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Электронный компонент: W83L785R

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W83L785R
WINBOND H/W MONITORING IC FOR NOTEBOOK
1. GENERAL DESCRIPTION
W83L785R is a condensed product of W83L785R --- Winbond's most popular hardware monitoring IC
for notebook. Specifically designed for the graphic cards and notebook systems, W83L785R can be
used to monitor several critical hardware parameters of the system, including voltages, fan speeds,
and temperatures, which are very important for the system to work stably and properly.
An 8-bit analog-to-digital converter (ADC) was built inside W83L785R. The W83L785R can monitor 4
analog voltage inputs, 2 fan tachometer inputs, 2 remote temperature sensors. The remote
temperature sensing can be performed by thermistors, or 2N3904 NPN-type transistors, or connected
from Intel
TM
Deschutes CPU thermal diode output. The W83L785R provides 2 PWM (pulse width
modulation) outputs for the fan speed control. Also the W83L785R provides: SMI#, OVT#, Temp
fault, GPIO signals for system protection events; I
2
C
TM
serial bus interface. W83L785R also provides
4 pure GPIO and 7 multifunctional GPIO pins, and powered by 3.3V.
Through the application software or BIOS, the users can read all the monitored parameters of system
from time to time. And a pop-up warning can be also activated when the monitored item was out of
the proper/preset range. The application software could be Winbond's Hardware Doctor
TM
, or Intel
TM
LDCM (LanDesk Client Management), or other management application software. Also the users can
set up the upper and lower limits (alarm thresholds) of these monitored parameters and to activate
one programmable and maskable interrupts. For the spacing saving consideration of the Notebook
system, W83L785R is in the package of 209mil 20pins-SSOP.
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 2 - Revision 0.28web
2. FEATURES
2.1 Monitoring Items
2 thermal inputs from remote thermistors or 2N3904 NPN-type transistors or Pentium
TM
II
(Deschutes) thermal diode output
4 voltage inputs
--- typical for Vcore, +3.3V (Power), +2.5V, +1.5V
2 sets of PWM fan speed control
WATCHDOG comparison of all monitored values
Programmable hysteresis and setting points (alarm thresholds) for all monitored items
2.2 Actions Enabling
2 PWM (pulse width modulation) outputs for fan speed control
--- Total up to 2 sets of fan speed monitoring and controlling
Issue temperature fault signal as the temperature of the system/CPU exceeds its limit.
Issue SMI#, OVT#, GPIO and Temp. Fault signals to activate system protection
Warning signal pop-up in application software
2.3 General
I
2
C
TM
serial bus interface
Intel
TM
LDCM (DMI driver 2.0) support
Winbond hardware monitoring application software (Hardware Doctor
TM
) support, for both
Windows 95/98 and Windows NT 4.0/5.0
Meet WfM 2.0 (Wired for Management) spec.
3.3V VCC operation
2.4 Package
20-pin SSOP (209mil)
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 3 - Revision 0.28web
3. KEY SPECIFICATIONS
Voltage monitoring accuracy
1% (Max)
Monitoring Temperature Range and Accuracy
- 40
C to +120
C
3
C(Max)
Supply Voltage 2.7V ~ 5.5V
Operating Supply Current 2 mA typ.
Power Down Supply Current 20 uA typ.
ADC Resolution 8 Bits
4. PIN CONFIGURATION
20
19
18
17
16
15
1
2
3
4
5
6
7
8
9
10
SDA
13
14
12
11
VCC
CPUT1/PII1
VREF
+2.5VIN/GPIO14
CPUT2/PII2
GND
GPIO5
OVT#/GPIO8
SMI#/GPIO7
PWMOUT2
SCL
PWMOUT1
TEMP_FAULT/GPIO11
FANIN2/GPIO2
FANIN1/GPIO1
GPIO13
GPIO6
VCORE/GPIO16
+1.5V/GPIO15
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 4 - Revision 0.28web
5. PIN DESCRIPTION
I/O
12t
- TTL level bi-directional pin with 12 mA source-sink capability,open drain output
I/O
12ts
- TTL level and schmitt trigger
OUT
12
- Output pin with 12 mA source-sink capability
AOUT - Output pin(Analog)
OD
12
- Open-drain output pin with 12 mA sink capability
IN
t
- TTL level input pin
IN
ts
- TTL level input pin and schmitt trigger
AIN - Input pin(Analog)
PIN NAME
PIN NO.
