MAX1617D.pdf

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The MAX1617 is a serially programmable temperature sensor
optimized for monitoring modern high performance CPUs with
on–board, integrated temperature sensing diodes. Temperature data is
converted from the CPU’s diode outputs and made available as an
8–bit digital word.
Communication with the MAX1617 is accomplished via the
standard System Management Bus (SMBus) commonly used in
modern computer systems. This permits reading the current
internal/external temperature, programming the threshold setpoints,
and configuring the device. Additionally, an interrupt is generated on
the ALERT pin when temperature moves outside the preset threshold
windows in either direction.
A Standby command may be sent via the SMBus by signaling the
STBY input to activate the low–power Standby mode. Registers can
be accessed while in Standby mode. Address selection inputs allow up
to nine MAX1617s to share the same 2–wire SMBus for multi–zone
monitoring.
All registers can be read by the host, and both polled and interrupt
driven systems are easily accommodated. Small size, low installed
cost, and ease of use make the MAX1617 an ideal choice for
implementing sophisticated system management schemes, such as
ACPI.
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16–Pin QSOP
DB SUFFIX
CASE TBD
PRELIMINARY INFORMATION
PIN CONFIGURATION
(Top View)
NC
V DD
D +
D
1
2
3
4
16
15
14
13
NC
STBY
SCL
NC
MAX1617
NC
ADD1
GND
GND
5
6
7
8
12
11
10
9
SDA
ALERT
ADD0
NC
Features
Includes Internal and External Sensing Capability
Outputs Temperature As 8–Bit Digital Word
Solid State Temperature Sensing; 1
°
C Resolution
3.0 — 5.5V Operating Range
Independent Internal and External Threshold Set–Points With
ALERT Interrupt Output
SMBus 2–Wire Serial Interface
Up To 9 MAX1617s May Share the Same Bus
ORDERING INFORMATION
Low Standby Power Mode
Low Power: 70
m
A (max) Operating, 10
m
A (max) Standby Mode
Device
Package
Shipping
16–Pin Plastic QSOP Package
MAX1617DBR2 16–Pin QSOP 2500 Tape/Reel
Operating Temperature Range: –55
°
C to +125
°
C
Typical Applications
and Other
High Performance CPUs with Integrated On–Board Diode - No
Sensor Mounting Problems!
E
Accurate Temperature Sensing From Any Silicon Junction Diode
Thermal Management in Electronic Systems: Computers, Network
Equipment, Power Supplies
Semiconductor Components Industries, LLC, 1999
February, 2000 – Rev. 0
1
Publication Order Number:
MAX1617/D
Thermal Protection For Intel “Deschutes” Pentium II
W
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MAX1617
FUNCTIONAL BLOCK DIAGRAM
Internal
Sensor
(Diode)
D +
D
Modulator
Control
Logic
ALERT
STBY
Register Set
Int. Temp
Ext.Temp
Status Byte
Config. Byte
Conv. Rate
Ext. Hi Limit
Ext. Lo Limit
Int. Hi Limit
Int. Lo Limit
SCL
SDA
SMBus
Interface
ADD 0
ADD 1
ABSOLUTE MAXIMUM RATINGS*
Symbol
Parameter
Value
Unit
V DD
Power Supply Voltage
6.0
V
Voltage on Any Pin
(GND – 0.3 V) to (V DD + 0.3 V)
V
T A
Operating Temperature Range
–55 to +125
°
C
T stg
Storage Temperature Range
–65 to +150
°
C
SMBus Input/Output Current
–1 to +50
mA
D Input Current
± 1
mA
P D
Maximum Power Dissipation
330
mW
* Maximum Ratings are those values beyond which damage to the device may occur.
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MAX1617
PIN DESCRIPTION
Pin No.
Symbol
Type
Description
2
V DD ÁÁÁÁÁ
Power ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
Power Supply Input
3
D + ÁÁÁÁÁ
Bi–Directional ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
Current Source and A/D Positive Input
4
D ÁÁÁÁÁ
Bi–Directional ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
Current Sink and A/D Negative Input
6, 10 ÁÁÁÁ
ADD[1:0] ÁÁÁÁÁ
Input ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
Address Select Pins (See Address Decode Table)
7, 8 ÁÁÁÁ
GND ÁÁÁÁÁ
Power ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
System Ground
11 ÁÁÁÁ
ALERT ÁÁÁÁÁ
Output ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
SMBus Interrupt (SMBALERT) or Comparator Output
12 ÁÁÁÁ
SDA ÁÁÁÁÁ
Bi–Directional ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
SMBus Serial Data
14 ÁÁÁÁ
SCL ÁÁÁÁÁ
Input ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
SMBus Serial Clock
15 ÁÁÁÁ
STBY ÁÁÁÁÁ
Input ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
Standby Enable
1, 5, 9, 13, 16 ÁÁÁÁ
NC ÁÁÁÁÁ
ÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁÁ
Not Connected
PIN DESCRIPTION
SCL
Input. SMBus serial clock. Clocks data into and out of the
MAX1617.
