NSC LM76 ±0.5â°c, â±1â°c, 12-bit sign digital temperature sensor and thermal window comparator with two-wire interface Datasheet

LM76
± 0.5˚C, ± 1˚C, 12-Bit + Sign Digital Temperature Sensor
and Thermal Window Comparator with Two-Wire
Interface
General Description
Features
The LM76 is a digital temperature sensor and thermal window comparator with an I2C™ Serial Bus interface with an
accuracy of ± 1˚C. This accuracy for the LM76CHM is specified for a −10˚C to 45˚C temperature range, while for the
LM76CNM the temperature range is 70˚C to 100˚C. The
LM76CHM is specified with an accuracy ± 0.5˚C at 25˚C. The
window-comparator architecture of the LM76 eases the design of temperature control systems conforming to the ACPI
(Advanced Configuration and Power Interface) specification
for personal computers. The open-drain Interrupt (INT) output becomes active whenever temperature goes outside a
programmable window, while a separate Critical Temperature Alarm (T_CRIT_A) output becomes active when the
temperature exceeds a programmable critical limit. The INT
output can operate in either a comparator or event mode,
while the T_CRIT_A output operates in comparator mode
only.
The host can program both the upper and lower limits of the
window as well as the critical temperature limit. Programmable hysterisis as well as a fault queue are available to
minimize false tripping. Two pins (A0, A1) are available for
address selection. The sensor powers up with default thresholds of 2˚C THYST, 10˚C TLOW, 64˚C THIGH, and 80˚C
T_CRIT.
The LM76’s 3.3V and 5.0V supply voltage, Serial Bus interface, 12-bit + sign output, and full-scale range of over 127˚C
make it ideal for a wide range of applications. These include
thermal management and protection applications in personal
computers, electronic test equipment, office electronics and
bio-medical applications.
n Window comparison simplifies design of ACPI
compatible temperature monitoring and control.
n Serial Bus interface
n Separate open-drain outputs for Interrupt and Critical
Temperature shutdown
n Shutdown mode to minimize power consumption
n Up to 4 LM76s can be connected to a single bus
n 12-bit + sign output; full-scale reading of over 127˚C
Key Specifications
n Supply Voltage
n Supply Current
3.3V or 5.0V
operating
250 µA (typ)
450 µA (max)
n Temperature
Accuracy
shutdown
8 µA (max)
+25˚C
−10˚C to +45˚C
± 0.5˚C(max)
± 1.0˚C(max)
± 1.0˚C(max)
70˚C to 100˚C
n Resolution
0.0625˚C
Applications
n
n
n
n
System Thermal Management
Personal Computers
Office Electronics
HVAC
I2C ® is a registered trademark of Philips Corporation.
© 2000 National Semiconductor Corporation
DS101015
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LM76 ± 0.5˚C, ± 1˚C, 12-Bit + Sign Digital Temperature Sensor and Thermal Window Comparator
with Two-Wire Interface
January 2000
LM76
Simplified Block Diagram
DS101015-1
Connection Diagram
SO-8
DS101015-2
LM76 See NS Package Number M08A
Ordering Information
Order Number
Supply Voltage
Acurracy
LM76CHM-5
5.0V
LM76CHMX-5
5.0V
± 0.5˚C
± 1.0˚C
± 0.5˚C
± 1.0˚C
± 1˚C
± 1˚C
LM76CNM-3
3.3V
LM76CNMX-3
3.3V
Temperature
Range for
Accuracy
Transport Media
25˚C
−10˚C to 45˚C
95 units in Rail
25˚C
−10˚C to 45˚C
2500 Units on Tape and
Reel
70˚C to 100˚C
95 units in Rail
70˚C to 100˚C
2500 Units on Tape and
Reel
Pin Description
Label
SDA
Pin #
Function
Typical Connection
1
Serial Bi-Directional Data Line, Open Drain Output,
CMOS Logic Level
Pull Up Resistor, Controller I2C Data Line
SCL
2
Serial Bus Clock Input, CMOS Logic Level
From Controller I2C Clock Line
T_CRIT_A
3
Critical Temperature Alarm, Open Drain Output
Pull Up Resistor, Controller Interrupt Line
or System Hardware Shutdown
GND
4
Power Supply Ground
Ground
INT
5
Interrupt, Open Drain Output
Pull Up Resistor, Controller Interrupt Line
+VS
8
Positive Supply Voltage Input
DC Voltage from 3.3V power supply or
5V.