TYPE
DESCRIPTION
FANIN1 /
GPIO1
1
IN
t s
/
I/OD
12ts
0V to +3.3V amplitude fan tachometer input.(Default) /
General purpose I/O function.
This multi-functional pin is programmable.
FANIN2 /
GPIO2
2
IN
t s
/
OUT
1 2
0V to +3.3V amplitude fan tachometer input. (Default) /
General purpose I/O function.
This multi-functional pin is programmable.
PWMOUT1
3
OD
12
Fan speed control PWM output. This pin is open-drain
PWMOUT2
4
OD
12
Fan speed control PWM output. This pin is open-drain
GPIO5
5
I/OD
12ts
General purpose I/O function.
GPIO6
6
I/OD
12ts
General purpose I/O function.
SMI#/
GPIO7
7
OD
12
I/OD
12ts
System Management Interrupt.
General purpose I/O function.
This multi-functional pin is programmable.
OVT#/
GPIO8
8
OD
12
I/OD
12ts
Over temperature Shutdown Output.
General purpose I/O function.
This multi-functional pin is programmable.
SCL
9
IN
t s
Serial Bus Clock.
SDA
10
I/OD
12
Serial Bus bi-directional Data.
TEMP_FAULT
GPIO11
11
OD
1 2
I/OD
12ts
Active-Low output. This pin will be a logic LOW when the
temperature of the system or CPU exceeds its limit. (Default) /
General purpose I/O function.
This multi-functional pin is programmable.
GND
12
Ground
Ground.
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 5 - Revision 0.28web
Pin Discription, continued
PIN NAME
PIN NO.
TYPE
DESCRIPTION
GPIO13
13
I/OD
12ts
General purpose I/O function. Default Open drain.
+2.5V/
GPIO14
14
AIN
I/OD
12ts
0V to 2.048V FSR Analog Inputs. (This pin is connected to the
+2.5V).
General purpose I/O function.
This multi-functional pin is programmable.
+1.5V/
GPIO15
15
AIN
I/OD
12ts
0V to 2.048V FSR Analog Inputs. (This pin is connected to the
+1.5V).
General purpose I/O function.
This multi-functional pin is programmable.
VCORE/
GPIO16
16
AIN
I/OD
12ts
0V to 2.048V FSR Analog Inputs. (This pin connected to
VCORE)
General purpose I/O function.
This multi-functional pin is programmable.
VREF
17
AOUT
Reference Voltage.
CPUT2 /
PII2
18
AIN
Thermistor terminal input.(Default) /
Pentium
TM
II diode input.
This multi-functional pin is programmable.
CPUT1 /
PII1
19
AIN
Thermistor terminal input.(Default) /
Pentium
TM
II diode input.
This multi-functional pin is programmable.
VCC
20
POWER
+3.3 VCC power supply input.
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 6 - Revision 0.28web
6. FUNCTIONAL DESCRIPTION
6.1 General Description
The W83L785R provides most 4 analog positive inputs, 2 fan speed monitors, 2 sets for fan
PWM (Pulse Width Modulation) control, 2 remote thermal inputs from remote thermistors or 2N3904
transistors or Pentium
TM
II (Deschutes) thermal diode outputs. W83L785R also provides software
power down this chip to save power, but I2C interface is still working. When W83L785 starts the
monitor function on the chip, the Watch Dog machine monitor every function and store the value to
registers. If the monitor value exceeds the limit value, the interrupt status will be set to 1.
6.2 Access Interface
The W83L785R provides I
2
C Serial Bus to read/write internal registers. In the W83L785R, the
I2C address defined value is 0101101.
