REGISTER (8-bits) (All Alarms are latched until read, then cleared if alarm condition was removed at the
time of the read.)
0
Busy
When this bit is a 0, the ADC is not converting.
When this bit is set to a 1, the ADC is performing a conversion. This bit does not
affect ALERT status.
6
0
Local
High Alarm
When this bit is a 0, the internal temperature of the LM64 is at or below the Local
High Setpoint.
When this bit is a 1, the internal temperature of the LM64 is above the Local High
Setpoint, and an ALERT is triggered.
5
0
4
0
Remote
High Alarm
When this bit is a 0, the temperature of the Remote Diode is at or below the
Remote High Setpoint.
When this bit is a 1, the temperature of the Remote Diode is above the Remote
High Setpoint, and an ALERT is triggered.
3
0
Remote
Low Alarm
When this bit is a 0, the temperature of the Remote Diode is at or above the
Remote Low Setpoint.
When this bit is a 1, the temperature of the Remote Diode is below the Remote
Low Setpoint, and an ALERT is triggered.
2
0
Remote Diode
Fault Alarm
When this bit is a 0, the Remote Diode appears to be correctly connected.
When this bit is a 1, the Remote Diode may be disconnected or shorted. This
Alarm does not trigger an ALERT.
1
0
Remote
T_CRIT Alarm
When this bit is a 0, the temperature of the Remote Diode is at or below the
T_CRIT Limit.
When this bit is a 1, the temperature of the Remote Diode is above the T_CRIT
Limit, and an ALERT is triggered.
Tach Alarm
When this bit is a 0, the Tachometer count is lower than or equal to the
Tachometer Limit (the RPM of the fan is greater than or equal to the minimum
desired RPM).
When this bit is a 1, the Tachometer count is higher than the Tachometer Limit
(the RPM of the fan is less than the minimum desired RPM), and an ALERT is
triggered.
7
0x02
Read
Only
0
0
This bit is unused and always read as 0.
16HEX ALERT MASK REGISTER (8-bits)
16
26
R/W
7
1
This bit is unused and always read as 1.
6
0
5
1
4
0
Remote
High Alarm Mask
When this bit is a 0, Remote High Alarm event will generate an ALERT.
When this bit is a 1, a Remote High Alarm event will not generate an ALERT.
3
0
Remote
Low Alarm
Mask
When this bit is a 0, a Remote Low Alarm event will generate an ALERT.
When this bit is a 1, a Remote Low Alarm event will not generate an ALERT.
2
1
Local High
Alarm Mask
When this bit is a 0, a Local High Alarm event will generate an ALERT.
When this bit is a 1, a Local High Alarm will not generate an ALERT
This bit is unused and always read as 1.
This bit is unused and always read as 1.
1
0
Remote
T_CRIT
Alarm Mask
0
0
Tach
Alarm Mask
When this bit is a 0, a Remote T_CRIT event will generate an ALERT.
When this bit is a 1, a Remote T_CRIT event will not generate an ALERT.
When this bit is a 0, a Tach Alarm event will generate an ALERT.
When this bit is a 1, a Tach Alarm event will not generate an ALERT.
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Conversion Rate And One-Shot Registers
ADDRESS Read/
Hex
Write
Bits
POR
Value
Name
Description
04 (0A)HEX CONVERSION RATE REGISTER (8-bits)
04 (0A)
R/W
7:0
Sets the conversion rate of the LM64.
00000000 = 0.0625 Hz
00000001 = 0.125 Hz
00000010 = 0.25 Hz
00000011 = 0.5 Hz
00000100 = 1 Hz
00000101 = 2 Hz
00000110 = 4 Hz
00000111 = 8 Hz
00001000 = 16 Hz
00001001 = 32 Hz
All other values = 32 Hz
Conversion
Rate
0x08
04 (0A)HEX ONE-SHOT REGISTER (8-bits)
0F
Write
Only
7:0
N/A
One Shot
Trigger
Bits
POR
Value
Name
With the LM64 in the STANDBY mode a single write to this register will initiate
one complete temperature conversion cycle.
