TC646EUATR

更新时间:2024-12-03 13:10:50
品牌:MICROCHIP
描述:BRUSHLESS DC MOTOR CONTROLLER

TC646EUATR 概述

BRUSHLESS DC MOTOR CONTROLLER 运动控制电子器件

TC646EUATR 规格参数

生命周期:Active包装说明:,
Reach Compliance Code:compliantHTS代码:8542.39.00.01
风险等级:5.59模拟集成电路 - 其他类型:BRUSHLESS DC MOTOR CONTROLLER
Base Number Matches:1

TC646EUATR 数据手册

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TC646  
M
PWM Fan Speed Controller with Auto-Shutdown  
and FanSenseTechnology  
Features  
Package Types  
Temperature Proportional Fan Speed for Acoustic  
Control and Longer Fan Life  
SOIC/PDIP/MSOP  
• Efficient PWM Fan Drive  
• 3.0V to 5.5V Supply Range:  
- Fan Voltage Independent of TC646  
Supply Voltage  
V
V
V
1
2
3
4
8
7
6
5
IN  
DD  
C
OUT  
F
TC646  
V
FAULT  
SENSE  
AS  
GND  
- Supports any Fan Voltage  
• FanSense™ Fault Detection Circuits Protect  
Against Fan Failure and Aid System Testing  
General Description  
• Shutdown Mode for "Green" Systems  
• Supports Low Cost NTC/PTC Thermistors  
• Space Saving 8-Pin MSOP Package  
• Over-temperature Indication  
The TC646 is a switch mode, fan speed controller for  
use with brushless DC fans. Temperature proportional  
speed control is accomplished using pulse width mod-  
ulation (PWM). A thermistor (or other voltage output  
temperature sensor) connected to the V input fur-  
IN  
Applications  
• Power Supplies  
• Computers  
• File Servers  
• Portable Computers  
Telecom Equipment  
• UPS, Power Amps  
• General Purpose Fan Speed Control  
nishes the required control voltage of 1.25V to 2.65V  
(typical) for 0% to 100% PWM duty cycle. The TC646  
automatically suspends fan operation when measured  
temperature (V ) is below a user programmed  
IN  
minimum setting (V ). An integrated Start-up Timer  
AS  
ensures reliable motor start-up at turn-on, coming out  
of shutdown mode, auto-shutdown mode or following a  
transient fault.  
The TC646 features Microchip Technology's propri-  
etary FanSense™ technology for increasing system  
reliability. In normal fan operation, a pulse train is  
present at SENSE (Pin 5). A missing-pulse detector  
monitors this pin during fan operation. A stalled, open,  
or unconnected fan causes the TC646 to trigger its  
Start-up Timer once. If the fault persists, the FAULT  
output goes low and the device is latched in its shut-  
down mode. FAULT is also asserted if the PWM  
reaches 100% duty cycle, indicating a possible thermal  
runaway situation, although the fan continues to run.  
See Section 5.0, “Typical Applications”, for more  
information and system design guidelines.  
Available Tools  
• Fan Controller Demonstration Board (TC642DEMO)  
• Fan Controller Evaluation Kit (TC642EV)  
The TC646 is available in the 8-pin plastic DIP, SOIC  
and MSOP packages and is available in the industrial  
and extended commercial temperature ranges.  
2002 Microchip Technology Inc.  
DS21446C-page 1  
TC646  
Functional Block Diagram  
V
IN  
+
V
DD  
V
OTF  
OTF  
+
PWM  
Control  
Logic  
V
OUT  
C
F
3 x T  
PWM  
Timer  
Clock  
Generator  
FAULT  
Start-up  
Timer  
V
AS  
+
SHDN  
Missing  
Pulse  
Detect.  
+
+
TC646  
V
SHDN  
SENSE  
10kΩ  
GND  
70mV (typ.)  
DS21446C-page 2  
2002 Microchip Technology Inc.  
TC646  
*Stresses above those listed under "Absolute Maximum Rat-  
ings" may cause permanent damage to the device. These are  
stress ratings only and functional operation of the device at  
these or any other conditions above those indicated in the  
operation sections of the specifications is not implied. Expo-  
sure to absolute maximum rating conditions for extended peri-  
ods may affect device reliability.  
1.0  
ELECTRICAL  
CHARACTERISTICS  
Absolute Maximum Ratings*  
Supply Voltage ......................................................... 6V  
Input Voltage, Any Pin..... (GND – 0.3V) to (V +0.3V)  
DD  
Package Thermal Resistance:  
PDIP (R ).............................................125°C/W  
θJA  
SOIC (R ) ............................................155°C/W  
θJA  
MSOP (R ) ..........................................200°C/W  
θJA  
Specified Temperature Range ........... -40°C to +125°C  
Storage Temperature Range.............. -65°C to +150°C  
DC ELECTRICAL SPECIFICATIONS  
Electrical Characteristics: Unless otherwise specified, TMIN TA TMAX, VDD = 3.0V to 5.5V  
Symbol  
VDD  
IDD  
Parameter  
Supply Voltage  
Supply Current, Operating  
Min  
Typ  
Max  
Units  
Test Conditions  
3.0  
0.5  
5.5  
1.0  
V
mA Pins 6, 7 Open,  
CF = 1 µF, VIN = VC(MAX)  
IDD(SHDN)  
Supply Current, Shutdown/  
Auto-shutdown Mode  
25  
µA Pins 6, 7 Open;  
Note 1  
CF =1 µF, VIN = 0.35V  
µA Note 1  
IIN  
VIN, VAS Input Leakage  
-1.0  
+1.0  
VOUT Output  
tR  
tF  
tSHDN  
VOUT Rise Time  
VOUT Fall Time  
Pulse Width(On VIN) to Clear  
Fault Mode  
30  
50  
50  
µsec IOH = 5 mA, Note 1  
µsec IOL = 1 mA, Note 1  
µsec VSHDN, VHYST  
Specifications,  
Note 1  
IOL  
IOH  
Sink Current at VOUT Output  
Source Current at VOUT  
Output  
1.0  
5.0  
mA VOL = 10% of VDD  
mA VOH = 80% of VDD  
SENSE Input  
VTH(SENSE)  
SENSE Input Threshold  
Voltage with Respect to GND  
50  
70  
90  
mV Note 1  
FAULT Output  
VOL  
tMP  
tSTARTUP  
tDIAG  
Output Low Voltage  
Missing Pulse Detector Timer  
Start-up Timer  
0.3  
V
IOL = 2.5 mA  
32/F  
32/F  
3/F  
Sec CF = 1.0 µF  
Sec CF = 1.0 µF  
Sec CF = 1.0 µF  
Diagnostic Timer  
Note 1: Ensured by design, not tested.  