6.2.1 The first serial bus access timing are shown as follow:
(a) Serial bus write to internal address register followed by the data byte
0
Start By
Master
0
1
0
1
1
0
1
D7
D6
D5
D4
D3
D2
D1
D0
Ack
by
785R
R/W
Ack
by
785R
SCL
SDA
D7
D6
D5
D4
D3
D2
D1
D0
Ack
by
784R
Stop
by
Master
SCL
SDA (Continued)
7
8
0
7
8
0
7
8
Frame 2
Internal Index Register Byte
(Continued)
Frame 3
Data Byte
Frame 1
Serial Bus Address Byte
Figure 1. Serial Bus Write to Internal Address Register followed by the Data Byte
Ack
by
785R
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 7 - Revision 0.28web
(b) Serial bus read form internal address register followed by the data byte
0
Start By
Master
0
1
0
1
1
0
1
D7
D6
D5
D4
D3
D2
D1
D0
Ack
by
785R
R/W
Ack
by
785R
SCL
SDA
D7
D6
D5
D4
D3
D2
D1
D0
Ack
by
784R
Stop by
Master
SCL
SDA (Continued)
7
8
0
7
8
Frame 2
Internal Index Register Byte
(Continued)
Frame 4
Data Byte
Frame 1
Serial Bus Address Byte
Figure 2. Serial Bus read from Internal Address Register followed by the Data Byte
0
1
2
3
4
5
6
7
8
0
1
3
4
5
2
6
7
1
0
1
1
0
0
1
R/W
8
ack
by
785R
Frame 3
Serial Bus Byte
ack
by
785R
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 8 - Revision 0.28web
6.3 Analog Inputs
The maximum input voltage of the analog pin is 2.048V because the 8-bit ADC has the 8mv LSB.
Actually, the application of the voltage monitoring would most often be connected to power suppliers.
The +1.5V voltage can directly connected to these analog inputs. The +2.5V and CPU VOCRE, the
inputs higher than 2.048V, should be reduced a factor with external resistors so as to obtain the input
range. As Figure 3 shows.
VIN0(VCORE)(Max2.048V)
+1.5V
Pin 15
Pin 14
Pin 20
VCC
R1
+2.5Vin
8-bit ADC
with
8mV LSB
Typical Thermister
Connection
100K, 1%
RTHM
Pin 17
CPUT1
Pin 19
Positive Inputs
10K, 25 C
**The connections of CPUT2
is same as CPUT1
R2
R
Pin 16
VREF
10K, 1%
200K, 1%
VIN1(Max2.048V)
VIN2
VIN3
Figure. 3.
6.3.1 Voltage Monitor input can not be over 2.048V :
The input voltage VIN1 or Vcore can be expressed as following equation:
2
1
2
5
.
2
1
R
R
R
V
VIN
V
+
=
+
. V
+2.5V
is +2.5V inputs.
The value of R1 and R2 can be selected to 100K Ohms and 200K Ohms, respectively, when the input
voltage is 2.5V. The node voltage of VIN3 can be subject to less than 2.048V for the maximum input
range of the 8-bit ADC. The pin 20 is connected to the power supply VCC with +3.3V. There are two
functions in this pin with 3.3V. The first function is to supply internal analog power of the W83L785R
and the second function is that this voltage with 3.3V is connected to internal serial resistors to
monitor the +3.3V voltage. The value of two serial resistors are 20K ohms and 40K ohms so that
input voltage to ADC is 1.1V which is less than 2.048V of ADC maximum input voltage. The express
equation can represent as follows.
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 9 - Revision 0.28web
V
K
K
K
VCC
V
in
1
.
1
40
20
20
+
=
where VCC is set to 3.3V.
6.4 Temperature Measurement Machine
The temperature data format is 8-bit two-complement for thermal sensor. The 8-bit temperature data
can be obtained by reading the CR[26h] or CR[27h]. The format of the temperature data is show in
Table 1.
Temperature
8-Bit Digital Output
8-Bit Binary
8-Bit Hex
+125
C
0111,1101
7Dh
+25
C
0001,1001
19h
+2
C
0000,0010
02h
+1
C
0000,0001
01h
+0
C
0000,0000
00h
-1
C
1111,1111
FFh
-2
C
1111,1110
FEh
-25
C
1110,0111
E7h
-55
C
1100,1001
C9h
Table 1.