ID Registers
ADDRESS Read/
Hex
Write
Description
FFHEX STEPPING / DIE REVISION ID REGISTER (8-bits)
FF
Read
Only
7:0
Stepping/Die
Revision ID
0x51
Version of LM64
FEHEX MANUFACTURER’S ID REGISTER (8-bits)
FE
Read
Only
7:0
0x01
Manufacturer’s ID
0x01 = Texas Instruments
General Purpose Registers
ADDRES
S
Hex
Read/
Write
Bits
POR
Value
Name
Description
1AHEX GENERAL PURPOSE INPUT REGISTER (8-bits)
7:5
1A
Read
Only
4:0
000
See
(1)
These bits are unused and always set to 0.
General
Purpose
Input
These 5 bits reflect the logic states of the GPIOx pins.
1BHEX GENERAL PURPOSE OUTPUT REGISTER (8-bits)
7:5
1B
(1)
(2)
R/W
4:0
000
See
(2)
These bits are unused and always set to 0.
General
Purpose
Output
These 5 bits reflect the GPI register bits [4:0] except for Power-OnDefault when they are the 5 logic states of the General Pupose Default
(GPD) input pins.
For Register 0x1A the Power-On-Reset for the five LSB's are the logic states present on the 5 GPIOx pins.
For Register 0x1B the Power-On-Reset for the five LSB's are the logic states present on the 5 GPDx pins.
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Application Notes
FAN CONTROL DUTY CYCLE VS. REGISTER SETTINGS AND FREQUENCY
PWM
Freq
4D
[4:0]
Step
Resolution,
%
PWM
Value
4D [5:0]
for 100%
PWM
Value
4C [5:0] for
about 75%
0
PWM
Value
4C [5:0]
for 50%
PWM
Freq at
360 kHz
Internal
Clock, kHz
PWM
Freq at
1.4 kHz
Internal
Clock, Hz
Actual Duty
Cycle, %
When
75% is
Selected
Address 0 is mapped to Address 1
1
50
2
1
1
180.0
703.1
50.0
2
25
4
3
2
90.00
351.6
75.0
3
16.7
6
5
3
60.00
234.4
83.3
4
12.5
8
6
4
45.00
175.8
75.0
5
10.0
10
8
5
36.00
140.6
80.0
6
8.33
12
9
6
30.00
117.2
75.0
7
7.14
14
11
7
25.71
100.4
78.6
8
6.25
16
12
8
22.50
87.9
75.0
9
5.56
18
14
9
20.00
78.1
77.8
10
5.00
20
15
10
18.00
70.3
75.0
11
4.54
22
17
11
16.36
63.9
77.27
12
4.16
24
18
12
15.00
58.6
75.00
13
3.85
26
20
13
13.85
54.1
76.92
14
3.57
28
21
14
12.86
50.2
75.00
15
3.33
30
23
15
12.00
46.9
76.67
16
3.13
32
24
16
11.25
43.9
75.00
17
2.94
34
26
17
10.59
41.4
76.47
18
2.78
36
27
18
10.00
39.1
75.00
19
2.63
38
29
19
9.47
37.0
76.32
20
2.50
40
30
20
9.00
35.2
75.00
21
2.38
42
32
21
8.57
33.5
76.19
22
2.27
44
33
22
8.18
32.0
75.00
23
2.17
46
35
23
7.82
30.6
76.09
24
2.08
48
36
24
7.50
29.3
75.00
25
2.00
50
38
25
7.20
28.1
76.00
26
1.92
52
39
26
6.92
27.0
75.00
27
1.85
54
41
27
6.67
26.0
75.93
28
1.79
56
42
28
6.42
25.1
75.00
29
1.72
58
44
29
6.21
24.2
75.86
30
1.67
60
45
30
6.00
23.4
75.00
31
1.61
62
47
31
5.81
22.7
75.81
Computing Duty Cycles for a Given Frequency
Select a PWM Frequency from the first column corresponding to the desired actual frequency in columns 6 or 7.
