MAXIM MAX1617MEE

19-1265; Rev 1; 3/98
KIT
ATION
EVALU
E
L
B
A
AVAIL
Remote/Local Temperature Sensor
with SMBus Serial Interface
____________________________Features
The MAX1617 (patents pending) is a precise digital
thermometer that reports the temperature of both a
remote sensor and its own package. The remote sensor
is a diode-connected transistor—typically a low-cost,
easily mounted 2N3904 NPN type—that replaces conventional thermistors or thermocouples. Remote accuracy is ±3°C for multiple transistor manufacturers, with
no calibration needed. The remote channel can also
measure the die temperature of other ICs, such as
microprocessors, that contain an on-chip, diode-connected transistor.
The 2-wire serial interface accepts standard System
Management Bus (SMBus™) Write Byte, Read Byte,
Send Byte, and Receive Byte commands to program the
alarm thresholds and to read temperature data. The data
format is 7 bits plus sign, with each bit corresponding to
1°C, in twos-complement format. Measurements can be
done automatically and autonomously, with the conversion rate programmed by the user or programmed to
operate in a single-shot mode. The adjustable rate allows
the user to control the supply-current drain.
The MAX1617 is available in a small, 16-pin QSOP surface-mount package.
♦ Two Channels: Measures Both Remote and Local
Temperatures
________________________Applications
Desktop and Notebook
Computers
Central Office
Telecom Equipment
Smart Battery Packs
Test and Measurement
LAN Servers
Industrial Controls
Multi-Chip Modules
___________________Pin Configuration
♦ No Calibration Required
♦ SMBus 2-Wire Serial Interface
♦ Programmable Under/Overtemperature Alarms
♦ Supports SMBus Alert Response
♦ Accuracy:
±2°C (+60°C to +100°C, local)
±3°C (-40°C to +125°C, local)
±3°C (+60°C to +100°C, remote)
♦ 3µA (typ) Standby Supply Current
♦ 70µA (max) Supply Current in Auto-Convert Mode
♦ +3V to +5.5V Supply Range
♦ Small, 16-Pin QSOP Package
_______________Ordering Information
PART*
MAX1617MEE
TEMP. RANGE
-55°C to +125°C
*U.S. and foreign patents pending.
__________Typical Operating Circuit
3V TO 5.5V
200Ω
0.1µF
TOP VIEW
N.C. 1
16 N.C.
VCC 2
15 STBY
DXP 3
14 SMBCLK
DXN 4
PIN-PACKAGE
16 QSOP
VCC
STBY
10k EACH
MAX1617
MAX1617
DXP
13 N.C.
12 SMBDATA
N.C. 5
ADD1 6
11 ALERT
GND 7
10 ADD0
GND 8
9
2N3904
N.C.
SMBCLK
SMBDATA
DXN
2200pF
ALERT
CLOCK
DATA
INTERRUPT
TO µC
ADD0 ADD1 GND
QSOP
SMBus is a trademark of Intel Corp.
†Patents Pending
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 408-737-7600 ext. 3468.
MAX1617 †
________________General Description
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
ABSOLUTE MAXIMUM RATINGS
VCC to GND ..............................................................-0.3V to +6V
DXP, ADD_ to GND ....................................-0.3V to (VCC + 0.3V)
DXN to GND ..........................................................-0.3V to +0.8V
SMBCLK, SMBDATA, ALERT, STBY to GND ...........-0.3V to +6V
SMBDATA, ALERT Current .................................-1mA to +50mA
DXN Current .......................................................................±1mA
ESD Protection (SMBCLK, SMBDATA,
ALERT, human body model) .......................................... 4000V
ESD Protection (other pins, human body model)...............2000V
Continuous Power Dissipation (TA = +70°C)
QSOP (derate 8.30mW/°C above +70°C) .....................667mW
Operating Temperature Range .........................-55°C to +125°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +165°C
Lead Temperature (soldering, 10sec) .............................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VCC = +3.3V, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
ADC AND POWER SUPPLY
Temperature Resolution (Note 1)
Monotonicity guaranteed
8
Initial Temperature Error,
Local Diode (Note 2)
TA = +60°C to +100°C
-2
2
TA = 0°C to +85°C
-3
3
TR = +60°C to +100°C
-3
3
TR = -55°C to +125°C
-5
5
TA = +60°C to +100°C
-2.5
2.5
TA = 0°C to +85°C
-3.5
3.5
Temperature Error, Remote Diode
(Notes 2 and 3)
Temperature Error, Local Diode
(Notes 1 and 2)
Including long-term drift
Supply-Voltage Range
Undervoltage Lockout Threshold
3.0
VCC input, disables A/D conversion, rising edge
2.60
Undervoltage Lockout Hysteresis
Power-On Reset Threshold
Average Operating Supply Current
VCC, falling edge
1.0
Logic inputs
forced to VCC
or GND
3
Hardware or software standby, SMBCLK at 10kHz
4
Auto-convert mode, average
measured over 4sec. Logic
inputs forced to VCC or GND.