User-Set Address Inputs, TTL Logic Level
Ground (Low, “0”) or +VS (High, “1”)
A0–A1
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7,6
2
LM76
Pin Description
(Continued)
DS101015-3
FIGURE 1. Typical Application
3
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LM76
Absolute Maximum Ratings (Note 1)
Supply Voltage
Voltage at any Pin
Input Current at any Pin
Package Input Current (Note 2)
T_CRIT_A and INT Output Sink
Current
T_CRIT_A and INT Output
Voltage
Storage Temperature
Soldering Information, Lead
Temperature
SOP Package (Note 3)
Vapor Phase (60 seconds)
Infrared (15 seconds)
ESD Susceptibility (Note 4)
Human Body Model
Machine Model
−0.3V to 6.5V
−0.3V to (+VS + 0.3V)
5mA
20mA
10mA
6.5V
−65˚C to +125˚C
215˚C
220˚C
3000V
250V
Operating Ratings(Notes 1, 5)
Operating Temperature Range
Specified Temperature Range
(Note 6)
LM76CHM-5
LM76CNM-3
Supply Voltage Range (+VS)(Note 7)
−55˚C to +150˚C
TMIN to TMAX
−20˚C to +85˚C
−55˚C to +125˚C
+3.0V to +5.5V
Temperature-to-Digital Converter Characteristics
Unless otherwise noted, these specifications apply for +VS = +3.3 Vdc ± 5% for the LM76CNM-3 and for +VS = +5.0 Vdc ± 10%
for the LM76CHM-5. (Note 7). Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = +25˚C, unless otherwise noted.
Parameter
Accuracy (Note 7)
Typical
(Note 8)
Conditions
LM76CNM-3
Limits
(Note 9)
LM76CHM-5
Limits
(Note 9)
Units
(Limit)
± 2.5
TA = −25˚C to +125˚C for
LM76CNM-3
TA = +70˚C to +100˚C
TA = −20˚C to +85˚C for
LM76CHM-5
TA = −10˚C to +45˚C
± 1.0
± 1.5
˚C (max)
± 1.0
± 0.5
TA = +25˚C
Resolution
(Note 10)
13
0.0625
Temperature Conversion
Time
(Note 11)
400
Quiescent Current
I2C Inactive
0.25
I2C Active
0.25
Shutdown Mode:
Bits
˚C
500
1000
ms
0.5
0.45
mA (max)
12
18
µA (max)
mA
5
TA = +85˚C
TA = +25˚C
µA
8
µA (max)
12
µA (max)
THYST Default Temperature
(Notes 13, 14)
2
˚C
TLOW Default Temperature
(Note 14)
10
˚C
THIGH Default Temperature
(Note 14)
64
˚C
TCRIT Default Temperature
(Note 14)
80
˚C
Logic Electrical Characteristics
DIGITAL DC CHARACTERISTICS Unless otherwise noted, these specifications apply for for +VS = +3.3 Vdc ± 5% for the
LM76CNM-3 and for +VS = +5.0 Vdc ± 10% for the LM76CHM-5. . Boldface limits apply for TA = TJ = TMIN to TMAX; all
other limits TA = TJ = +25˚C, unless otherwise noted.
Symbol
VIN(1)
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Parameter
Conditions
SDA and SCL Logical “1” Input
Voltage
4
Typical
(Note 8)
Limits
(Note 9)
Units
(Limit)
+VS x 0.7
V (min)
+VS+0.3
V (max)
LM76
Logic Electrical Characteristics
(Continued)
DIGITAL DC CHARACTERISTICS Unless otherwise noted, these specifications apply for for +VS = +3.3 Vdc ± 5% for the
LM76CNM-3 and for +VS = +5.0 Vdc ± 10% for the LM76CHM-5. . Boldface limits apply for TA = TJ = TMIN to TMAX; all
other limits TA = TJ = +25˚C, unless otherwise noted.