Note the PWM Value for 100% Duty Cycle.
Find the Duty Cycle by taking the PWM Value of Register 4C and computing:
DutyCycle _(%) =
PWM _Value
PWM _Value _ for _ 100 %
u 100 %
(1)
Example: For a PWM Frequency of 24, a PWM Value at 100% = 48 and PWM Value actual = 28, then the Duty
Cycle is (28/48) × 100% = 58.3%.
28
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USE OF THE LOOKUP TABLE FOR NON-LINEAR PWM VALUES VS TEMPERATURE
The Lookup Table, Registers 50 through 5F, can be used to create a non-linear PWM vs Temperature curve that
could be used to reduce the acoustic noise from processor fan due to linear or step transfer functions. An
example is given below:
EXAMPLE:
In a particular system it was found that the best acoustic fan noise performance was found to occur when the
PWM vs Temperature transfer function curve was parabolic in shape.
From 25°C to 105°C the fan is to go from 20% to 100%. Since there are 8 steps to the Lookup Table we will
break up the Temperature range into 8 separate temperatures. For the 80°C over 8-steps = 10°C per step. This
takes care of the x-axis.
For the PWM Value, we first select the PWM Frequency. In this example we will make the PWM Frequency
(Register 4C) 20.
For 100% Duty Cycle then, the PWM value is 40. For 20% the minimum is 40 x (0.2) = 8.
We can then arrange the PWM, Temperature pairs in a parabolic fashion in the form of y = 0.005 • (x −25)2 + 8
Temperature
PWM Value
Calculated
Closest PWM
Value
25
8.0
8
35
8.5
9
45
10.0
10
55
12.5
13
65
16.0
16
75
20.5
21
85
26.0
26
95
32.5
33
105
40.0
40
We can then program the Lookup Table with the temperature and Closest PWM Values required for the curve
required in our example.
NON-IDEALITY FACTOR AND TEMPERATURE ACCURACY
The LM64 can be applied to remote diode sensing in the same way as other integrated-circuit temperature
sensors. It can be soldered to a printed-circuit board, and because the path of best thermal conductivity is
between the die and the pins, its temperature will effectively be that of the printed-circuit board lands and traces
soldered to its pins. This presumes that the ambient air temperature is nearly the same as the surface
temperature of the printed-circuit board. If the air temperature is much higher or lower than the surface
temperature, the actual temperature of the LM64 die will be an intermediate temperature between the surface
and air temperatures. Again, the primary thermal conduction path is through the leads, so the circuit board
surface temperature will contribute to the die temperature much more than the air temperature.
To measure the temperature external to the die use a remote diode. This diode can be located on the die of the
target IC, such as a CPU processor chip, allowing measurement of the IC’s temperature, independent of the
LM64’s temperature. The LM64 has been optimized for use with a MMBT3904 diode-connected transistor.
A discrete diode can also be used to sense the temperature of external objects or ambient air. Remember that a
discrete diode’s temperature will be affected, and often dominated by, the temperature of its leads.
Most silicon diodes do not lend themselves well to this application. It is recommended that a diode-connected
MMBT3904 transistor be used. The base of the transistor is connected to the collector and becomes the anode.
The emitter is the cathode.