2002 Microchip Technology Inc.  
DS21446C-page 3  
TC646  
DC ELECTRICAL SPECIFICATIONS (CONTINUED)  
Electrical Characteristics: Unless otherwise specified, TMIN TA TMAX, VDD = 3.0V to 5.5V  
Symbol  
Parameter  
Min  
Typ  
Max  
Units  
Test Conditions  
VIN, VAS Inputs  
VC(MAX),VOTF Voltage at VIN for 100% Duty  
Cycle and Overtemp. Fault  
2.5  
1.3  
VC(MAX) ~  
VC(SPAN)  
2.65  
2.8  
V
VC(SPAN)  
VAS  
VC(MAX) - VC(MIN)  
Auto-shutdown Threshold  
1.4  
1.5  
VC(MAX)  
V
V
VSHDN  
VREL  
Voltage Applied to VIN to  
ensure Reset/Shutdown  
Voltage Applied to VIN to  
Release Reset Mode  
VDD x 0.13  
V
V
VDD x 0.19  
VDD = 5V,  
See Figure 5-11  
VHYST  
VHAS  
Hysteresis on VSHDN, VREL  
Hysteresis on Auto-shutdown  
Comparator  
0.01 x VDD  
70  
V
mV  
Pulse Width Modulator  
FOSC  
PWM Frequency  
26  
30  
34  
Hz CF = 1.0 µF  
Note 1: Ensured by design, not tested.  
DS21446C-page 4  
2002 Microchip Technology Inc.  
TC646  
2.3  
Analog Input (V  
)
2.0  
PIN DESCRIPTIONS  
AS  
An external resistor divider connected to the V input  
The descriptions of the pins are listed in Table 2-1.  
AS  
sets the auto-shutdown threshold. Auto-shutdown  
occurs when V V . The fan is automatically  
IN  
AS  
TABLE 2-1:  
Pin No. Symbol  
PIN FUNCTION TABLE  
Description  
V Analog Input  
IN  
restarted when V (V + V ) (see Section 5.0,  
HAS  
IN  
AS  
“Typical Applications”, for more details).  
1
2
3
4
5
6
7
8
2.4  
Ground (GND)  
C
Analog Output  
Analog Input  
F
GND denotes the ground terminal.  
V
AS  
GND  
Ground Terminal  
2.5  
Analog Input (SENSE)  
SENSE Analog Input  
FAULT Digital (Open Collector) Output  
Pulses are detected at the SENSE pin as fan rotation  
chops the current through a sense resistor (R ).  
SENSE  
V
Digital Output  
OUT  
The absence of pulses indicates  
a fault (see  
V
Power Supply Input  
Section 5.0, “Typical Applications”, for more details).  
DD  
2.1  
Analog Input (V )  
2.6  
Digital Output (FAULT)  
IN  
The thermistor network (or other temperature sensor)  
The FAULT line goes low to indicate a fault condition.  
When FAULT goes low due to a fan fault condition, the  
device is latched in shutdown mode until deliberately  
cleared or until power is cycled. FAULT will also be  
asserted when the PWM reaches 100% duty cycle,  
indicating that maximum cooling capability has been  
reached and a possible over-temperature condition  
may occur. This is a non-latching state and the FAULT  
output will go high when the PWM duty cycle goes  
below 100%.  
connects to the V input. A voltage range of 1.25V to  
IN  
2.65V (typical) on this pin drives an active duty cycle of  
0% to 100% on the V  
pin. The TC646 enters shut-  
OUT  
down mode when V V  
. During shutdown, the  
SHDN  
IN  
FAULT output is inactive, and supply current falls to  
25 µA (typical). The TC646 exits shutdown mode  
when V V  
(see Section 5.0, “Typical  
REL  
IN  
Applications”, for details).  
2.2  
Analog Output (C )  
F
2.7  
Digital Output (V  
)
OUT  
is an active high complimentary output that drives  
C is the positive terminal for the PWM ramp generator  
F
V
timing capacitor. The recommended C is 1 µF for  
F
OUT  
30 Hz PWM operation.  
the base of an external NPN transistor (via an appropri-  
ate base resistor) or the gate of an N-channel MOS-  
FET. This output has asymmetrical drive (see  
Section 1.0, “Electrical Characteristics”).  