Symbol
VIN(0)
VIN(HYST)
Parameter
Typical
(Note 8)
SDA and SCL Logical “0” Input
Voltage
SDA and SCL Digital Input
Hysteresis
VIN(1)
A0 and A1 Logical “1” Input
Voltage
VIN(0)
A0 and A1 Logical “0” Input
Voltage
IIN(1)
Logical “1” Input Current
IIN(0)
Logical “0” Input Current
CIN
Capacitance of All Digital Inputs
IOH
High Level Output Current
VOL
Conditions
500
VIN = + VS
VIN = 0V
Limits
(Note 9)
Units
(Limit)
−0.3
V (min)
+VS x 0.3
V (max)
250
mV (min)
2.0
V (min)
+VS+0.3
V (max)
−0.3
V (min)
0.8
V (max)
0.005
1.0
µA (max)
−0.005
−1.0
µA (max)
10
µA (max)
20
Low Level Output Voltage
VOH = + VS
IOL = 3 mA
T_CRIT_A Output Saturation
Voltage
IOUT = 4.0 mA
(Note 12)
pF
0.4
V (max)
0.8
V (max)
1
Conversions
(max)
250
ns (max)
T_CRIT_A Delay
tOF
CL = 400 pF
IO = 3 mA
Output Fall Time
SERIAL BUS DIGITAL SWITCHING CHARACTERISTICS Unless otherwise noted, these specifications apply for +VS = +3.3
Vdc ± 5% for the LM76CNM-3 and for +VS = +5.0 Vdc ± 10% for the LM76CHM-5, CL (load capacitance) on output lines = 80
pF unless otherwise specified. Boldface limits apply for TA = TJ = TMIN to TMAX; all other limits TA = TJ = +25˚C, unless otherwise noted.
The switching characteristics of the LM76 fully meet or exceed the published specifications of the I2C bus. The following parameters are the timing relationship between SCL and SDA signal related to the LM76. They are not the I2C bus specifications.
Symbol
Parameter
Conditions
Typical
(Note 8)
Limits
(Note 9)
Units
(Limit)
µs(min)
t1
SCL (Clock) Period
2.5
t2
Data in Set-Up Time to SCL High
100
ns(min)
t3
Data Out Stable after SCL Low
0
ns(min)
t4
SDA Low Set-Up Time to SCL Low (Start Condition)
100
ns(min)
t5
SDA High Hold Time after SCL High (Stop Condition)
100
ns(min)
DS101015-4
5
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LM76
Logic Electrical Characteristics
(Continued)
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. DC and AC electrical specifications do not apply when operating
the device beyond its rated operating conditions.
Note 2: When the input voltage (VI) at any pin exceeds the power supplies (VI < GND or VI > +VS) the current at that pin should be limited to 5 mA. The 20 mA
maximum package input current rating limits the number of pins that can safely exceed the power supplies with an input current of 5 mA to four.
Note 3: See AN-450 “Surface Mounting Methods and Their Effect on Product Reliability” or the section titled “Surface Mount” found in a current National Semiconductor Linear Data Book for other methods of soldering surface mount devices.
Note 4: Human body model, 100 pF discharged through a 1.5 kΩ resistor. Machine model, 200 pF discharged directly into each pin.
Note 5: LM76 θJA (thermal resistance, junction-to-ambient) when attached to a printed circuit board with 2 oz. foil is 200˚C/W.
Note 6: While the LM76 has a full-scale-range in excess of 128˚C, prolonged operation at temperatures above 125˚C is not recommended.
Note 7: The LM76 will operate properly over the +VS supply voltage range of 3V to 5.5V for the LM76CNM-3 and the LM76CHM-5. The LM76CNM-3 is tested and
specified for rated accuracy at the nominal supply voltage of 3.3V. Accuracy of the LM76CNM-3 will degrade 0.2˚C for a ± 1% variation in +VS from the nominal value.
The LM76CHM-5 is tested and specified for a rated accuracy at the nominal supply voltage of 5.0V. Accuracy of the LM76CHM-5 will degrade 0.08˚C for a ± 1%
variation in +VS from the nominal value.
Note 8: Typicals are at TA = 25˚C and represent most likely parametric norm.
Note 9: Limits are guaranteed to National’s AOQL (Average Outgoing Quality Level).
Note 10: 12 bits + sign, two’s complement
Note 11: This specification is provided only to indicate how often temperature data is updated. The LM76 can be read at any time without regard to conversion state
(and will yield last conversion result). If a conversion is in process it will be interrupted and restarted after the end of the read.