°C
°C
V
V
mV
2.5
V
mV
10
0.25 conv/sec
35
70
2.0 conv/sec
120
180
125
156
ms
25
%
µA
Conversion Rate Timing Error
Auto-convert mode
-25
DXP forced to 1.5V
°C
µA
94
High level
80
100
120
Low level
8
10
12
DXN Source Voltage
2
1.7
SMBus static
From stop bit to conversion complete (both channels)
Address Pin Bias Current
2.95
50
Conversion Time
Remote-Diode Source Current
5.5
2.80
50
POR Threshold Hysteresis
Standby Supply Current
Bits
ADD0, ADD1; momentary upon power-on reset
µA
0.7
V
160
µA
_______________________________________________________________________________________
Remote/Local Temperature Sensor
with SMBus Serial Interface
(VCC = +3.3V, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
SMBus INTERFACE
Logic Input High Voltage
STBY, SMBCLK, SMBDATA; VCC = 3V to 5.5V
Logic Input Low Voltage
STBY, SMBCLK, SMBDATA; VCC = 3V to 5.5V
Logic Output Low Sink Current
ALERT, SMBDATA forced to 0.4V
ALERT Output High Leakage
Current
ALERT forced to 5.5V
Logic Input Current
Logic inputs forced to VCC or GND
SMBus Input Capacitance
SMBCLK, SMBDATA
SMBus Clock Frequency
(Note 4)
DC
SMBCLK Clock Low Time
tLOW, 10% to 10% points
4.7
µs
SMBCLK Clock High Time
tHIGH, 90% to 90% points
4
µs
4.7
µs
500
ns
SMBus Start-Condition Setup Time
2.2
V
0.8
6
V
mA
-1
1
µA
1
µA
100
kHz
5
pF
SMBus Repeated Start-Condition
Setup Time
tSU:STA, 90% to 90% points
SMBus Start-Condition Hold Time
tHD:STA, 10% of SMBDATA to 90% of SMBCLK
4
µs
SMBus Stop-Condition Setup Time
tSU:STO, 90% of SMBCLK to 10% of SMBDATA
4
µs
SMBus Data Valid to SMBCLK
Rising-Edge Time
tSU:DAT, 10% or 90% of SMBDATA to 10% of SMBCLK
800
ns
SMBus Data-Hold Time
tHD:DAT (Note 5)
0
µs
SMBCLK Falling Edge to SMBus
Data-Valid Time
Master clocking in data
1
µs
MAX
UNITS
ELECTRICAL CHARACTERISTICS
(VCC = +3.3V, TA = -55°C to +125°C, unless otherwise noted.) (Note 6)
PARAMETER
CONDITIONS
MIN
TYP
ADC AND POWER SUPPLY
Temperature Resolution (Note 1)
Monotonicity guaranteed
8
Initial Temperature Error,
Local Diode (Note 2)
TA = +60°C to +100°C
-2
2
TA = -55°C to +125°C
-3
3
Temperature Error, Remote Diode
(Notes 2 and 3)
TR = +60°C to +100°C
-3
3
TR = -55°C to +125°C
-5
5
3.0
5.5
V
156
ms
25
%
Supply-Voltage Range
Conversion Time
From stop bit to conversion complete (both channels)
94
Conversion Rate Timing Error
Auto-convert mode
-25
Bits
125
°C
°C
_______________________________________________________________________________________
3
MAX1617
ELECTRICAL CHARACTERISTICS (continued)
ELECTRICAL CHARACTERISTICS (continued)
(VCC = +3.3V, TA = -55°C to +125°C, unless otherwise noted.) (Note 6)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
SMBus INTERFACE
VCC = 3V
2.2
VCC = 5.5V
2.4
Logic Input High Voltage
STBY, SMBCLK, SMBDATA
Logic Input Low Voltage
STBY, SMBCLK, SMBDATA; VCC = 3V to 5.5V
Logic Output Low Sink Current
ALERT, SMBDATA forced to 0.4V
ALERT Output High Leakage
Current
ALERT forced to 5.5V
Logic Input Current
Logic inputs forced to VCC or GND
V
0.8
V
6
mA
-2
1
µA
2
µA
Note 1: Guaranteed but not 100% tested.
Note 2: Quantization error is not included in specifications for temperature accuracy. For example, if the MAX1617 device temperature is exactly +66.7°C, the ADC may report +66°C, +67°C, or +68°C (due to the quantization error plus the +1/2°C offset
used for rounding up) and still be within the guaranteed ±1°C error limits for the +60°C to +100°C temperature range. See
Table 2.
Note 3: A remote diode is any diode-connected transistor from Table 1. TR is the junction temperature of the remote diode. See
Remote Diode Selection for remote diode forward voltage requirements.
Note 4: The SMBus logic block is a static design that works with clock frequencies down to DC. While slow operation is possible, it
violates the 10kHz minimum clock frequency and SMBus specifications, and may monopolize the bus.
Note 5: Note that a transition must internally provide at least a hold time in order to bridge the undefined region (300ns max) of
SMBCLK’s falling edge.
Note 6: Specifications from -55°C to +125°C are guaranteed by design, not production tested.
__________________________________________Typical Operating Characteristics
(TA = +25°C, unless otherwise noted.)
PATH = DXP TO GND
0
-10
1
ZETEX FMMT3904
0
MOTOROLA MMBT3904
SAMSUNG KST3904
-1
-20
3
10
30
LEAKAGE RESISTANCE (MΩ)
100
MAX1617TOC04
VIN = SQUARE WAVE APPLIED TO
VCC WITH NO 0.1µF VCC CAPACITOR
9
VIN = 250mVp-p
REMOTE DIODE
6
VIN = 250mVp-p
LOCAL DIODE
VIN = 100mVp-p
REMOTE DIODE
3
0
-2
1
12
RANDOM
SAMPLES
PATH = DXP TO VCC (5V)
4
MAX1617TOC02
MAX1617TOC01
10
2
TEMPERATURE ERROR (°C)
20
TEMPERATURE ERROR vs.
POWER-SUPPLY NOISE FREQUENCY
TEMPERATURE ERROR
vs. REMOTE-DIODE TEMPERATURE
TEMPERATURE ERROR (°C)
TEMPERATURE ERROR
vs. PC BOARD RESISTANCE
TEMPERATURE ERROR (°C)
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
-50
0
50
TEMPERATURE (°C)
100
150
50
500
5k
50k
500k
FREQUENCY (Hz)
_______________________________________________________________________________________
5M
50M
Remote/Local Temperature Sensor
with SMBus Serial Interface
20
VIN = 50mVp-p
VIN = 25mVp-p
0
10
VIN = 10mVp-p SQUARE WAVE
APPLIED TO DXP-DXN
TEMPERATURE ERROR (°C)
TEMPERATURE ERROR (°C)
VIN = 100mVp-p
MAX1617TOC03
VIN = SQUARE WAVE
AC COUPLED TO DXN
TEMPERATURE ERROR (°C)
5
MAX1617TOC05
30
10
TEMPERATURE ERROR vs.