2.8  
Power Supply Input (V  
)
DD  
may be independent of the fan’s power supply  
V
DD  
(see Section 1.0, “Electrical Characteristics”).  
2002 Microchip Technology Inc.  
DS21446C-page 5  
TC646  
3.5  
FAULT Output  
3.0  
DETAILED DESCRIPTION  
The TC646 detects faults in two ways:  
3.1  
PWM  
First, pulses appearing at SENSE due to the PWM  
turning on are blanked, with the remaining pulses being  
filtered by a missing pulse detector. If consecutive  
pulses are not detected for thirty-two PWM cycles  
The PWM circuit consists of a ramp generator and  
threshold detector. The frequency of the PWM is  
determined by the value of the capacitor connected to  
the C input. A frequency of 30 Hz is recommended  
F
( 1 Sec if C = 1 µF), the Diagnostic Timer is activated  
F
(C = 1 µF). The PWM is also the time base for the  
F
and V  
is driven high continuously for three PWM  
OUT  
Start-up Timer (see Section 3.3, “Start-Up Timer”). The  
PWM voltage control range is 1.25V to 2.65V (typical)  
for 0% to 100% output duty cycle.  
cycles ( 100 msec if C = 1 µF). If a pulse is not  
F
detected within this window, the Start-up Timer is trig-  
gered (see Section 3.3, “Start-up Timer”). This should  
clear a transient fault condition. If the missing pulse  
detector times out again, the PWM is stopped and  
FAULT goes low. When FAULT is activated due to this  
condition, the device is latched in shutdown mode and  
will remain off indefinitely. Therefore, the TC646 is pre-  
vented from attempting to drive a fan under cata-  
strophic fault conditions.  
3.2  
The V  
VOUT Output  
pin is designed to drive a low cost transistor  
OUT  
or MOSFET as the low side, power switching element  
in the system. Various examples of driver circuits will be  
shown throughout this data sheet. This output has  
asymmetric complementary drive and is optimized for  
driving NPN transistors or N-channel MOSFETs. Since  
the system relies on PWM rather than linear control,  
the power dissipation in the power switch is kept to a  
minimum. Generally, very small devices (TO-92 or SOT  
packages) will suffice.  
One of two things will restore operation: Cycling power  
off and then on again or pulling V below V  
and  
SHDN  
IN  
releasing it to a level above V  
. When one of these  
REL  
two conditions is satisfied, the normal start-up cycle is  
triggered and operation will resume if the fault has been  
cleared.  
3.3  
Start-Up Timer  
The second condition by which the TC646 asserts a  
FAULT is when the PWM control voltage applied to V  
To ensure reliable fan start-up, the Start-up Timer turns  
IN  
becomes greater than that needed to drive 100% duty  
cycle (see Section 1.0, “Electrical Characteristics”).  
This indicates that the fan is at maximum drive and the  
potential exists for system overheating. Either heat dis-  
sipation in the system has gone beyond the cooling  
system’s design limits or some subtle fault exists (such  
as fan bearing failure or an airflow obstruction). This  
output may be treated as a “System Overheat” warning  
and be used to trigger system shutdown or some other  
corrective action.  
the V  
output on for 32 cycles of the PWM whenever  
OUT  
the fan is started from the off state. This occurs at  
power-up and when coming out of shutdown or auto-  
shutdown mode. If the PWM frequency is 30 Hz  
(C = 1 µF), the resulting start-up time will be approxi-  
F
mately one second. If a fan fault is detected, the Diag-  
nostic Timer is triggered once, followed by the Start-up  
Timer. If the fault persists, the device is shut down (see  
Section 3.5, “FAULT Output”).  
3.4  
SENSE Input  
However, in this case, the fan will continue to run even  
(FanSenseTechnology)  
when FAULT is asserted. If the system is allowed to  
continue operation, and the temperature (and thus V )  
IN  
IN  
The SENSE input (Pin 5) is connected to a low value  
current sensing resistor in the ground return leg of the  
fan circuit. During normal fan operation, commutation  
occurs as each pole of the fan is energized. This  
causes brief interruptions in the fan current, seen as  
pulses across the sense resistor. If the device is not in  
auto-shutdown or shutdown mode, and pulses are not  
appearing at the SENSE input, a fault exists.  
falls, the FAULT output will become inactive when V  
< V  
.
OTF  
3.6  
Auto-Shutdown Mode  
If the voltage on V becomes less than the voltage on  
IN  
V
, the fan is automatically shut off (auto-shutdown  
AS  
mode). The TC646 exits auto-shutdown mode when  
the voltage on V becomes higher than the voltage on  
IN  
The short, rapid change in fan current (high dI/dt)  
causes a corresponding dV/dt across the sense  
V
by V  
(the auto-shutdown Hysteresis Voltage  
HAS  
AS  
(see Figure 3-1)). The Start-up Timer is triggered and  
normal operation is resumed upon exiting auto-shut-  
down mode. The FAULT output is unconditionally  
inactive in auto-shutdown mode.  
resistor,  
R
.
The waveform on  
R
is  
SENSE  
SENSE  
differentiated and converted to a logic-level pulse-train  
by C  
and the internal signal processing circuitry.  
SENSE  
The presence and frequency of this pulse-train is a  
direct indication of fan operation. See Section 5.0,  
“Typical Applications”, for more details.  
DS21446C-page 6  
2002 Microchip Technology Inc.  
TC646  
Normal  
Operation  
TC646  
Status  
Normal  
Operation  
Auto-Shutdown  
Mode  
Shut-  
Down  
Normal  
Operation  
HI  
2.6V  
V
+ V  
V
AS  
HAS  
AS  
TEMP.  