6.4.1 Monitor temperature from thermistor:
The W83L785R can connect two thermistors to measure three different environment temperature or
remote temperature. The specification of thermistor should be considered to (1)
value is 3435K, (2)
resistor value is 10K ohms at 25
C. In the Figure 3, the themistor is connected by a serial resistor with
10K Ohms, then connect to VREF (pin 17).
6.4.2 Monitor temperature from Pentium II
TM
thermal diode or bipolar transistor 2N3904
The W83L785R can alternate the thermistor to Pentium II
TM
(Deschutes) thermal diode interface or
transistor 2N3904 and the circuit connection is shown as Figure 4. The pin of Pentium II
TM
D- is
connected to power supply ground (GND) and the pin D+ is connected to pin PIIx in the W83L785R.
The resistor R=15K ohms should be connected to VREF to supply the diode bias current and the
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 10 - Revision 0.28web
bypass capacitor C=3300pF should be added to filter the high frequency noise. The transistor 2N3904
should be connected to a form with a diode, that is, the Base (B) and Collector (C) in the 2N3904
should be tied together to act as a thermal diode.
2N3904
C
E
B
R=15K, 1%
C=3300pF
Bipolar Transistor
Temperature Sensor
Pentium II
CPU
D+
D-
Therminal
Diode
C=3300pF
R=30K, 1%
VREF
PIITDx
PIITDx
OR
W83L785R
Figure 4.
6.4.3 Over Temperature signal (OVT#)
W83L785R provides two external thermal sensors to detect temperature. When detected
temperature exceeds the over-temperature value, pin OVT# will be asserted until the
temperature goes below the hysteresis temperature. Pin OVT# has 2 operating modes:
6.4.3.1 Comparator Mode :
At this mode, temperature exceeding T
O
causes the OVT# output activated until the temperature
is less than T
HYST
. ( Figure 5)
6.4.3.2 Interrupt Mode:
At this mode, temperature exceeding T
O
causes the OVT# output activated indefinitely until reset
by reading interrupt status register. Temperature exceeding T
O
, then OVT# asserted, and then
temperature going below T
HYST
will also cause the OVT# activated indefinitely until reset by
reading temperature sensor1 or sensor2 registers. Once the OVT# is activated by exceeding T
O
,
then reset, if the temperature remains above T
HYST
, the OVT# will not be activated
again.( Figure 5)
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 11 - Revision 0.28web
T
HYST
*
*
*
*Interrupt Reset when Interrupt Status Register is read
OVT#
OVT#
*
(Comparator Mode; default)
(Interrupt Mode)
To
Figure 5.
6.4.4 Temperature Fault (Temp_fault #)
W83L785R provides a good protection for temperature. Set pin11(TEMP_FAULT#) to
monitor temperature and enable TEMP_FAULT# function. When VTIN1(Pin19) or VTIN(Pin18)
temperature exceeds Temperature fault limit in CR53,or R54 pin11 TEMP_FAULT# will be
asserted(Figure 6).
Figure 6. TEMP_FAULT
TEMP_FAULT limit
TEMP_FAULT#
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 12 - Revision 0.28web
6.5 FAN Speed Count and FAN Speed Control
6.5.1 Fan speed count
Inputs are provided by the signals from fans equipped with tachometer outputs. The level of these
signals should be set to TTL level, and maximum input voltage cannot be over VCC. If the input
signals from the tachometer outputs are over the VCC, the external trimming circuit should be added
to reduce the voltage to obtain the input specification. The normal circuit and trimming circuits are
shown as Figure 7.
Determine the fan counter according to:
Count
RPM Divisor
=
1 35 10
6
.
In other words, the fan speed counter has been read from register CR28 or CR29, the fan speed can
be evaluated by the following equation.
RPM
Count
Divisor
=
1 35
10
6
.
The default divisor is 2 and defined at CR47.bit0~2, bit4~6 which are three bits for divisor. That
provides very low speed fan counter such as power supply fan. The followed table is an example for
the relation of divisor, RPM, and count.