DIFFERENTIAL-MODE NOISE FREQUENCY
TEMPERATURE ERROR vs.
DIFFERENTIAL-MODE NOISE FREQUENCY
MAX1617TOC06
TEMPERATURE ERROR vs.
COMMON-MODE NOISE FREQUENCY
5
0
VIN = 3mVp-p SQUARE WAVE
APPLIED TO DXP-DXN
0
500
5k
50k
500k
5M
50M
50
500
5k
50k
500k
5M
50
50M
500
5k
50k
500k
5M
FREQUENCY (Hz)
FREQUENCY (Hz)
FREQUENCY (Hz)
TEMPERATURE ERROR vs.
DXP–DXN CAPACITANCE
STANDBY SUPPLY CURRENT
vs. CLOCK FREQUENCY
STANDBY SUPPLY CURRENT
vs. SUPPLY VOLTAGE
10
25
VCC = 5V
20
15
10
50M
ADD0,
ADD1
= GND
60
VCC = 3.3V
MAX1617TOC09
100
SUPPLY CURRENT (µA)
SMBCLK IS
DRIVEN RAIL-TO-RAIL
30
SUPPLY CURRENT (µA)
VCC = 5V
MAX1617TOC08
35
MAX1617TOC07
20
ADD0,
ADD1
= HIGH-Z
20
6
3
5
0
0
0
0
20
40
60
80
100
1k
DXP-DXN CAPACITANCE (nF)
10k
100k
0
1000k
1
2
3
4
5
SUPPLY VOLTAGE (V)
SMBCLK FREQUENCY (Hz)
OPERATING SUPPLY CURRENT
vs. CONVERSION RATE
RESPONSE TO THERMAL SHOCK
VCC = 5V
AVERAGED MEASUREMENTS
100
TEMPERATURE (°C)
400
300
200
100
MAX1617TOC11
125
MAX1617TOC10
500
SUPPLY CURRENT (µA)
TEMPERATURE ERROR (°C)
-5
-5
50
75
50
25
16-QSOP IMMERSED
IN +115°C FLUORINERT BATH
0
0 0.0625 0.125 0.25
0.5
1
2
CONVERSION RATE (Hz)
4
8
0
T = -2
T=0
T=2
T=4
T=6
T=8
T = 10
TIME (sec)
_______________________________________________________________________________________
5
MAX1617
____________________________Typical Operating Characteristics (continued)
(TA = +25°C, unless otherwise noted.)
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
______________________________________________________________Pin Description
PIN
NAME
FUNCTION
1, 5, 9,
13, 16
N.C.
No Connection. Not internally connected. May be used for PC board trace routing.
2
VCC
Supply Voltage Input, 3V to 5.5V. Bypass to GND with a 0.1µF capacitor. A 200Ω series resistor is recommended but not required for additional noise filtering.
3
DXP
Combined Current Source and A/D Positive Input for remote-diode channel. Do not leave DXP floating; tie
DXP to DXN if no remote diode is used. Place a 2200pF capacitor between DXP and DXN for noise filtering.
4
DXN
Combined Current Sink and A/D Negative Input. DXN is normally biased to a diode voltage above
ground.
6
ADD1
SMBus Address Select pin (Table 8). ADD0 and ADD1 are sampled upon power-up. Excess capacitance
(>50pF) at the address pins when floating may cause address-recognition problems.
7, 8
GND
Ground
10
ADD0
SMBus Slave Address Select pin
11
ALERT
SMBus Alert (interrupt) Output, open drain
12
SMBDATA
14
SMBCLK
15
STBY
SMBus Serial-Data Input/Output, open drain
SMBus Serial-Clock Input
Hardware Standby Input. Temperature and comparison threshold data are retained in standby mode.
Low = standby mode, high = operate mode.
_______________Detailed Description
The MAX1617 (patents pending) is a temperature sensor designed to work in conjunction with an external
microcontroller (µC) or other intelligence in thermostatic, process-control, or monitoring applications. The µC
is typically a power-management or keyboard controller, generating SMBus serial commands by “bitbanging” general-purpose input-output (GPIO) pins or
via a dedicated SMBus interface block.
Essentially an 8-bit serial analog-to-digital converter
(ADC) with a sophisticated front end, the MAX1617
contains a switched current source, a multiplexer, an
ADC, an SMBus interface, and associated control logic
(Figure 1). Temperature data from the ADC is loaded
into two data registers, where it is automatically compared with data previously stored in four over/undertemperature alarm registers.
ADC and Multiplexer
The ADC is an averaging type that integrates over a
60ms period (each channel, typical), with excellent
noise rejection.
The multiplexer automatically steers bias currents
through the remote and local diodes, measures their
forward voltages, and computes their temperatures.
Both channels are automatically converted once the
conversion process has started, either in free-running
or single-shot mode. If one of the two channels is not
used, the device still performs both measurements, and
the user can simply ignore the results of the unused
channel. If the remote diode channel is unused, tie DXP
to DXN rather than leaving the pins open.
The DXN input is biased at 0.65V above ground by an
internal diode to set up the analog-to-digital (A/D)
inputs for a differential measurement. The worst-case
DXP–DXN differential input voltage range is 0.25V to
0.95V.
Excess resistance in series with the remote diode causes about +1/2°C error per ohm. Likewise, 200µV of offset voltage forced on DXP–DXN causes about 1°C error.