1.2V  
REL  
t
RESET  
V
IN  
V
V
SHDN  
LO  
GND  
Time  
FIGURE 3-1:  
TC646 Nominal Operation.  
If a fan fault has occurred and the device has latched  
itself into shutdown mode, performing a reset will not  
3.7 Shutdown Mode (Reset)  
If an unconditional shutdown and/or device reset is  
desired, the TC646 may be placed in shutdown mode  
clear the fault unless V > (V + V  
). If V is not  
IN  
IN  
AS  
HAS  
greater than (V + V  
) upon exiting shutdown  
HAS  
AS  
by forcing V to a logic low (i.e., V < V ) (see  
SHDN  
IN  
IN  
mode, the fan will not be restarted. Consequently, there  
is no way to establish that the fan fault has been  
cleared. To ensure that a complete reset takes place,  
Figure 3-1). In this mode, all functions cease and the  
FAULT output is unconditionally inactive. The TC646  
should not be shut down unless all heat producing  
activity in the system is at a negligible level. The TC646  
the user’s circuitry must ensure that V > (V + V )  
HAS  
IN  
AS  
when the device is released from shutdown mode. A  
recommended algorithm for management of the TC646  
by a host microcontroller or other external circuitry is  
given in Section 5.0, “Typical Applications”. A small  
exits shutdown mode when V becomes greater than  
IN  
V
, the release voltage.  
REL  
Entering shutdown mode also performs a complete  
device reset. Shutdown mode resets the TC646 into its  
power-up state. The Start-up and Fault Timers, and any  
current faults, are cleared. FAULT is unconditionally  
inactive in shutdown mode. Upon exiting shutdown  
amount of hysteresis, typically one percent of V  
DD  
(50 mV at V = 5.0V), is designed into the V  
/
SHDN  
DD  
V
V
threshold. The levels specified for V  
and  
SHDN  
REL  
REL  
in Section 1.0, “Electrical Characteristics”,  
include this hysteresis plus adequate margin to  
account for normal variations in the absolute value of  
the threshold and hysteresis.  
mode (V > V  
), the Start-up Timer will be triggered  
IN  
REL  
and normal operation will resume, assuming no fault  
conditions exist and V > V + V  
IN  
AS  
HAS  
CAUTION: Shutdown mode is unconditional. That is,  
Note: If V < V when the device exits shutdown  
IN  
AS  
the fan will remain off as long as the V pin is being  
mode, the fan will not restart as it will be in auto-shut-  
down mode.  
IN  
held low or V < V + V .  
HAS  
IN  
AS  
2002 Microchip Technology Inc.  
DS21446C-page 7  
TC646  
4.3  
Fan Fault  
4.0  
SYSTEM BEHAVIOR  
Fan fault is an infinite loop wherein the TC646 is  
The flowcharts describing the TC646’s behavioral  
algorithm are shown in Figure 4-1. They can be  
summarized as follows:  
latched in shutdown mode. This mode can only be  
released by a reset (i.e., V being brought below  
IN  
HAS  
V
, then above (V + V  
), or by power-cycling).  
SHDN  
AS  
4.1  
Power-Up  
(1) While in this state, FAULT is latched on (low) and  
the V output is disabled.  
OUT  
(1) Assuming the device is not being held in auto-shut-  
down mode (V > V )..........  
(2) A reset sequence applied to the V pin will exit the  
IN  
AS  
IN  
loop to Power-up.  
(3) End.  
(2) Turn V  
output on for 32 cycles of the PWM  
OUT  
clock. This ensures that the fan will start from a  
dead stop.  
(3) During this Start-up Timer, if a fan pulse is  
detected, branch to Normal Operation; if none are  
received…  
(4) Activate the 32-cycle Start-up Timer one more time  
and look for fan pulse; if a fan pulse is detected,  
proceed to Normal Operation; if none are  
received…  
(5) Proceed to Fan Fault.  
(6) End.  
4.2  
Normal Operation  
“Normal Operation” is an endless loop which may only  
be exited by entering shutdown mode, auto-shutdown  
mode or Fan Fault. The loop can be thought of as  
executing at the frequency of the oscillator and PWM.  
(1) Reset the missing pulse detector.  
(2) Is the TC646 in shutdown or auto-shutdown  
mode?  
If so...  
a. V  
duty cycle goes to zero.  
OUT  
b. FAULT is disabled.  
c. Exit the loop and wait for V > (V + V ) to  
HAS  
IN  
AS  
resume operation.  
(3) If an over-temperature fault occurs (V > V  
),  
OTF  
IN  
activate FAULT; release FAULT when  
V < V  
.
IN  
OTF  
(4) Drive V  
to a duty cycle proportional to V on  
IN  
OUT  
a cycle by cycle basis.  
(5) If a fan pulse is detected, branch back to the  
start of the loop (1).  
(6) If the missing pulse detector times out …  
(7) Activate the 3-cycle Diagnostic Timer and look  
for pulses; if a fan pulse is detected, branch  
back to the start of the loop (1); if none are  
received…  
(8) Activate the 32-cycle Start-up Timer and look for  
pulses; if a fan pulse is detected, branch back to  
the start of the loop (1); if none are received…  
(9) Quit Normal Operation and go to Fan Fault.  
(10) End.  