Divisor
Nominal
RPM
Time per
Revolution
Counts
70% RPM
Time for 70%
1
8800
6.82 ms
153
6160
9.74 ms
2 (default)
4400
13.64 ms
153
3080
19.48 ms
4
2200
27.27 ms
153
1540
38.96 ms
8
1100
54.54 ms
153
770
77.92 ms
16
550
109.08 ms
153
385
155.84 ms
32
275
218.16 ms
153
192
311.68 ms
64
137
436.32 ms
153
96
623.36 ms
128
68
872.64 ms
153
48
1246.72 ms
Table 2.
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 13 - Revision 0.28web
FAN Out
+12V
GND
Pull-up resister
4.7K Ohms
+12V
Fan Input
Pin 1
Pin 2
W83L785R
22K~30K
10K
FAN
Connector
FAN Out
+12V
GND
Pull-up resister < 1K
or totem-pole output
+12V
Fan Input
Pin 1
Pin 2
W83L785R
> 1K
Figure 7-2. Fan with Tach Pull-Up to +12V, or
Totem-Pole Putput and Zener Clamp
3.3V Zener
Figure 7-1. Fan with Tach Pull-Up to +12V, or Totern-Pole
Output and Register Attenuator
FAN Out
+5V
GND
Pull-up resister
4.7K Ohms
+5V
Fan Input
Pin 1
Pin 2
W83L785R
1K~2.7K
10K
FAN
Connector
FAN Out
+5V
GND
Pull-up resister < 1K
or totem-pole output
+5V
Fan Input
Pin 1
Pin 2
W83L785R
> 1K
Figure 7-4. Fan with Tach Pull-Up to +5V, or
Totem-Pole Putput and Zener Clamp
3.3V Zener
Figure 7-3. Fan with Tach Pull-Up to +5V, or Totern-Pole
Output and Register Attenuator
6.5.2 Fan speed control
The W83L785R provides four sets for fan PWM speed control. The duty cycle of PWM can be
programmed by a 8-bit register which are defined in the CR81h and CR83h. The default duty cycle is
set to 100%, that is, the default 8-bit registers is set to FFh. The expression of duty can be
represented as follows.
Duty
cycle
Programmed 8 - bit Register Value
255
-
=
(%)
100%
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 14 - Revision 0.28web
+12V
FAN
R1
R2
NMOS
PNP Transistor
C
+
-
PWM Clock Input
D
S
G
+5V
FAN
R1
R2
NMOS
PNP Transistor
C
+
-
PWM Clock Input
D
S
G
Figure 8.
6.6 SMI#
6.6.1 Temperature
Pin SMI# for temperature has 3 modes.
6.6.1.1 Comparator Interrupt Mode
Temperature exceeding T
O
causes an interrupt and this interrupt will be reset when reading all of
the Interrupt Status Registers. Once an interrupt event has occurred by exceeding T
O
, then reset,
if the temperature remains above the T
HYST
, the interrupt will occur again when the next
conversion has completed. If an interrupt event has occurred by exceeding T
O
and not reset, the
interrupts will not occur again. The interrupts will continue to occur in this manner until the
temperature goes below T
HYST
. (Figure 9-1)
6.6.1.2 Two-Times Interrupt Mode
Temperature exceeding T
O
causes an interrupt and then temperature going below T
HYST
will also
cause an interrupt if the previous interrupt has been reset by reading all the interrupt Status
Register. Once an interrupt event has occurred by exceeding T
O
, then reset, if the temperature
remains above the T
HYST
, the interrupt will not occur. (Figure 9-2 )
6.6.1.3 One-Time Interrupt Mode
Temperature exceeding T
O
causes an interrupt and then temperature going below T
HYST
will not
cause an interrupt. Once an interrupt event has occurred by exceeding T
O
, then going below
T
HYST,
an interrupt will not occur again until the temperature exceeding T
O
. (Figure 9-3)
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 15 - Revision 0.28web
T
OI
T
HYST
*
*
*
Figure 9-1. Comparator Interrupt Mode
*Interrupt Reset when Interrupt Status Registers are read
T
OI
T
HYST
Figure 9-2. Two-Times Interrupt Mode
SMI#
SMI#
*
*
*
*
*
*Interrupt Reset when Interrupt Status Registers are read
T