6
_______________________________________________________________________________________
ALERT
GND
DXN
DXP
REMOTE TEMPERATURE
DATA REGISTER
DIODE
FAULT
LOCAL
REMOTE
-
+
Q
R
S
DIGITAL COMPARATOR
(REMOTE)
8
LOW-TEMPERATURE THRESHOLD
(REMOTE TLOW)
8 HIGH-TEMPERATURE THRESHOLD
(REMOTE THIGH)
8
-
+
-
+
MUX
ADC
8
CONTROL
LOGIC
SELECTED VIA
SLAVE ADD = 0001 100
DIGITAL COMPARATOR
(LOCAL)
8
LOW-TEMPERATURE THRESHOLD
(LOCAL TLOW)
HIGH-TEMPERATURE THRESHOLD 8
(LOCAL THIGH)
LOCAL TEMPERATURE
DATA REGISTER
MAX1617
2
8
READ
ALERT RESPONSE
ADDRESS REGISTER
CONVERSION RATE
REGISTER
CONFIGURATION
BYTE REGISTER
STATUS BYTE REGISTER
8
WRITE
SMBUS
7
ADD1
ADDRESS
DECODER
ADD0
COMMAND BYTE
(INDEX) REGISTER
STBY
SMBCLK
SMBDATA
MAX1617
VCC
Remote/Local Temperature Sensor
with SMBus Serial Interface
Figure 1. Functional Diagram
_______________________________________________________________________________________
7
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
A/D Conversion Sequence
If a Start command is written (or generated automatically in the free-running auto-convert mode), both channels are converted, and the results of both
measurements are available after the end of conversion. A BUSY status bit in the status byte shows that the
device is actually performing a new conversion; however, even if the ADC is busy, the results of the previous
conversion are always available.
Remote-Diode Selection
Temperature accuracy depends on having a good-quality, diode-connected small-signal transistor. Accuracy
has been experimentally verified for all of the devices
listed in Table 1. The MAX1617 can also directly measure the die temperature of CPUs and other integrated
circuits having on-board temperature-sensing diodes.
The transistor must be a small-signal type with a relatively high forward voltage; otherwise, the A/D input
voltage range can be violated. The forward voltage
must be greater than 0.25V at 10µA; check to ensure
this is true at the highest expected temperature. The
forward voltage must be less than 0.95V at 100µA;
check to ensure this is true at the lowest expected temperature. Large power transistors don’t work at all.
Also, ensure that the base resistance is less than 100Ω.
Tight specifications for forward-current gain (+50 to
+150, for example) indicate that the manufacturer has
good process controls and that the devices have consistent VBE characteristics.
For heat-sink mounting, the 500-32BT02-000 thermal
sensor from Fenwal Electronics is a good choice. This
device consists of a diode-connected transistor, an
aluminum plate with screw hole, and twisted-pair cable
(Fenwal Inc., Milford, MA, 508-478-6000).
Thermal Mass and Self-Heating
Thermal mass can seriously degrade the MAX1617’s
effective accuracy. The thermal time constant of the
QSOP-16 package is about 140sec in still air. For the
MAX1617 junction temperature to settle to within +1°C
after a sudden +100°C change requires about five time
constants or 12 minutes. The use of smaller packages
for remote sensors, such as SOT23s, improves the situation. Take care to account for thermal gradients
between the heat source and the sensor, and ensure
that stray air currents across the sensor package do
not interfere with measurement accuracy.
Self-heating does not significantly affect measurement
accuracy. Remote-sensor self-heating due to the diode
current source is negligible. For the local diode, the
worst-case error occurs when auto-converting at the
8
Table 1. Remote-Sensor Transistor
Manufacturers
MANUFACTURER
MODEL NUMBER
Central Semiconductor (USA)
CMPT3904
Motorola (USA)
MMBT3904
National Semiconductor (USA)
MMBT3904
Rohm Semiconductor (Japan)
SST3904
Samsung (Korea)
KST3904-TF
Siemens (Germany)
SMBT3904
Zetex (England)
FMMT3904CT-ND
Note: Transistors must be diode-connected (base shorted to
collector).
fastest rate and simultaneously sinking maximum current at the ALERT output. For example, at an 8Hz rate
and with ALERT sinking 1mA, the typical power dissipation is VCC x 450µA plus 0.4V x 1mA. Package theta
J-A is about 150°C/W, so with VCC = 5V and no copper
PC board heat-sinking, the resulting temperature rise
is:
dT = 2.7mW x 150°C/W = 0.4°C
Even with these contrived circumstances, it is difficult
to introduce significant self-heating errors.
ADC Noise Filtering
The ADC is an integrating type with inherently good
noise rejection, especially of low-frequency signals
such as 60Hz/120Hz power-supply hum. Micropower
operation places constraints on high-frequency noise
rejection; therefore, careful PC board layout and proper
external noise filtering are required for high-accuracy
remote measurements in electrically noisy environments.
High-frequency EMI is best filtered at DXP and DXN
with an external 2200pF capacitor. This value can be
increased to about 3300pF (max), including cable
capacitance. Higher capacitance than 3300pF introduces errors due to the rise time of the switched current source.
Nearly all noise sources tested cause the ADC measurements to be higher than the actual temperature, typically
by +1°C to +10°C, depending on the frequency and
amplitude (see Typical Operating Characteristics).
_______________________________________________________________________________________
Remote/Local Temperature Sensor
with SMBus Serial Interface
2) Do not route the DXP–DXN lines next to the deflection coils of a CRT. Also, do not route the traces
across a fast memory bus, which can easily introduce +30°C error, even with good filtering.
Otherwise, most noise sources are fairly benign.
3) Route the DXP and DXN traces in parallel and in
close proximity to each other, away from any highvoltage traces such as +12VDC. Leakage currents
from PC board contamination must be dealt with
carefully, since a 20MΩ leakage path from DXP to
ground causes about +1°C error.
4) Connect guard traces to GND on either side of the
DXP–DXN traces (Figure 2). With guard traces in
place, routing near high-voltage traces is no longer
an issue.
5) Route through as few vias and crossunders as possible to minimize copper/solder thermocouple effects.