DS21446C-page 8  
2002 Microchip Technology Inc.  
TC646  
Normal  
Operation  
Power-Up  
Clear Missing  
Pulse Detector  
Power-on  
Reset  
FAULT = 1  
Yes  
Shutdown  
= 0  
V
< V  
?
SHDN  
IN  
V
OUT  
Yes  
Shutdown  
= 0  
V
< V ?  
SHDN  
IN  
No  
V
OUT  
No  
V
V
REL  
>
?
IN  
No  
V
> V  
REL  
No  
IN  
Yes  
Yes  
Auto  
Shutdown  
Yes  
Power-Up  
Auto-  
Shutdown  
OUT = 0  
V
< V  
> V  
?
AS  
IN  
Yes  
V
= 0  
OUT  
V
< V ?  
AS  
IN  
V
No  
No  
V
>
)
HAS  
No  
IN  
+ V  
Yes  
(V  
AS  
V
>
No  
V
?
OTF  
IN  
+ V  
IN  
(V  
)
AS  
HAS  
Yes  
No  
Hot Start  
FAULT = 0  
Yes  
Hot Start  
V
OUT  
Proportional  
to V  
Fire Start-up  
Timer  
(1 SEC)  
IN  
Yes  
No  
No  
Fire Start-up  
Timer  
(1 SEC)  
Fan Pulse  
Detected?  
Fan Pulse  
Detected?  
M.P.D.  
Expired?  
Yes  
No  
Yes  
Yes  
Fan Pulse  
Detected?  
Fire  
Diagnostic  
Timer  
(100msec)  
No  
Normal  
Operation  
Fan Fault  
No  
Yes  
Fire Start-up  
Timer  
(1 sec)  
Fan Pulse  
Detected?  
Fan Fault  
Yes  
Fan Pulse  
Detected?  
FAULT = 0,  
V
= 0  
OUT  
No  
Fan Fault  
No  
Auto-Shutdown  
FAULT = 1  
No  
Cycling  
Power  
V
< V  
?
IN  
SHDN  
V
= 0  
OUT  
Yes  
Yes  
Yes  
No  
V
> V  
REL  
?
V
> (V + V  
)?  
HAS  
IN  
IN  
AS  
No  
Yes  
Power-Up  
FIGURE 4-1:  
TC646 Behavioral Algorithm Flowchart.  
2002 Microchip Technology Inc.  
DS21446C-page 9  
TC646  
The TC642 demonstration and prototyping board  
(TC642DEMO) and the TC642 Evaluation Kit  
(TC642EV) provide working examples of TC646 cir-  
cuits and prototyping aids. The TC642DEMO is a  
printed circuit board optimized for small size and ease  
of inclusion into system prototypes. The TC642EV is a  
larger board intended for benchtop development and  
analysis. At the very least, anyone contemplating a  
design using the TC646 should consult the documen-  
tation for both TC642EV (DS21403) and TC642DEMO  
(DS21401). Figure 5-1 shows the base schematic for  
the TC642DEMO.  
5.0  
TYPICAL APPLICATIONS  
Designing with the TC646 involves the following:  
(1) The temperature sensor network must be  
configured to deliver 1.25V to 2.65V on V for 0%  
IN  
to 100% of the temperature range to be regulated.  
(2) The auto-shutdown temperature must be set  
with a voltage divider on V  
.
AS  
(3) The output drive transistor and associated circuitry  
must be selected.  
(4) The SENSE network, R  
and C  
, must  
SENSE  
SENSE  
be designed for maximum efficiency while  
delivering adequate signal amplitude.  
(5) If shutdown capability is desired, the drive require-  
ments of the external signal or circuit must be  
considered.  
+5V*  
C
+12V  
B
1µF  
NTC  
R
1
8
Fan  
Q
1
Shutdown**  
V
V
DD  
IN  
C
B
0.01µF  
6
R
2
Thermal  
Shutdown  
FAULT  
1
+5V  
R
BASE  
TC646  
7
5
V
R
OUT  
3
3
V
C
AS  
C
B
0.01µF  
SENSE  
2
C
SENSE  
R
F
4
R
SENSE  
C
1µF  
GND  
4
F
NOTES: *See cautions regarding latch-up considerations in Section 5.0, "Typical Applications".  
**Optional. See Section 5.0, "Typical Applications", for details.  
FIGURE 5-1:  
Typical Application Circuit.  
DS21446C-page 10  
2002 Microchip Technology Inc.  
TC646  
EQUATION  
5.1  
Temperature Sensor Design  
V
x R  
2
DD  
The temperature signal connected to V must output a  
IN  
= V(T )  
1
voltage in the range of 1.25V to 2.65V (typical) for 0%  
to 100% of the temperature range of interest. The  
circuit in Figure 5-2 illustrates a convenient way to  
provide this signal.  
R
(T ) + R  
1 2  
TEMP  
V
x R  
2
DD  
= V(T )  
2
R
(T ) + R  
2 2  
TEMP  
V
DD  
Where T and T are the chosen temperatures and  
1
2
R
is the parallel combination of the thermistor  
TEMP  
and R .  
1
I
DIV  
These two equations facilitate solving for the two  
unknown variables, R and R . More information about  
1
2
thermistors may be obtained from AN679, “Tempera-  
ture Sensing Technologies”, and AN685, “Thermistors  
In Single Supply Temperature Sensing Circuits”, which  
can be downloaded from Microchip’s web site at  
www.microchip.com.  