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Diode Non_Ideality
When a transistor is connected to a diode the following relationship holds for Vbe, T, and IF:
ª §¨¨ Vbe ·¸¸
K ˜V
I S ˜ «e © T ¹
«
¬
IF
º
1»
»
¼
(2)
where
V =
T
•
•
•
•
•
•
•
kT
q
q = 1.6x10−19 Coulombs (the electron charge)
T = Absolute Temperature in Kelvin
k = 1.38x10−23 joules/K (Boltzmann’s constant)
η is the non-ideality factor of the manufacturing process used to make the thermal diode
Is = Saturation Current and is process dependent
If = Forward Current through the base emitter junction
Vbe = Base Emitter Voltage Drop
(3)
In the active region, the −1 term is negligible and may be eliminated, yielding the following equation
IF
ª §¨¨ Vbe ·¸¸º
K ˜V
IS ˜ «e © T ¹»
»
«
¼
¬
(4)
In the above equation, η and Is are dependent upon the process that was used in the fabrication of the particular
diode. By forcing two currents with a very controlled ratio (N) and measuring the resulting voltage difference, it is
possible to eliminate the Is term. Solving for the forward voltage difference yields the relationship:
' Vbe
§ kT ·
¸ ˜ ln N
¨ q ¸
¹
©
K¨
(5)
The non-ideality factor, η, is the only other parameter not accounted for and depends on the diode that is used
for measurement. Since ΔVbe is proportional to both η and T, the variations in η cannot be distinguished from
variations in temperature. Since the temperature sensor does not control the non-ideality factor, it will directly add
to the inaccuracy of the sensor.
For example, if a processor manufacturer specifies a ±0.1% variation in η from part to part. As an example,
assume that a temperature sensor has an accuracy specification of ±1°C at room temperature of 25°C. The
resulting accuracy will be:
TACC = ±1°C + (±0.1% of 298°K) = ±1.3°C
The additional inaccuracy in the temperature measurement caused by η, can be eliminated if each temperature
sensor is calibrated with the remote diode that it will be paired with. Refer to the processor datasheet for the nonideality factor.
Compensating for Diode Non-Ideality
In order to compensate for the errors introduced by non-ideality, the temperature sensor is calibrated for a
particular processor. Texas Instruments temperature sensors are always calibrated to the typical non-ideality of a
particular processor type.
The LM64 is calibrated for a MMBT3904 diode-connected transistor.
When a temperature sensor, calibrated for a specific type of processor is used with a different processor type or
a given processor type has a non-ideality that strays form the typical value, errors are introduced.
30
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Temperature errors associated with non-ideality may be introduced in a specific temperature range of concern
through the use of the Temperature Offset Registers 11HEX and 12HEX.
The user is encouraged to send an e-mail to [email protected] to further request information
on our recommended setting of the offset register for different processor types.
COMPUTING RPM OF THE FAN FROM THE TACH COUNT
The Tach Count Registers 46HEX and 47HEX count the number of periods of the 90 kHz tachometer clock in the
LM64 for the tachometer input from the fan assuming a 2 pulse per revolution fan tachometer, such as the fans
supplied with the Pentium 4 boxed processors. The RPM of the fan can be computed from the Tach Count
Registers 46HEX and 47HEX. This can best be shown through an example.
Example:
Given: the fan used has a tachometer output with 2 per revolution.
Let:
Register 46 (LSB) is BFHEX = Decimal (11 x 16) + 15 = 191 and
Register 47 (MSB) is 7HEX = Decimal (7 x 256) = 1792.
The total Tach Count, in decimal, is 191 + 1792 = 1983.
The RPM is computed using the formula
f u 5, 400 , 000
Fan _ RPM =
,
Total _ Tach _ Count _( Decimal )
(6)
where
f = 1 for 2 pulses/rev fan tachometer output;
f = 2 for 1 pulse/rev fan tachometer output, and
f = 2 / 3 for 3 pulses/rev fan tachometer output
For our example
Fan _ RPM =
1 u 5, 400 , 000
= 2723 _ RPM
1983
(7)
PCB LAYOUT FOR MINIMIZING NOISE
Figure 12. Ideal Diode Trace Layout
In a noisy environment, such as a processor mother board, layout considerations are very critical. Noise induced
on traces running between the remote temperature diode sensor and the LM64 can cause temperature
conversion errors. Keep in mind that the signal level the LM64 is trying to measure is in microvolts. The following
guidelines should be followed:
1. Place a 0.1 µF power supply bypass capacitor as close as possible to the VDD pin and the recommended 2.2
nF capacitor as close as possible to the LM64's D+ and D− pins. Make sure the traces to the 2.2 nF
capacitor are matched.