6) When introducing a thermocouple, make sure that
both the DXP and the DXN paths have matching
thermocouples. In general, PC board-induced thermocouples are not a serious problem. A copper-solder thermocouple exhibits 3µV/°C, and it takes
about 200µV of voltage error at DXP–DXN to cause
a +1°C measurement error. So, most parasitic thermocouple errors are swamped out.
7) Use wide traces. Narrow ones are more inductive
and tend to pick up radiated noise. The 10 mil
widths and spacings recommended in Figure 2
aren’t absolutely necessary (as they offer only a
minor improvement in leakage and noise), but try to
use them where practical.
8) Keep in mind that copper can’t be used as an EMI
shield, and only ferrous materials such as steel work
well. Placing a copper ground plane between the
DXP-DXN traces and traces carrying high-frequency
noise signals does not help reduce EMI.
PC Board Layout Checklist
• Place the MAX1617 close to a remote diode.
•
•
•
•
Keep traces away from high voltages (+12V bus).
Keep traces away from fast data buses and CRTs.
Use recommended trace widths and spacings.
Place a ground plane under the traces.
MAX1617
PC Board Layout
1) Place the MAX1617 as close as practical to the
remote diode. In a noisy environment, such as a
computer motherboard, this distance can be 4 in. to
8 in. (typical) or more as long as the worst noise
sources (such as CRTs, clock generators, memory
buses, and ISA/PCI buses) are avoided.
GND
10 MILS
10 MILS
DXP
MINIMUM
10 MILS
DXN
10 MILS
GND
Figure 2. Recommended DXP/DXN PC Traces
• Use guard traces flanking DXP and DXN and connecting to GND.
• Place the noise filter and the 0.1µF V CC bypass
capacitors close to the MAX1617.
• Add a 200Ω resistor in series with VCC for best
noise filtering (see Typical Operating Circuit).
Twisted Pair and Shielded Cables
For remote-sensor distances longer than 8 in., or in particularly noisy environments, a twisted pair is recommended. Its practical length is 6 feet to 12 feet (typical)
before noise becomes a problem, as tested in a noisy
electronics laboratory. For longer distances, the best
solution is a shielded twisted pair like that used for audio
microphones. For example, Belden #8451 works well for
distances up to 100 feet in a noisy environment. Connect
the twisted pair to DXP and DXN and the shield to GND,
and leave the shield’s remote end unterminated.
Excess capacitance at DX_ limits practical remote sensor distances (see Typical Operating Characteristics).
For very long cable runs, the cable’s parasitic capacitance often provides noise filtering, so the 2200pF
capacitor can often be removed or reduced in value.
Cable resistance also affects remote-sensor accuracy;
1Ω series resistance introduces about +1/2°C error.
Low-Power Standby Mode
Standby mode disables the ADC and reduces the supply-current drain to less than 10µA. Enter standby
mode by forcing the STBY pin low or via the RUN/STOP
bit in the configuration byte register. Hardware and
software standby modes behave almost identically: all
data is retained in memory, and the SMB interface is
alive and listening for reads and writes. The only difference is that in hardware standby mode, the one-shot
command does not initiate a conversion.
Standby mode is not a shutdown mode. With activity on
the SMBus, extra supply current is drawn (see Typical
Operating Characteristics). In software standby mode,
_______________________________________________________________________________________
9
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
SMBus Digital Interface
the MAX1617 can be forced to perform A/D conversions
via the one-shot command, despite the RUN/STOP bit
being high.
From a software perspective, the MAX1617 appears as a
set of byte-wide registers that contain temperature data,
alarm threshold values, or control bits. A standard
SMBus 2-wire serial interface is used to read temperature data and write control bits and alarm threshold data.
Each A/D channel within the device responds to the
same SMBus slave address for normal reads and writes.
The MAX1617 employs four standard SMBus protocols:
Write Byte, Read Byte, Send Byte, and Receive Byte
(Figure 3). The shorter Receive Byte protocol allows
quicker transfers, provided that the correct data register
was previously selected by a Read Byte instruction. Use
caution with the shorter protocols in multi-master systems,
since a second master could overwrite the command
byte without informing the first master.
Activate hardware standby mode by forcing the STBY
pin low. In a notebook computer, this line may be connected to the system SUSTAT# suspend-state signal.
The STBY pin low state overrides any software conversion
command. If a hardware or software standby command is
received while a conversion is in progress, the conversion
cycle is truncated, and the data from that conversion is not
latched into either temperature reading register. The previous data is not changed and remains available.
Supply-current drain during the 125ms conversion period is always about 450µA. Slowing down the conversion rate reduces the average supply current (see
Typical Operating Characteristics). In between conversions, the instantaneous supply current is about 25µA
due to the current consumed by the conversion rate
timer. In standby mode, supply current drops to about
3µA. At very low supply voltages (under the power-onreset threshold), the supply current is higher due to the
address pin bias currents. It can be as high as 100µA,
depending on ADD0 and ADD1 settings.
The temperature data format is 7 bits plus sign in twos-complement form for each channel, with each data bit representing 1°C (Table 2), transmitted MSB first. Measurements
are offset by +1/2°C to minimize internal rounding errors; for
example, +99.6°C is reported as +100°C.