RT  
R = 100 kΩ  
1
1
NTC Thermistor  
100 k@25˚C  
V
IN  
5.2  
Auto-Shutdown Temperature  
Design  
R = 23.2kΩ  
2
A voltage divider on V sets the temperature where  
AS  
the part is automatically shut down if the sensed  
FIGURE 5-2:  
Temperature Sensing  
temperature at V drops below the set temperature at  
IN  
Circuit.  
V
(i.e., V < V ). As with the V input, 1.25V to  
IN AS IN  
AS  
2.65V corresponds to the temperature range of interest  
from T to T , respectively. Assuming that the  
Figure 5-2 shows a simple temperature dependent  
voltage divider circuit. RT is a conventional NTC ther-  
1
2
1
temperature sensor network designed above is linearly  
mistor, while R and R are standard resistors. The  
1
2
related to temperature, the shutdown temperature T  
supply voltage, V , is divided between R and the  
AS  
DD  
2
is related to T and T by:  
parallel combination of RT and R . For convenience,  
2
1
1
1
the parallel combination of RT and R will be referred  
1
1
to as R  
. The resistance of the thermistor at various  
EQUATION  
TEMP  
temperatures is obtained from the manufacturer’s  
specifications. Thermistors are often referred to in  
terms of their resistance at 25°C.  
V
T
- 1.25V  
- T  
AS  
2.65V - 1.25V  
T - T  
=
AS  
1
2
1
1.4V  
Generally, the thermistor shown in Figure 5-2 is a non-  
)
V
=
(
( T - T ) + 1.25V  
AS 1  
linear device with a negative temperature coefficient  
AS  
T - T  
2
1
(also called an NTC thermistor). In Figure 5-2, R is  
1
used to linearize the thermistor temperature response  
For example, if 1.25V and 2.65V at V corresponds to  
IN  
and R is used to produce a positive temperature  
a temperature range of T = 0°C to T = 125°C, and the  
2
1
2
coefficient at the V node. As an added benefit, this  
auto-shutdown temperature desired is 25°C, then V  
voltage is:  
IN  
AS  
configuration produces an output voltage delta of 1.4V,  
which is well within the range of the V  
C(SPAN)  
specification of the TC646. A 100 kNTC thermistor is  
EQUATION  
selected for this application in order to keep I  
minimum.  
at a  
DIV  
1.4V  
V
=
(25 - 0) + 1.25V = 1.53V  
AS  
(125 - 0)  
For the voltage range at V to be equal to 1.25V to  
IN  
2.65V, the temperature range of this configuration is  
0°C to 50°C. If a different temperature range is required  
The V voltage may be set using a simple resistor  
divider as shown in Figure 5-3.  
AS  
from this circuit, R should be chosen to equal the  
1
resistance value of the thermistor at the center of this  
new temperature range. It is suggested that a maxi-  
mum temperature range of 50°C be used with this cir-  
cuit due to thermistor linearity limitations. With this  
change, R is adjusted according to the following  
2
equations:  
2002 Microchip Technology Inc.  
DS21446C-page 11  
TC646  
5.3  
Operations at Low Duty Cycle  
V
DD  
One boundary condition which may impact the selec-  
tion of the minimum fan speed is the irregular activation  
of the Diagnostic Timer due to the TC646 “missing” fan  
commutation pulses at low speeds. This is a natural  
consequence of low PWM duty cycles (typically 25% or  
less). Recall that the SENSE function detects commu-  
tation of the fan as disturbances in the current through  
R
R
1
I
IN  
R
. These can only occur when the fan is ener-  
I
V
AS  
SENSE  
DIV  
gized (i.e., V  
is “on”). At very low duty cycles, the  
OUT  
V
output is “off” most of the time. The fan may be  
OUT  
rotating normally, but the commutation events are  
occurring during the PWM’s off-time.  
2
The phase relationship between the fan’s commutation  
and the PWM edges tends to “walk around” as the  
system operates. At certain points, the TC646 may fail  
to capture a pulse within the 32-cycle missing pulse  
detector window. If this happens, the 3-cycle  
GND  
FIGURE 5-3:  
V
CIRCUIT  
AS  
Per Section 1.0, “Electrical Characteristics”, the leak-  
Diagnostic Timer will be activated, the V  
output will  
OUT  
age current at the V pin is no more than 1 µA. It is  
AS  
be active continuously for three cycles and, if the fan is  
operating normally, a pulse will be detected. If all is  
well, the system will return to normal operation. There  
is no harm in this behavior, but it may be audible to the  
user as the fan accelerates briefly when the Diagnostic  
conservative to design for a divider current, I , of  
DIV  
100 µA. If V = 5.0V then…  
DD  
EQUATION  
Timer fires. For this reason, it is recommended that V  
be set no lower than 1.8V.  
AS  
5.0V  
–4  
I
= 1e A =  
, therefore  
DIV  
R + R  
1
2
5.4  
FanSenseNetwork  
(RSENSE and CSENSE  
5.0V  
1e A  
R + R =  
= 50,000= 50kΩ  
1
2
)
–4  
The FanSense network, comprised of R  
and  
SENSE  
C
, allows the TC646 to detect commutation of  
SENSE  
We can further specify R and R by the condition that  
1
2
the fan motor (FanSense technology). This network  
can be thought of as a differentiator and threshold  
the divider voltage is equal to our desired V . This  
AS  
yields:  
detector. The function of R  
current into a voltage. C  
is to convert the fan  
SENSE  
SENSE  
serves to AC-couple this  
EQUATION  
voltage signal and provide a ground-referenced input to  
the SENSE pin. Designing a proper SENSE network is  
V
x R  
2
DD  
V
=
simply a matter of scaling R  
to provide the  
AS  
SENSE  
R + R  
necessary amount of gain (i.e., the current-to-voltage  
conversion ratio). A 0.1 µF ceramic capacitor is  
1
2
recommended for C  
. Smaller values require  
SENSE  
Solving for the relationship between R and R results  
1
2
larger sense resistors, and higher value capacitors are  
bulkier and more expensive. Using a 0.1 µF capacitor  
in:  
results in reasonable values for R  
. Figure 5-4  
SENSE  
EQUATION  
illustrates a typical SENSE network. Figure 5-5 shows  
the waveforms observed using a typical SENSE net-  
work.  