2. Ideally, the LM64 should be placed within 10 cm of the Processor diode pins with the traces being as
straight, short and identical as possible. Trace resistance of 1 Ω can cause as much as 1°C of error. This
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3.
4.
5.
6.
7.
8.
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error can be compensated by using the Remote Temperature Offset Registers, since the value placed in
these registers will automatically be subtracted from or added to the remote temperature reading.
Diode traces should be surrounded by a GND guard ring to either side, above and below if possible. This
GND guard should not be between the D+ and D− lines. In the event that noise does couple to the diode
lines it would be ideal if it is coupled common mode. That is equally to the D+ and D− lines.
Avoid routing diode traces in close proximity to power supply switching or filtering inductors.
Avoid running diode traces close to or parallel to high speed digital and bus lines. Diode traces should be
kept at least 2 cm apart from the high speed digital traces.
If it is necessary to cross high speed digital traces, the diode traces and the high speed digital traces should
cross at a 90 degree angle.
The ideal place to connect the LM64's GND pin is as close as possible to the Processor's GND associated
with the sense diode.
Leakage current between D+ and GND should be kept to a minimum. One nano-ampere of leakage can
cause as much as 1°C of error in the diode temperature reading. Keeping the printed circuit board as clean
as possible will minimize leakage current.
Noise coupling into the digital lines greater than 400 mVp-p (typical hysteresis) and undershoot less than 500 mV
below GND, may prevent successful SMBus communication with the LM64. SMBus no acknowledge is the most
common symptom, causing unnecessary traffic on the bus. Although the SMBus maximum frequency of
communication is rather low (100 kHz max), care still needs to be taken to ensure proper termination within a
system with multiple parts on the bus and long printed circuit board traces. An RC lowpass filter with a 3 dB
corner frequency of about 40 MHz is included on the LM64's SMBCLK input. Additional resistance can be added
in series with the SMBData and SMBCLK lines to further help filter noise and ringing. Minimize noise coupling by
keeping digital traces out of switching power supply areas as well as ensuring that digital lines containing high
speed data communications cross at right angles to the SMBData and SMBCLK lines.
32
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REVISION HISTORY
Changes from Original (March 2013) to Revision A
•
Page
Changed layout of National Data Sheet to TI format .......................................................................................................... 32
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PACKAGE OPTION ADDENDUM
www.ti.com
7-Oct-2013
PACKAGING INFORMATION
Orderable Device
Status
(1)
LM64CILQ-F/NOPB
ACTIVE
Package Type Package Pins Package
Drawing
Qty
WQFN
NHW
24
1000
Eco Plan
Lead/Ball Finish
(2)
Green (RoHS
& no Sb/Br)
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
CU SN
Level-3-260C-168 HR
(4/5)
0 to 125
64CILQF
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
Samples
PACKAGE MATERIALS INFORMATION
www.ti.com
23-Sep-2013
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
LM64CILQ-F/NOPB
Package Package Pins
Type Drawing
WQFN
NHW
24
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
1000
178.0
12.4
Pack Materials-Page 1
4.3
B0
(mm)
K0
(mm)
P1
(mm)
5.3
1.3
8.0
W
Pin1
(mm) Quadrant
12.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
23-Sep-2013
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
LM64CILQ-F/NOPB
WQFN
NHW
24
1000
213.0
191.0
55.0
Pack Materials-Page 2
MECHANICAL DATA
NHW0024B
LQA24A (Rev B)
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