Write Byte Format
S
ADDRESS
WR
ACK
COMMAND
7 bits
ACK
DATA
8 bits
Slave Address: equivalent to chip-select line of
a 3-wire interface
ACK
P
8 bits
Command Byte: selects which
register you are writing to
1
Data Byte: data goes into the register
set by the command byte (to set
thresholds, configuration masks, and
sampling rate)
Read Byte Format
S
ADDRESS
WR
ACK
7 bits
COMMAND
ACK
ACK
Command Byte: selects
which register you are
reading from
DATA
WR
ACK
COMMAND
ACK
P
8 bits
Command Byte: sends command with no data, usually
used for one-shot command
P
8 bits
Slave Address: repeated
due to change in dataflow direction
Data Byte: reads from
the register set by the
command byte
Shaded = Slave transmission
/// = Not acknowledged
S
ADDRESS
7 bits
RD
ACK
DATA
///
P
8 bits
Data Byte: reads data from
the register commanded
by the last Read Byte or
Write Byte transmission;
also used for SMBus Alert
Response return address
Figure 3. SMBus Protocols
10
///
Receive Byte Format
7 bits
S = Start condition
P = Stop condition
RD
7 bits
Send Byte Format
ADDRESS
ADDRESS
8 bits
Slave Address: equivalent to chip-select line
S
S
______________________________________________________________________________________
Remote/Local Temperature Sensor
with SMBus Serial Interface
TEMP.
(°C)
ROUNDED
TEMP.
(°C)
DIGITAL OUTPUT
DATA BITS
SIGN
MSB
LSB
+130.00
+127
0
111
1111
+127.00
+127
0
111
1111
+126.50
+127
0
111
1111
+126.00
+126
0
111
1110
+25.25
+25
0
001
1001
+0.50
+1
0
000
+0.25
+0
0
+0.00
+0
-0.25
Table 3. Read Format for Alert Response
Address (0001100)
BIT
NAME
7
(MSB)
ADD7
6
ADD6
5
ADD5
4
ADD4
3
ADD3
0001
2
ADD2
000
0000
1
ADD1
0
000
0000
+0
0
000
0000
0
(LSB)
1
-0.50
+0
0
000
0000
-0.75
-1
1
111
1111
-1.00
-1
1
111
1111
-25.00
-25
1
110
0111
-25.50
-25
1
110
0110
-54.75
-55
1
100
1001
-55.00
-55
1
100
1001
-65.00
-65
1
011
1111
-70.00
-65
1
011
1111
Alarm Threshold Registers
Four registers store alarm threshold data, with hightemperature (THIGH) and low-temperature (TLOW) registers for each A/D channel. If either measured
temperature equals or exceeds the corresponding
alarm threshold value, an ALERT interrupt is asserted.
The power-on-reset (POR) state of both THIGH registers
is full scale (0111 1111, or +127°C). The POR state of
both TLOW registers is 1100 1001 or -55°C.
Diode Fault Alarm
There is a continuity fault detector at DXP that detects
whether the remote diode has an open-circuit condition. At the beginning of each conversion, the diode
fault is checked, and the status byte is updated. This
fault detector is a simple voltage detector; if DXP rises
above V CC - 1V (typical) due to the diode current
source, a fault is detected. Note that the diode fault
isn’t checked until a conversion is initiated, so immediately after power-on reset the status byte indicates no
fault is present, even if the diode path is broken.
If the remote channel is shorted (DXP to DXN or DXP to
GND), the ADC reads 0000 0000 so as not to trip either
FUNCTION
Provide the current MAX1617
slave address that was latched at
POR (Table 8)
Logic 1
the T HIGH or T LOW alarms at their POR settings. In
applications that are never subjected to 0°C in normal
operation, a 0000 0000 result can be checked to indicate a fault condition in which DXP is accidentally short
circuited. Similarly, if DXP is short circuited to VCC, the
ADC reads +127°C for both remote and local channels,
and the device alarms.
ALERT Interrupts
The ALERT interrupt output signal is latched and can
only be cleared by reading the Alert Response address.
Interrupts are generated in response to THIGH and TLOW
comparisons and when the remote diode is disconnected (for continuity fault detection). The interrupt does not
halt automatic conversions; new temperature data continues to be available over the SMBus interface after
ALERT is asserted. The interrupt output pin is open-drain
so that devices can share a common interrupt line. The
interrupt rate can never exceed the conversion rate.
The interface responds to the SMBus Alert Response
address, an interrupt pointer return-address feature
(see Alert Response Address section). Prior to taking
corrective action, always check to ensure that an interrupt is valid by reading the current temperature.
Alert Response Address
The SMBus Alert Response interrupt pointer provides
quick fault identification for simple slave devices that
lack the complex, expensive logic needed to be a bus
master. Upon receiving an ALERT interrupt signal, the
host master can broadcast a Receive Byte transmission
to the Alert Response slave address (0001 100). Then
any slave device that generated an interrupt attempts
to identify itself by putting its own address on the bus
(Table 3).
______________________________________________________________________________________
11
MAX1617
Table 2. Data Format (Twos-Complement)
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
Table 4. Command-Byte Bit Assignments
REGISTER
COMMAND
POR STATE
FUNCTION
RLTS
00h
0000 0000*
Read local temperature: returns latest temperature
RRTE
01h
0000 0000*
Read remote temperature: returns latest temperature
RSL
02h
N/A
Read status byte (flags, busy signal)
RCL
03h
0000 0000
Read configuration byte
RCRA
04h
0000 0010
Read conversion rate byte
RLHN
05h
0111 1111
Read local THIGH limit
RLLI
06h
1100 1001
Read local TLOW limit
RRHI
07h
0111 1111
Read remote THIGH limit
RRLS
08h
1100 1001
Read remote TLOW limit
WCA
09h
N/A
Write configuration byte
WCRW
0Ah
N/A
Write conversion rate byte
WLHO
0Bh
N/A
Write local THIGH limit
WLLM
0Ch
N/A
Write local TLOW limit
WRHA
0Dh
N/A
Write remote THIGH limit
WRLN
0Eh
N/A
Write remote TLOW limit
OSHT
0Fh
N/A
One-shot command (use send-byte format)
*If the device is in hardware standby mode at POR, both temperature registers read 0°C.
The Alert Response can activate several different slave
devices simultaneously, similar to the I2C General Call.
If more than one slave attempts to respond, bus arbitration rules apply, and the device with the lower address
code wins. The losing device does not generate an
acknowledge and continues to hold the ALERT line low
until serviced (implies that the host interrupt input is
level-sensitive). Successful reading of the alert
response address clears the interrupt latch.