( NOTE: A pull–up resistor is necessary on ALERT since
it is an open–drain output. Current sourced from the pull–up
resistor causes power dissipation and may cause internal
heating of the MAX1617. To avoid affecting the accuracy of
internal temperature readings, the pull–up resistors should
be made as large as possible.)
SDA
Bi–directional. Serial data is transferred on the SMBus in
both directions using this pin.
STBY
Input. The activation of Standby mode may be achieved
using either the STBY pin or the CHIP STOP bit (CONFIG
register). If STBY is pulled low, the MAX1617
unconditionally enters its low–power Standby mode. The
temperature–to–digital conversion process is halted, but
ALERT remains functional. The MAX1617’s bus interface
remains active, and all registers may be read from and
written to normally. The INT_TEMP and EXT_TEMP
registers will contain whatever data was valid at the time of
Standby. (Transitions on SDA or SCL due to external bus
activity may increase the Standby power consumption.)
D +
Bi–directional. this pin connects to the anode of the
external diode and is the positive A/D input. Current is
injected into the external diode from the MAX1617, and the
temperature proportional V BE is measured and converted to
digital temperature data.
D
Bi–directional. This pin connects to the cathode of the
external diode. Current is sunk from the external diode into
the MAX1617 through this pin. It also is the negative input
terminal to the MAX1617’s A/D converter. This node is kept
at approximately 0.7V above GROUND.
ADD1, ADD0
Inputs. Sets the 7–bit SMBus address. These pins are
“tri–state,” and the SMBus addresses are specified in the
Address Decode Table below.
( NOTE: The tri–state scheme allows up to nine
MAX1617s on a single bus. A match between the
MAX1617’s address and the address specified in the serial
bit stream must be made to initiate communication. Many
SMBus–compatible devices with other addresses may share
the same 2–wire bus. These pins are only active at power–on
reset, and will latch into the appropriate states.
ALERT
Output, Open Collector, Active Low. The ALERT output
corresponds to the general SMBALERT signal and indicates
an interrupt event. The MAX1617 will respond to the
standard SMBus Alert Response Address when ALERT is
asserted. Normally, the ALERT output will be asserted when
any of the following occurs:
INT_TEMP equal to or exceeds INT_HLIM
INT_TEMP falls below INT_LLIM
EXT_TEMP equal to or exceeds EXT_HLIM
EXT_TEMP falls below EXT_LLIM
External Diode “Open”
The operation of the ALERT output is controlled by the
MASK1 bit in the CONFIG register. If the MASK1 bit is set
to “1,” no interrupts will be generated on ALERT. The
ALERT output is cleared and re–armed by the Alert
Response Address (ARA). This output may be
WIRE–ORed with similar outputs from other SMBus
devices. If the alarm condition persists after the ARA, the
ALERT output will be immediately re–asserted.
V DD
Input. Power supply input. See electrical specifications.
GND
Input. Ground return for all MAX1617 functions.
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MAX1617
DC ELECTRICAL CHARACTERISTICS (V DD = 3.3 V, –55 ° C 3 T A 3 125 ° C, unless otherwise noted.)