5 - 1.53  
1.53  
V
- V  
AS  
DD  
R = R x  
= R x  
1
2
2
V
AS  
In the case of this example, R = (2.27) R .  
1
2
Substituting this relationship back into the original  
equation yields the resistor values:  
R = 15.3 k, and  
2
R = 34.7 kΩ  
1
In this case, the standard values of 34.8 kand  
15.4 kare very close to the calculated values and  
would be more than adequate.  
DS21446C-page 12  
2002 Microchip Technology Inc.  
TC646  
TABLE 5-1:  
Nominal Fan Current (mA)  
RSENSE VS. FAN CURRENT  
V
DD  
R
()  
SENSE  
9.1  
4.7  
3.0  
2.4  
2.0  
1.8  
1.5  
1.3  
1.2  
1.0  
50  
100  
150  
200  
250  
300  
350  
400  
450  
500  
Fan  
R
BASE  
V
OUT  
Q
1
SENSE  
C
SENSE  
(0.1 µF Typ.)  
R
SENSE  
5.5  
Output Drive Transistor Selection  
The TC646 is designed to drive an external transistor  
or MOSFET for modulating power to the fan. This is  
shown as Q in Figures 5-1, 5-4, 5-6, 5-7, 5-8 and 5-9.  
1
GND  
The V  
pin has a minimum source current of 5 mA  
OUT  
FIGURE 5-4:  
SENSE Network.  
and a minimum sink current of 1 mA. Bipolar transistors  
or MOSFETs may be used as the power switching  
element, as shown in Figure 5-7. When high current  
gain is needed to drive larger fans, two transistors may  
be used in a Darlington configuration. These circuit  
topologies are shown in Figure 5-7: (a) shows a single  
NPN transistor used as the switching element; (b)  
illustrates the Darlington pair; and (c) shows an N-  
channel MOSFET.  
Tek Run: 10.0kS/s Sample  
[
T
]
One major advantage of the TC646’s PWM control  
scheme versus linear speed control is that the power  
dissipation in the pass element is kept very low.  
Generally, low cost devices in very small packages,  
such as TO-92 or SOT, can be used effectively. For  
fans with nominal operating currents of no more than  
200 mA, a single transistor usually suffices. Above  
200 mA, the Darlington or MOSFET solution is  
recommended. For the fan sensing function to work  
correctly, it is imperative that the pass transistor be fully  
saturated when “on”.  
Waveform @ Sense Resistor  
Waveform @ Sense Pin  
GND  
1
2
90mV  
50mV  
GND  
T
M5.00ms  
Ch1  
100mV  
142mV  
Ch1  
Ch2  
100mV  
FIGURE 5-5:  
SENSE Waveforms.  
Table 5-2 gives examples of some commonly available  
transistors and MOSFETs. This table should be used  
as a guide only since there are many transistors and  
MOSFETs which will work just as well as those listed.  
The critical issues when choosing a device to use as  
Table 5-1 lists the recommended values of R  
SENSE  
based on the nominal operating current of the fan. Note  
that the current draw specified by the fan manufacturer  
may be a worst-case rating for near-stall conditions and  
not the fan’s nominal operating current. The values in  
Table 5-1 refer to actual average operating current. If  
the fan current falls between two of the values listed,  
use the higher resistor value. The end result of employ-  
ing Table 5-1 is that the signal developed across the  
sense resistor is approximately 450 mV in amplitude.  
Q
are: (1) the breakdown voltage (V  
or V  
(BR)CEO DS  
1
(MOSFET)) must be large enough to withstand the  
highest voltage applied to the fan (Note: This will occur  
when the fan is off); (2) 5 mA of base drive current must  
be enough to saturate the transistor when conducting  
the full fan current (transistor must have sufficient  
gain); (3) the V  
voltage must be high enough to suf-  
OUT  
ficiently drive the gate of the MOSFET to minimize the  
R
of the device; (4) rated fan current draw must  
DS(on)  
be within the transistor's/MOSFET's current handling  
capability; and (5) power dissipation must be kept  
within the limits of the chosen device.  
2002 Microchip Technology Inc.  
DS21446C-page 13  
TC646  
A base-current limiting resistor is required with bipolar  
transistors. This is shown in Figure 5-6.  
The correct value for this resistor can be determined as  
follows:  
V
V
V
= V  
+ V  
+ V  
BE R  
(SAT) BASE  
OH  
R
SENSE  
x R  
V
DD  
= I  
R
R
FAN  
SENSE  
SENSE  
BASE  
= R  
x I  
BASE  
BASE  
/ h  
FAN FE  
I
= I  
BASE  
V
is specified as 80% of V  
in Section 1.0,  
is given in the  
OH  
DD  
“Electrical Characteristics”; V  
BE  
(SAT)  
Fan  
chosen transistor data sheet. It is now possible to solve  
for R  
.