Note 12: For best accuracy, minimize output loading. Higher sink currents can affect sensor accuracy with internal heating. This can cause an error of 0.64˚C at full
rated sink current and saturation voltage based on junction-to-ambient thermal resistance.
Note 13: Hysteresis value adds to the TLOW setpoint value (e.g.: if TLOW setpoint = 10˚C, and hysteresis = 2˚C, then actual hysteresis point is 10+2 = 12˚C); and
subtracts from the THIGH and T_CRIT setpoints (e.g.: if THIGH setpoint = 64˚C, and hysteresis = 2˚C, then actual hysteresis point is 64−2 = 62˚C). For a detailed
discussion of the function of hysteresis refer to Section 1.1, TEMPERATURE COMPARISON, and Figure 3.
Note 14: Default values set at power up.
Electrical Characteristics
Continued
DS101015-5
FIGURE 2. Temperature-to-Digital Transfer Function (Non-linear scale for clarity)
1.0 Functional Description
1.1 TEMPERATURE COMPARISON
The LM76 temperature sensor incorporates a band-gap type
temperature sensor, 13-bit ADC, and a digital comparator
with user-programmable upper and lower limit values. The
comparator activates either the INT line for temperatures
outside the TLOW and THIGH window, or the T_CRIT_A line
for temperatures which exceed T_CRIT. The lines are programmable for mode and polarity.
LM76 provides a window comparison against a lower (TLOW)
and upper (THIGH) trip point. A second upper trip point
(T_CRIT) functions as a critical alarm shutdown. Figure 3
depicts the comparison function as well as the modes of operation.
1.1.1 STATUS BITS
The internal Status bits operate as follows:
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6
Avoid programming setpoints so close that their hysteresis
values overlap. An example would be that with a THYST value
of 2˚C then setting THIGH and TLOW to within 4˚C of each
other will violate this restriction. To be more specific, with
THYST set to 2˚C assume THIGH set to 64˚C. If TLOW is set
equal to, or higher than 60˚C this restriction is violated.
(Continued)
“True”: Temperature above a THIGH or T_CRIT is “true” for
those respective bits. A “true” for TLOW is temperature below
TLOW.
“False”: Assuming temperature has previously crossed
above THIGH or T_CRIT, then the temperature must drop below the points corresponding THYST (THIGH − THYST or
T_CRIT − THYST) in order for the condition to be false. For
TLOW, assuming temperature has previously crossed below
TLOW, a “false” occurs when temperature goes above TLOW
+ THYST.
The Status bits are not affected by reads or any other actions, and always represent the state of temperature vs. setpoints.
1.2 DEFAULT SETTINGS
The LM76 always powers up in a known state. LM76 power
up default conditions are:
1.
2.
Comparator Interrupt Mode
TLOW set to 10˚C
3. THIGH set to 64˚C
4. T_CRIT set to 80˚C
5. THYST set to 2˚C
6. INT and T_CRIT_A active low
1.1.2 HARDWIRE OUTPUTS
The T_CRIT_A hardwire output mirrors the T_CRIT_A flag,
when the flag is true, the T_CRIT_A output is asserted at all
times regardless of mode. Reading the LM76 has no effect
on the T_CRIT_A output, although the internal conversion is
restarted.
The behavior of the INT hardwire output is as follows:
Comparator Interrupt Mode (Default): User reading part
resets output until next measurement completes. If condition
is still true, output is set again at end of next conversion
cycle. For example, if a user never reads the part, and temperature goes below TLOW then INT becomes active. It
would stay that way until temperature goes above TLOW +
THYST. However if the user reads the part, the output would
be reset. At the end of the next conversion cycle, if the condition is true, it is set again. If not, it remains reset.
Event Interrupt Mode: User reading part resets output until next condition ″event″ occurs (in other words, output is
only set once for a true condition, if reset by a read, it remains reset until the next triggering threshold has been
crossed). Conversely, if a user never read the part, the output would stay set indefinitely after the first event that set the
output. An “event” for Event Interrupt Mode is defined as:
1. Transitioning upward across a setpoint, or
2. Transitioning downward across a setpoint’s corresponding hysteresis (after having exceeded that setpoint).
For example, if a user never read the part, and temperature
went below TLOW then INT would become active. It would
stay that way forever if a user never read the part.