Command Byte Functions
The 8-bit command byte register (Table 4) is the master
index that points to the various other registers within the
MAX1617. The register’s POR state is 0000 0000, so
that a Receive Byte transmission (a protocol that lacks
the command byte) that occurs immediately after POR
returns the current local temperature data.
The one-shot command immediately forces a new conversion cycle to begin. In software standby mode
(RUN/STOP bit = high), a new conversion is begun, after
which the device returns to standby mode. If a conversion
is in progress when a one-shot command is received, the
command is ignored. If a one-shot command is received
in auto-convert mode (RUN/STOP bit = low) between conversions, a new conversion begins, the conversion rate
timer is reset, and the next automatic conversion takes
place after a full delay elapses.
12
Configuration Byte Functions
The configuration byte register (Table 5) is used to
mask (disable) interrupts and to put the device in software standby mode. The lower six bits are internally set
to (XX1111), making them “don’t care” bits. Write zeros
to these bits. This register’s contents can be read back
over the serial interface.
Status Byte Functions
The status byte register (Table 6) indicates which (if
any) temperature thresholds have been exceeded. This
byte also indicates whether or not the ADC is converting and whether there is an open circuit in the remote
diode DXP–DXN path. After POR, the normal state of all
the flag bits is zero, assuming none of the alarm conditions are present. The status byte is cleared by any
successful read of the status byte, unless the fault persists. Note that the ALERT interrupt latch is not automatically cleared when the status flag bit is cleared.
When reading the status byte, you must check for internal bus collisions caused by asynchronous ADC timing,
or else disable the ADC prior to reading the status byte
(via the RUN/STOP bit in the configuration byte). In
one-shot mode, read the status byte only after the conversion is complete, which is 150ms max after the oneshot conversion is commanded.
______________________________________________________________________________________
Remote/Local Temperature Sensor
with SMBus Serial Interface
Table 7. Conversion-Rate Control Byte
DATA
CONVERSION
RATE
(Hz)
AVERAGE SUPPLY
CURRENT
(µA typ, at VCC = 3.3V)
BIT
NAME
POR
STATE
7 (MSB)
MASK
0
Masks all ALERT interrupts when high.
00h
0.0625
30
01h
0.125
33
02h
0.25
35
03h
0.5
48
0
Standby mode control
bit. If high, the device
immediately stops converting and enters standby mode. If low, the
device converts in either
one-shot or timer mode.
04h
1
70
05h
2
128
06h
4
225
07h
8
425
08h to
FFh
RFU
—
6
5–0
RUN/
STOP
RFU
0
FUNCTION
Reserved for future use
Table 6. Status-Byte Bit Assignments
BIT
NAME
FUNCTION
7
(MSB)
BUSY
A high indicates that the ADC is busy
converting.
6
LHIGH*
A high indicates that the local hightemperature alarm has activated.
5
LLOW*
A high indicates that the local lowtemperature alarm has activated.
4
RHIGH*
A high indicates that the remote hightemperature alarm has activated.
3
RLOW*
A high indicates that the remote lowtemperature alarm has activated.
2
OPEN*
A high indicates a remote-diode continuity (open-circuit) fault.
1
RFU
Reserved for future use (returns 0)
0
(LSB)
RFU
Reserved for future use (returns 0)
*These flags stay high until cleared by POR, or until the status
byte register is read.
To check for internal bus collisions, read the status
byte. If the least significant seven bits are ones, discard
the data and read the status byte again. The status bits
LHIGH, LLOW, RHIGH, and RLOW are refreshed on the
SMBus clock edge immediately following the stop condition, so there is no danger of losing temperature-related status data as a result of an internal bus collision.
The OPEN status bit (diode continuity fault) is only
refreshed at the beginning of a conversion, so OPEN
MAX1617
Table 5. Configuration-Byte Bit
Assignments
data is lost. The ALERT interrupt latch is independent of
the status byte register, so no false alerts are generated by an internal bus collision.
When auto-converting, if the THIGH and TLOW limits
are close together, it’s possible for both high-temp and
low-temp status bits to be set, depending on the
amount of time between status read operations (especially when converting at the fastest rate). In these circumstances, it’s best not to rely on the status bits to
indicate reversals in long-term temperature changes
and instead use a current temperature reading to
establish the trend direction.
Conversion Rate Byte
The conversion rate register (Table 7) programs the
time interval between conversions in free-running autoconvert mode. This variable rate control reduces the
supply current in portable-equipment applications. The
conversion rate byte’s POR state is 02h (0.25Hz). The
MAX1617 looks only at the 3 LSB bits of this register, so
the upper 5 bits are “don’t care” bits, which should be
set to zero. The conversion rate tolerance is ±25% at
any rate setting.
Valid A/D conversion results for both channels are
available one total conversion time (125ms nominal,
156ms maximum) after initiating a conversion, whether
conversion is initiated via the RUN/STOP bit, hardware
STBY pin, one-shot command, or initial power-up.
Changing the conversion rate can also affect the delay
until new results are available. See Table 8.
______________________________________________________________________________________
13
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
Table 8. RLTS and RRTE Temp Register Update Timing Chart
OPERATING MODE
CONVERSION INITIATED BY:
NEW CONVERSION RATE
(CHANGED VIA WRITE TO
WCRW)
TIME UNTIL RLTS AND RRTE
ARE UPDATED
Auto-Convert
Power-on reset
n/a (0.25Hz)
156ms max
Auto-Convert
1-shot command, while idling
between automatic conversions
n/a
156ms max
Auto-Convert
1-shot command that occurs
during a conversion
n/a
When current conversion is
complete (1-shot is ignored)
Auto-Convert
Rate timer
0.0625Hz
20sec
Auto-Convert
Rate timer
0.125Hz
10sec
Auto-Convert
Rate timer
0.25Hz
5sec
Auto-Convert
Rate timer
0.5Hz
2.5sec
Auto-Convert
Rate timer
1Hz
1.25sec
Auto-Convert
Rate timer
2Hz
625ms
Auto-Convert
Rate timer
4Hz
312.5ms
Auto-Convert
Rate timer
8Hz
237.5ms
Hardware Standby
STBY pin
n/a
156ms
Software Standby
RUN/STOP bit
n/a
156ms
Software Standby
1-shot command
n/a
156ms
Slave Addresses
The MAX1617 appears to the SMBus as one device
having a common address for both ADC channels. The
device address can be set to one of nine different values by pin-strapping ADD0 and ADD1 so that more
than one MAX1617 can reside on the same bus without
address conflicts (Table 9).