OI
T
HYST
Figure 9-3. One-Time Interrupt Mode
SMI#
*
*
6.6.2 Voltage
SMI# interrupt for voltage is Two-Times Interrupt Mode. Voltage exceeding high limit or going
below low limit will causes an interrupt if the previous interrupt has been reset by reading all the
interrupt Status Register. (Figure 10-1)
6.6.3 Fan
SMI# interrupt for fan is Two-Times Interrupt Mode. Fan count exceeding the limit, or exceeding
and then going below the limit (set at value ram index 3Bh and 3Ch), will causes an interrupt if
the previous interrupt has been reset by reading all the interrupt Status Register. (Figure 10-2)
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 16 - Revision 0.28web
*
*
*
Figure 10-1. Voltage SMI# Mode
*Interrupt Reset when Interrupt Status Registers are read
Figure 10-2. Fan SMI# Mode
SMI#
*
Voltage High limit
Voltage Low limit
*
SMI#
*
Fan Count limit
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 17 - Revision 0.28web
7. SPECIFICATIONS
7.1 Absolute Maximum Ratings
PARAMETER
RATING
UNIT
Power Supply Voltage
-0.5 to 7.0
V
Input Voltage
-0.5 to V
CC
+0.5
V
Operating Temperature
0 to +70
C
Storage Temperature
-55 to +150
C
Note: Exposure to conditions beyond those listed under Absolute Maximum Ratings may adversely affect the life and reliability of the
device.
7.2 DC Characteristics
(Ta = 0
C to 70
C, V
DD
= 5V
10%, V
SS
= 0V)
PARAMETER
SYM. MIN. TYP. MAX. UNIT
CONDITIONS
I/O
12t
- TTL level bi-directional pin with source-sink capability of 12 mA
Input Low Voltage
V
IL
0.8
V
Input High Voltage
V
IH
2.0
V
Output Low Voltage
V
OL
0.4
V
I
OL
= 12 mA
Output High Voltage
V
OH
2.4
V
I
OH
= - 12 mA
Input High Leakage
I
LIH
+10
A
V
IN
= V
DD
Input Low Leakage
I
LIL
-10
A
V
IN
= 0V
I/O
12ts
- TTL level bi-directional pin with source-sink capability of 12 mA and schmitt-trigger level
input
Input Low Threshold Voltage
V
t-
0.5
0.8
1.1
V
V
DD
= 5 V
Input High Threshold Voltage
V
t+
1.6
2.0
2.4
V
V
DD
= 5 V
Hysteresis
V
TH
0.5
1.2
V
V
DD
= 5 V
Output Low Voltage
V
OL
0.4
V
I
OL
= 12 mA
Output High Voltage
V
OH
2.4
V
I
OH
= - 12 mA
Input High Leakage
I
LIH
+10
A
V
IN
= V
DD
Input Low Leakage
I
LIL
-10
A
V
IN
= 0V
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 18 - Revision 0.28web
11.2 DC Characteristics, continued
PARAMETER
SYM.
MIN.
TYP.
MAX.
UNIT
CONDITIONS
OUT
12t
- TTL level output pin with source-sink capability of 12 mA
Output Low Voltage
V
OL
0.4
V
I
OL
= 12 mA
Output High Voltage
V
OH
2.4
V
I
OH
= -12 mA
OD
8
- Open-drain output pin with sink capability of 8 mA
Output Low Voltage
V
OL
0.4
V
I
OL
= 8 mA
OD
12
- Open-drain output pin with sink capability of 12 mA
Output Low Voltage
V
OL
0.4
V
I
OL
= 12 mA
OD
48
- Open-drain output pin with sink capability of 48 mA
Output Low Voltage
V
OL
0.4
V
I
OL
= 48 mA
IN
t
- TTL level input pin
Input Low Voltage
V
IL
0.8
V
Input High Voltage
V
IH
2.0
V
Input High Leakage
I
LIH
+10
A
V
IN
= V
DD
Input Low Leakage
I
LIL
-10
A
V
IN
= 0 V
IN
ts
- TTL level Schmitt-triggered input pin
Input Low Threshold Voltage
V
t-
0.5
0.8
1.1
V
V
CC
= 5 V
Input High Threshold Voltage
V
t+
1.6
2.0
2.4
V
V
CC
= 5 V
Hysteresis
V
TH
0.5
1.2
V
V
CC
= 5 V
Input High Leakage
I
LIH
+10
A
V
IN
= V
CC
Input Low Leakage
I
LIL
-10
A
V
IN
= 0 V
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 19 - Revision 0.28web
7.3 AC Characteristics
VALID DATA
SCL
SDA IN
SDA OUT
t HD;SDA
t
SCL
t
HD;DAT
t
SU;STO
t
SU;DAT
Serial Bus Timing Diagram
Serial Bus Timing
PARAMETER
SYMBOL
MIN.