However if the user read the part, the output would be reset.
Even if the condition is true, it will remain reset. The temperature must cross above TLOW + THYST to set the output
again.
In either mode, reading any register in the LM76 restarts the
conversion. This allows a designer to know exactly when the
LM76 begins a comparison. This prevents unnecessary Interrupts just after reprogramming setpoints. Typically, system Interrupt inputs are masked prior to reprogramming trip
points. By doing a read just after resetting trip points, but
prior to unmasking, unexpected Interrupts are prevented.
7. Pointer set to “00”; Temperature Register
The LM76 registers will always reset to these default values
when the power supply voltage is brought up from zero volts
as the supply crosses the voltage level plotted in the following curve. The LM76 registers will reset again when the
power supply drops below the voltage plotted in this curve.
Average Power on Reset Voltage
vs Temperature
DS101015-18
1.3 SERIAL BUS INTERFACE
The LM76 operates as a slave on the Serial Bus, so the SCL
line is an input (no clock is generated by the LM76) and the
SDA line is a bi-directional serial data line. According to Serial Bus specifications, the LM76 has a 7-bit slave address.
The five most significant bits of the slave address are hard
wired inside the LM76 and are “10010”. The two least significant bits of the address are assigned to pins A1–A0, and are
set by connecting these pins to ground for a low, (0); or to
+VS for a high, (1).
Therefore, the complete slave address is:
1
MSB
7
0
0
1
0
A1
A0
LSB
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LM76
1.0 Functional Description
LM76
1.0 Functional Description
(Continued)
DS101015-6
Note: Event Interrupt mode is drawn as if the user is reading the part. If the user doesn’t read, the outputs would go low and stay that way until the LM76 is read.
FIGURE 3. Temperature Response Diagram
1.5 SHUTDOWN MODE
Shutdown mode is enabled by setting the shutdown bit in the
Configuration register via the Serial Bus. Shutdown mode reduces power supply current to 5 µA typical. T_CRIT_A is reset if previously set. Since conversions are stoped during
shutdown, T_CRIT_A and INT will not be operational. The
Serial Bus interface remains active. Activity on the clock and
data lines of the Serial Bus may slightly increase shutdown
mode quiescent current. Registers can be read from and
written to in shutdown mode. The LM76 takes miliseconds to
respond to the shutdown command.
1.4 TEMPERATURE DATA FORMAT
Temperature data can be read from the Temperature and Set
Point registers; and written to the Set Point registers. Temperature data can be read at any time, although reading
faster than the conversion time of the LM76 will prevent data
from being updated. Temperature data is represented by a
13-bit, two’s complement word with an LSB (Least Significant Bit) equal to 0.0625˚C:
Temperature
Digital Output
Binary
Hex
+130˚C
0 1000 0 010 0000
08 20h
+125˚C
0 0111 1101 0000
07 D0h
+80˚C
0 0101 1010 0000
05 90h
+64˚C
0 0100 0000 0000
04 00h
+25˚C
0 0001 1001 0000
01 90h
+10˚C
0 0000 1010 0000
00 A0h
+2˚C
0 0000 0010 0000
00 20h
+0.0625˚C
0 0000 0000 0001
00 01h
0˚C
00 0000 0000
00 00h
−0.0625˚C
1 1111 1111 1111
1F FFh
−25˚C
1 1110 0111 0000
1E 70h
−55˚C
1 1100 1001 0000
1C 90h
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1.6 INT AND T_CRIT_A OUTPUT
The INT and T_CRIT_A outputs are open-drain outputs and
do not have internal pull-ups. A ″high″ level will not be observed on these pins until pull-up current is provided from
some external source, typically a pull-up resistor. Choice of
resistor value depends on many system factors but, in general, the pull-up resistor should be as large as possible. This
will minimize any errors due to internal heating of the LM76.
The maximum resistance of the pull up, based on LM76
specification for High Level Output Current, to provide a 2
volt high level, is 30K ohms.
1.7 FAULT QUEUE
A fault queue of up to 4 faults is provided to prevent false
tripping when the LM76 is used in noisy environments. The 4
faults must occur consecutively to set flags as well as INT
8
LM76
1.0 Functional Description
(Continued)
and T_CRIT_A outputs. The fault queue is enabled by setting bit 4 of the Configuration Register high (see Section
1.11).