Symbol
Characteristic
Min
Typ
Max
Unit
Power Supply
V DD
Power Supply Voltage
3.0
5.5
V
V UV–LOCK
V DD Undervoltage Lockout Threshold
2.4
2.80
2.95
V
V POR
Power–On Reset Threshold (V DD Falling Edge)
1.0
1.7
2.3
V
I DD
Operating Current
0.25 Conv./Sec Rate SMBus Inactive (1)
A
70
I DD
Operating Current
2 Conv./Sec Rate SMBus Inactive (1)
A
180
I DD–STANDBY
Standby Supply Current (SMBus Active)
100
A
I DD–STANDBY
Standby Supply Current (SMBus Inactive)
10
A
I ADD–BIAS
ADD[1:0] Bias Current (Power–Up Only)
160
A
ALERT Output
V OL
Output Low Voltage (I OL = 1.0 mA) (3)
0.4
V
ADD[1:0] Inputs
V IL
Logic Input Low
V DD x 0.3
V
V IH
Logic Input High
V DD x 0.7
V
STBY Input
V IL
Logic Input Low
V DD x 0.3
V
V IH
Logic Input High
V DD x 0.7
V
Temp–to–Bits Converter
T RES
Basic Temperature Resolution
1.0
° C
T IERR
Internal Diode Temperature
+60 ° C 3 T A 3 +100 ° C
0 ° C 3 T A 3 +125 ° C
–55 ° C 3 T A 3 0 ° C
° C
–2
–3
± 3
+2
+3
T EERR
External Diode Temperature
+60 ° C 3 T A 3 +100 ° C
0 ° C 3 T A 3 +125 ° C
–55 ° C 3 T A 3 0 ° C
° C
–3
–5
± 5
+3
+5
I DIODE–HIGH
External Diode High Source Current
(D + ) – (D ) ~ 0.65 V
100
A
I DIODE–LOW
External Diode Low Source Current
(D + ) – (D ) ~ 0.65 V
10
A
V D–SOURCE
Source Voltage
0.7
V
t CONV
Conversion Time
From CHIP STOP to Conv. Complete (2)
54
83
112
msec
CR
Conversion Rate Accuracy
(See Conversion Rate Register Desc.)
–35
+35
%
2–Wire SMBus Interface
V IH
Logic Input High
2.2
V
V IL
Logic Input Low
0.8
V
V OL
SDA Output Low
I OL = 2 mA (3)
I OL = 4 mA (3)
V
0.4
0.6
C IN Input Capacitance SDA, SCL — 5.0 — pF
I LEAK I/O Leakage –1.0 0.1 1.0 A
1. Operating current is an average value (including external diode injection pulse current) integrated over multiple conversion cycles. Transient
current may exceed this specification.
2. For true recurring conversion time see Conversion Rate register description.
3. Output current should be minimized for best temperature accuracy. Power dissipation within the MAX1617 will cause self–heating and
temperature drift error.
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MAX1617
SMBus PORT AC TIMING (V DD = 3.3 V, –55 ° C 3 (T A = T J ) 3 125 ° C; C L = 80 pF, unless otherwise noted.)
Symbol
Characteristic
Min
Typ
Max
Unit
f SMB
SMBus Clock Frequency
10
100
kHz
t LOW
Low Clock Period (10% to 10%)
4.7
sec
t HIGH
High Clock Period (90% to 90%)
4
sec
t R
SMBus Rise Time (10% to 90%)
1,000
nsec
t F
SMBus Fall Time (90% to 10%)
300
nsec
t SU(START)
Start Condition Setup Time (90% SCL to 10% SDA)
(for Repeated Start Condition)
4
sec
t H(START)
Start Condition Hold Time
4
sec
t SU–DATA
Data in Setup Time
1,000
nsec
t H–DATA
Data in Hold Time
1,250
nsec
t SU(STOP)
Stop Condition Setup Time
4
sec
t IDLE
Bus Free Time Prior to New Transition
4.7
sec
SMBUS Write Timing Diagram
A
B
C
D
E F
G
H
I J
K
L
M
I LOW
I HIGH
SCL
SDA
t SU(START)
t H(START)
t SU–DATA
t H–DATA
t SU(STOP)
t IDLE
A = Start Condition
B = MSB of Address Clocked into Slave
C = LS B of Address Clocked into Slave
D = R/W Bit Clocked into Slave
E = Slave Pulls SDA Line Low
F = Acknowledge Bit Clocked into Master
G = MSB of Data Clocked into Slave
H = LSB of Data Clocked into Slave
I = Slave Pulls SDA Line Low
J = Acknowledge Clocked into Master
K = Acknowledge Clock Pulse
L = Stop Condition, Data Executed by Slave
M= New Start Condition
SMBUS Read Timing Diagram
A
I LOW
B
I HIGH
C
D
E F
G
H
I
J
K
SCL
SDA
t SU(START) t H(START)
t SU–DATA
t SU(STOP)
t IDLE
A = Start Condition
B = MSB of Address Clocked into Slave
C = LS B of Address Clocked into Slave
D = R/W Bit Clocked into Slave
E = Slave Pulls SDA Line Low
F = Acknowledge Bit Clocked into Master
G = MSB of Data Clocked into Master
H = LSB of Data Clocked into Master
I = Acknowledge Clock Pulse
J = Stop Condition
K = New Start Condition
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