MAX.
UNIT
SCL clock period
t
-
SCL
10
uS
Start condition hold time
t
HD;SDA
4.7
uS
Stop condition setup-up time
t
SU;STO
4.7
uS
DATA to SCL setup time
t
SU;DAT
120
nS
DATA to SCL hold time
t
HD;DAT
5
nS
SCL and SDA rise time
t
R
1.0
uS
SCL and SDA fall time
t
F
300
nS
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 20 - Revision 0.28web
8. HOW TO READ THE TOP MARKING
The top marking of W83L785R
W83L785R
046OA
2826978Y
Left: Winbond logo
1st line: Type number W83L785R, R means SSOP (Thickness = 209mil).
2nd line: Tracking code 2 826978Y
2: wafers manufactured in Winbond FAB 2
826978Y: wafer production series lot number
3rd line: Tracking code 046 A A
046: packages made in 2000, week 46
O: assembly house ID; A means ASE, O means OSE, G means Greatek
A: IC revision; A means version A, B means version B
W83L785R
Preliminary
Publication Release Date: Apr. 2001
- 21 - Revision 0.28web
9. PACKAGE DRAWING AND DIMENSIONS
20 SSOP-209 mil
1
2
D
E
e
Y
b
A1
A2 A
SEATING PLANE
DTEAIL A
L
L1
DETAIL A
SEATING PLANE
E
H
10
11
0
0.002
0.197
0.291
7.80
0
7.40
8
8.20
5.30
b
E
D
c
10.05
5.00
A1
A2
A
5.60
10.35
10.20
2.00
1.85
8
0.323
0.307
0.073
0.079
0.220
0.395
0.407
0.401
0.209
MIN.
DIMENSION IN INCH
SYMBOL
DIMENSION IN MM
MIN.
NOM
MAX.
MAX.
NOM
0.05
e
L
L1
Y
0.009
0.015
0.004
0.008
0.021
0.030
0.050
0.004
0.22
0.38
0.09
0.21
0.65
0.0256
0.55
0.75
1.25
0.10
H
E
0.95
0.037
1.75
1.65
0.065
0.069
Headquarters
No. 4, Creation Rd. III
Science-Based Industrial Park
Hsinchu, Taiwan
TEL: 886-35-770066
FAX: 886-35-789467
www: http://www.winbond.com.tw/
Taipei Office
11F, No. 115, Sec. 3, Min-Sheng East Rd.
Taipei, Taiwan
TEL: 886-2-7190505
FAX: 886-2-7197502
TLX: 16485 WINTPE
Winbond Electronics (H.K.) Ltd.
Rm. 803, World Trade Square, Tower II
123 Hoi Bun Rd., Kwun Tong
Kowloon, Hong Kong
TEL: 852-27516023-7
FAX: 852-27552064
Winbond Electronics
(North America) Corp.
2730 Orchard Parkway
San Jose, CA 95134 U.S.A.
TEL: 1-408-9436666
FAX: 1-408-9436668
Please note that all data and specifications are subject to change without
notice. All the trade marks of products and companies mentioned in this data
sheet belong to their respective owners
.
These products are not designed for use in life support appliances, devices,
or systems where malfunction of these products can reasonably be expected
to result in personal injury. Winbond customers using or selling these
products for use in such applications do so at their own risk and agree to fully
indemnify Winbond for any damages resulting from such improper use or sale.