1.8 INTERNAL REGISTER STRUCTURE
DS101015-7
followed by retrieving the corresponding number of data
bytes. If the Pointer needs to be set, then an address byte,
pointer byte, repeat start, and another address byte plus required number of data bytes will accomplish a read.
The first data byte is the most significant byte with most significant bit first, permitting only as much data as necessary to
be read to determine the temperature condition. For instance, if the first four bits of the temperature data indicates
a critical condition, the host processor could immediately
take action to remedy the excessive temperature. At the end
of a read, the LM76 can accept either Acknowledge or No
Acknowledge from the Master (No Acknowledge is typically
used as a signal for the slave that the Master has read its
last byte).
There are four data registers in the LM76, selected by the
Pointer register. At power-up the Pointer is set to “00”; the location for the Temperature Register. The Pointer register
latches the last location it was set to. In Interrupt Mode, a
read from the LM76 resets the INT output. Placing the device
in Shutdown mode resets the INT and T_CRIT_A outputs. All
registers are read and write, except the Temperature register
which is read only.
A write to the LM76 will always include the address byte and
the Pointer byte. A write to the Configuration register requires one data byte, while the TLOW, THIGH, and T_CRIT
registers require two data bytes.
Reading the LM76 can take place either of two ways: If the
location latched in the Pointer is correct (most of the time it is
expected that the Pointer will point to the Temperature register because it will be the data most frequently read from the
LM76), then the read can simply consist of an address byte,
An inadvertent 8-bit read from a 16-bit register, with the D7
bit low, can cause the LM76 to stop in a state where the SDA
line is held low as shown in Figure 4. This can prevent any
further bus communication until at least 9 additional clock
cycles have occurred. Alternatively, the master can issue
clock cycles until SDA goes high, at which time issuing a
“Stop” condition will reset the LM76.
DS101015-8
FIGURE 4. Inadvertent 8-Bit Read from 16-Bit Register where D7 is Zero (“0”)
9
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LM76
1.0 Functional Description
(Continued)
1.9 POINTER REGISTER
(Selects which registers will be read from or written to):
P7
P6
P5
P4
P3
0
0
0
0
0
P2
P1
P0
Register Select
P0–P2: Register Select:
P2
P1
P0
0
0
0
Temperature (Read only) (Power-up
default)
Register
0
0
1
Configuration (Read/Write)
0
1
0
THYST (Read/Write)
0
1
1
T_CRIT (Read/Write)
1
0
0
TLOW (Read/Write)
1
0
1
THIGH (Read/Write)
P3–P7: Must be kept zero.
1.10 TEMPERATURE REGISTER
(Read Only):
D15
D14
D13
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Sign
MSB
Bit
10
Bit 9
Bit 8
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
CRIT
HIGH
LOW
Status Bits
D0–D2: Status Bits
D3–D15: Temperature Data. One LSB = 0.0625˚C. Two’s complement format.
1.11 CONFIGURATION REGISTER
(Read/Write):
D7
D6
D5
D4
D3
D2
D1
D0
0
0
0
Fault Queue
INT Polarity
T_CRIT_A
Polarity
INT Mode
Shutdown
D0: Shutdown - When set to 1 the LM76 goes to low power shutdown mode. Power up default of “0”.
D1: Interrupt mode - 0 is Comparator Interrupt mode, 1 is Event Interrupt mode. Power up default of “0”.
D2, D3: T_CRIT_A and INT Polarity - 0 is active low, 1 is active high. Outputs are open-drain. Power up default of “0”
D4: Fault Queue - When set to 1 the Fault Queu is enabled,
see Section 1.7. Power up default of “0”.
D5–D7: These bits are used for production testing and must be kept zero for normal operation.
1.12 THYST, TLOW, THIGH AND T_CRIT_A REGISTERS
(Read/Write):
D15
D14
D13
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
Sign
MSB
Bit
10
Bit 9
Bit 8
Bit7
Bit6
Bit5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
X
X
X
D0–D2: Undefined
D3–D15: THYST, TLOW, THIGH or T_CRIT Trip Temperature Data. Power up default is TLOW = 10˚C, THIGH = 64˚C, T_CRIT = 80˚C,
THYST = 2˚C.
THYST is subtracted from THIGH, and T_CRIT, and added to TLOW.