The address pin states are checked at POR only, and
the address data stays latched to reduce quiescent
supply current due to the bias current needed for high-Z
state detection.
The MAX1617 also responds to the SMBus Alert
Response slave address (see the Alert Response
Address section).
Table 9. Slave Address Decoding (ADD0
and ADD1)
ADD0
ADD1
ADDRESS
GND
GND
0011 000
GND
High-Z
0011 001
GND
VCC
0011 010
High-Z
GND
0101 001
High-Z
High-Z
0101 010
High-Z
VCC
0101 011
VCC
GND
1001 100
VCC
High-Z
1001 101
VCC
VCC
1001 110
POR and UVLO
Note: High-Z means that the pin is left unconnected and floating.
The MAX1617 has a volatile memory. To prevent ambiguous power-supply conditions from corrupting the data in
memory and causing erratic behavior, a POR voltage
detector monitors VCC and clears the memory if VCC falls
below 1.7V (typical, see Electrical Characteristics table).
When power is first applied and VCC rises above 1.75V
(typical), the logic blocks begin operating, although reads
and writes at VCC levels below 3V are not recommended.
A second VCC comparator, the ADC UVLO comparator,
prevents the ADC from converting until there is sufficient
headroom (VCC = 2.8V typical).
Power-Up Defaults:
• Interrupt latch is cleared.
• Address select pins are sampled.
• ADC begins auto-converting at a 0.25Hz rate.
• Command byte is set to 00h to facilitate quick
remote Receive Byte queries.
• THIGH and TLOW registers are set to max and min
limits, respectively.
14
______________________________________________________________________________________
Remote/Local Temperature Sensor
with SMBus Serial Interface
tLOW
B
tHIGH
C
E
D
F
G
I
H
J
K
L
MAX1617
A
M
SMBCLK
SMBDATA
tHD:STA
tSU:STA
tSU:DAT
A = START CONDITION
B = MSB OF ADDRESS CLOCKED INTO SLAVE
C = LSB OF ADDRESS CLOCKED INTO SLAVE
D = R/W BIT CLOCKED INTO SLAVE
E = SLAVE PULLS SMBDATA LINE LOW
tHD:DAT
tSU:STO tBUF
J = ACKNOWLEDGE CLOCKED INTO MASTER
K = ACKNOWLEDGE CLOCK PULSE
L = STOP CONDITION, DATA EXECUTED BY SLAVE
M = NEW START CONDITION
F = ACKNOWLEDGE BIT CLOCKED INTO MASTER
G = MSB OF DATA CLOCKED INTO SLAVE
H = LSB OF DATA CLOCKED INTO SLAVE
I = SLAVE PULLS SMBDATA LINE LOW
Figure 4. SMBus Write Timing Diagram
A
B
tLOW
C
D
E
F
G
tHIGH
H
J
I
K
SMBCLK
SMBDATA
tSU:STA tHD:STA
A = START CONDITION
B = MSB OF ADDRESS CLOCKED INTO SLAVE
C = LSB OF ADDRESS CLOCKED INTO SLAVE
D = R/W BIT CLOCKED INTO SLAVE
tSU:STO
tSU:DAT
E = SLAVE PULLS SMBDATA LINE LOW
F = ACKNOWLEDGE BIT CLOCKED INTO MASTER
G = MSB OF DATA CLOCKED INTO MASTER
H = LSB OF DATA CLOCKED INTO MASTER
tBUF
I = ACKNOWLEDGE CLOCK PULSE
J = STOP CONDITION
K = NEW START CONDITION
Figure 5. SMBus Read Timing Diagram
Programming Example:
Clock-Throttling Control for CPUs
An untested example of pseudocode for proportional
temperature control of Intel mobile CPUs via a powermanagement microcontroller is given in Listing 1. This
program consists of two main parts: an initialization routine and an interrupt handler. The initialization routine
checks for SMBus communications problems and sets
up the MAX1617 configuration and conversion rate. The
interrupt handler responds to ALERT signals by reading
the current temperature and setting a CPU clock duty
factor proportional to that temperature. The relationship
between clock duty and temperature is fixed in a lookup table contained in the microcontroller code.
Note: Thermal management decisions should be made
based on the latest temperature obtained from the
MAX1617 rather than the value of the Status Byte. The
MAX1617 has a very quick response to changes in its
environment due to its sensitivity and its small thermal
mass. High and low alarm conditions can exist in the
Status Byte due to the MAX1617 correctly reporting
environmental changes around it.
______________________________________________________________________________________
15
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
Listing 1. Pseudocode Example
16
______________________________________________________________________________________
Remote/Local Temperature Sensor
with SMBus Serial Interface
MAX1617
Listing 1. Pseudocode Example (continued)
______________________________________________________________________________________
17
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
Listing 1. Pseudocode Example (continued)
18
______________________________________________________________________________________
Remote/Local Temperature Sensor
with SMBus Serial Interface
QSOP.EPS
______________________________________________________________________________________
19
MAX1617
________________________________________________________Package Information
MAX1617
Remote/Local Temperature Sensor
with SMBus Serial Interface
NOTES
20
______________________________________________________________________________________