10.
W83L785R SCHEMATICS
785.SCH
0.1
W83L785R Application Circuit
Custom
1
1
Friday, March 30, 2001
Title
Size
Document Number
Rev
Date:
Sheet
of
CPU_VCORE
1.5V
VCC
VCC
VCC
VCC
VCC
VCC
2.5V
VCC
+12V
+12V
VCC
VCC
Fan5VCC
VCC
Fan5VCC
V1
V2
VREF
VREF
SDA
GP5
GP6
OVT#
SCL
GP13
SMI#
VTIN2
SDA
PWMOUT2
FANIN2
FANIN1
PWMOUT1
V1
GP13
VTIN1
VREF
VTIN1
VTIN2
V2
V3
V3
SCL
PWMOUT1
FANIN1
PWMOUT2
PWMOUT2
FANIN1
PWMOUT1
FANIN2
FANIN2
R16
R
10K
R18
100k
R17
10K
R34
R
10K 1%
R29
R
30K 1%
T
RT1
THERMISTOR
10K 1%
C4
CAP
3300p
R38
4.7k
R39
4.7k
R40
0
WINBOND ELECTRONICS CORP.
R19
200k
R44
1K
R45
1K
R46
1K
R1
4.7K
R11
10K
R14
4.7K
C2
0.1u
U1
W83785R
1
2
3
4
5
6
7
8
9
10
20
19
18
17
16
15
14
13
12
11
FANIN1/GPIO1
FANIN2/GPIO2
PWMOUT1
PWMOUT2
GPIO5
GPIO6
SMI#/GPIO7
OVT#/GPIO8
SCL
SDA
VCC
VTIN1
VTIN2
VREF
VCORE/GPIO16
+1.5V/GPIO15
+2.5V/GPIO14
GPIO13
GND
TEMP_FAULT#/GPO11
C1
10u/16V
R2
4.7K
R13
4.7K
R41
0
R28
10K
R24
4.7K
JP1
HEADER 3
1
2
3
Q1
3906
R22
1K
D1
1N4148
+
C3
47u
R37
10K
R33
4.7K
JP2
HEADER 3
1
2
3
Q3
3906
R32
1K
R30
4.7K
D2
1N4148
+
C5
47u
R35
100
R27
27K
R36
27K
R21
4.7K
R31
4.7K
Q4
MOSFET N
Q2
MOSFET N
R26
100
R20
4.7K
R24
4.7K
+
C5
47u
Q1
3906
JP2
HEADER 3
1
2
3
D2
1N4148
R27
2K
Q4
MOSFET N
R37
10K
R30
4.7K
R21
4.7K
R20
4.7K
JP1
HEADER 3
1
2
3
R28
10K
R22
1K
R35
100
R26
100
+
C3
47u
R33
4.7K
R31
4.7K
Q2
MOSFET N
R32
1K
R36
2K
D1
1N4148
Q3
3906
PIID-
PIID+
SMDAT
TEMP_FAULT#
GPIO6
THRM#
GPIO5
EXTSMI#
SMCLK
VOLTAGE SENSORING CIRCUIT
Rev.
0.1:W83L785R application circuit. 3.3VCC
{
From PII/PIII CPU
TEMPERATURE SENSORING CIRCUIT
NOTE:
ALL GPIO PIN Must add pull-up resistor
To chipset
}
(max 2.048V)
PWM1 Circuit for FAN1 speed Control
PWM2 Circuit for FAN2 speed Control
Signal
Power
GND
Signal
Power
GND
PWMOUT1 is
open-drain default.
PWMOUT2 is
open-drain default.
W83784R has SMARTFAN function
W83784R has SMARTFAN function
W83784R has SMARTFAN function
open-drain default.
PWMOUT1 is
Signal
Signal
PWMOUT2 is
GND
GND
PWM2 Circuit for FAN2 speed Control
W83784R has SMARTFAN function
open-drain default.
Power
Power
PWM1 Circuit for FAN1 speed Control
FOR 5V FAN
FOR 5V FAN
FOR 12V FAN
FOR 12V FAN