Avoid programming setpoints so close that their hysteresis values overlap. See Section 1.1.
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LM76
2.0 I2C Timing Diagrams
DS101015-9
Typical 2-Byte Read From Preset Pointer Location Such as Temp or Comparison Registers
DS101015-10
Typical Pointer Set Followed by Immediate Read for 2-Byte Register such as Temp or Comparison Registers
DS101015-11
Typical 1-Byte Read from Configuration Register with Preset Pointer
DS101015-12
Typical Pointer Set Followed by Immediate Read from Configuration Register
DS101015-13
Configuration Register Write
DS101015-14
Comparison Register Write
FIGURE 6. Timing Diagrams
11
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LM76
To implement ACPI compatible sensing it is necessary to
sense whenever the temperature goes outside the window,
issue an interrupt, service the interrupt, and reprogram the
window according to the desired granularity of the temperature scale. The reprogrammed window will now have the current temperature inside it, ready to issue an interrupt whenever the temperature deviates from the current window.
To understand this graph, assume that at the left hand side
the system is at some nominal temperature. For the 1st
event temperature rises above the upper window limit,
THIGH, causing INT to go active. The system responds to the
interrupt by querying the LM76’s status bits and determines
that THIGH was exceeded, indicating that temperature is rising. The system then reprograms the temperature limits to a
value higher by an amount equal to the desired granularity.
Note that in Event Interrupt Mode, reprogramming the limits
has caused a second, known, interrupt to be issued since
temperature has been returned within the window. In Comparator Interrupt Mode, the LM76 simply stops issuing interrupts.
The 2nd event is another identical rise in temperature. The
3rd event is typical of a drop in temperature. This is one of
the conditions that demonstrates the power of the LM76, as
the user receives notification that a lower limit is exceeded in
such a way that temperature is dropping.
The Critical Alarm Event activates the separate T_CRIT_A
output. Typically, this would feed circuitry separate from the
processor on the assumption that if the system reached this
temperature, the processor might not be responding.
3.0 Application Hints
The temperature response graph in Figure 7 depicts a typical application designed to meet ACPI requirements. In this
type of application, the temperature scale is given an arbitrary value of ″granularity″, or the window within which temperature notification events should occur. The LM76 can be
programmed to the window size chosen by the designer, and
will issue interrupts to the processor whenever the window
limits have been crossed. The internal flags permit quick determination of whether the temperature is rising or falling.
The T_CRIT limit would typically use its separate output to
activate hardware shutdown circuitry separate from the processor. This is done because it is expected that if temperature has gotten this high that the processor may not be responding. The separate circuitry can then shut down the
system, usually by shutting down the power supply.
Note that the INT and T_CRIT_A outputs are separate, but
can be wire-or’d together. Alternatively the T_CRIT_A can be
diode or’d to the INT line in such a way that a T_CRIT_A
event activates the INT line, but an INT event does not activate the T_CRIT_A line. This may be useful in the event that
it is desirable to notify both the processor and separate
T_CRIT_A shutdown circuitry of a critical temperature alarm
at the same time (maybe the processor is still working and
can coordinate a graceful shutdown with the separate shutdown circuit).
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12
LM76
3.0 Application Hints
(Continued)
DS101015-15
Note: Event Interrupt mode is drawn as if the user is reading the part. If the user doesn’t read, the outputs would go low and stay that way until the LM76 is read.
FIGURE 7. Temperature Response Diagram for ACPI Implementation
4.0 Typical Applications
DS101015-16
FIGURE 8. Typical Application
13
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LM76
4.0 Typical Applications
(Continued)
DS101015-19
FIGURE 9. ACPI Compatible Terminal Alarm Shutdown. By powering the LM76 from auxilary output of the power
supply, a non-functioning overheated computer can be powered down to preserve as much of the system as
possible.
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14
inches (millimeters) unless otherwise noted
8-Lead (0.150" Wide) Molded Small Outline Package (SOP), JEDEC
Order Number LM76CNM-3, LM76CNMX-3, LM76CHM-5 or LM76CHM-5X
NS Package Number M08A
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LM76 ± 0.5˚C, ± 1˚C, 12-Bit + Sign Digital Temperature Sensor and Thermal Window Comparator
with Two-Wire Interface
Physical Dimensions
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