BASE  
R
BASE  
EQUATION  
V
= 80% V  
DD  
OH  
Q
1
+
BE  
+
V
V
- V  
- V  
R
(SAT) SENSE  
R
OH  
BE  
BASE  
R
=
BASE  
V
I
(SAT)  
+
BASE  
V
Some applications benefit from the fan being powered  
from a negative supply to keep motor noise out of the  
positive supply rails. This can be accomplished as  
R
R
SENSE  
SENSE  
shown in Figure 5-8. Zener diode D offsets the -12V  
1
power supply voltage, holding transistor Q off when  
1
GND  
V
is low. When V  
is high, the voltage at the  
OUT  
OUT  
anode of D increases by V  
, causing Q to turn on.  
1
1
OUT  
FIGURE 5-6:  
Circuit For Determining  
Operation is otherwise the same as in the case of fan  
operation from +12V.  
R
.
BASE  
V
V
V
DD  
DD  
DD  
Fan  
Fan  
Fan  
R
BASE  
R
BASE  
V
OUT  
Q
1
V
Q
OUT  
1
Q
V
1
OUT  
Q
2
R
R
SENSE  
SENSE  
R
SENSE  
GND  
GND  
a) Single Bipolar Transistor  
GND  
b) Darlington Transistor Pair  
c) N-Channel MOSFET  
FIGURE 5-7:  
Output Drive Transistor Circuit Topologies.  
DS21446C-page 14  
2002 Microchip Technology Inc.  
TC646  
+5V  
V
DD  
R *  
2
2.2 kΩ  
V
OUT  
D
12.0V  
1
Fan  
Zener  
TC646  
Q *  
1
R *  
4
R *  
3
10 kΩ  
2.2Ω  
GND  
-12V  
NOTE: *Value depends on the specific application and is shown for example only.  
FIGURE 5-8:  
Power the Fan from a -12V Supply.  
TABLE 5-2:  
Device  
TRANSISTORS AND MOSFETS FOR Q (V = 5V)  
1
DD  
Max. V  
/V  
V
/V  
Fan Current  
(mA)  
Suggested  
BE(sat) GS  
CEO DS  
Package  
Min. H  
FE  
(V)  
(V)  
R
()  
BASE  
800  
800  
301  
Note 1  
Note 1  
Note 1  
Note 1  
MMBT2222A  
MPS2222A  
MPS6602  
SI2302  
MGSF1N02E  
SI4410  
SOT-23  
TO-92  
TO-92  
SOT-23  
SOT-23  
SO-8  
1.2  
1.2  
1.2  
2.5  
2.5  
4.5  
4.5  
50  
50  
50  
NA  
NA  
NA  
NA  
40  
40  
40  
20  
20  
30  
60  
150  
150  
500  
500  
500  
1000  
500  
SI2308  
SOT-23  
Note 1: A series gate resistor may be used in order to control the MOSFET turn-on and turn-off times.  
5.6  
Latch-up Considerations  
5.7  
Power Supply Routing and  
Bypassing  
As with any CMOS IC, the potential exists for latch-up  
if signals are applied to the device which are outside  
the power supply range. This is of particular concern  
during power-up if the external circuitry (such as the  
Noise present on the V and V inputs may cause  
IN  
AS  
erroneous operation of the FAULT output. As a result,  
these inputs should be bypassed with a 0.01 µF  
capacitor mounted as close to the package as possible.  
sensor network, V  
divider or shutdown circuit) is  
AS  
powered by a supply different from that of the TC646.  
This is especially true of V , which is usually driven  
IN  
Care should be taken to ensure that the TC646’s V  
from a high impedance source (such as a thermistor).  
DD  
supply powers up first. If possible, the networks  
attached to V and V should connect to the V sup-  
In addition, the V  
input should be bypassed with a  
DD  
1 µF capacitor. Grounds should be kept as short as  
possible. To keep fan noise off the TC646 ground pin,  
individual ground returns for the TC646 and the low  
side of the fan current sense resistor should be used.  
IN  
AS  
DD  
ply at the same physical location as the IC itself. Even  
if the IC and any external networks are powered by the  
same supply, physical separation of the connecting  
points can result in enough parasitic capacitance and/  
or inductance in the power supply connections to delay  
one power supply “routing” versus another.  
2002 Microchip Technology Inc.  
DS21446C-page 15  
TC646  
Design Example  
Step 1. Calculate R and R based on using an NTC  
1
2
having a resistance of 10 kat T  
(25°C)  
MIN  
and 4.65 kat T  
(45°C) (See Figure 5-9).  
MAX  
R = 20.5 kΩ  
1
R = 3.83 kΩ  
2
Step 2. Set auto-shutdown level V = 1.8V.  
AS  
Limit the divider current to 100 µA from which  
R = 33 kΩ  
5
R = 18 kΩ  
6
Step 3. Design the output circuit.  
Maximum fan motor current = 250 mA. Q  
1
beta is chosen at 50 from which R = 800 .  
7
+5V  
+12V  
+5V  
NTC  
10 kΩ  
@ 25˚C  
C
1 µF  
B
R
1
Open-Drain  
Device  
20.5 kΩ  
4
8
Fan  
Q
Reset  
Shutdown  
1
V
V
DD  
GND  
IN  
C
B
0.01 µF  
R
2
3.83 kΩ  
6
Fan/Thermal  
Fault  
FAULT  
1
(Optional)  
R
+5V  
7
800Ω  
TC646  
7
5
V
R
33 kΩ  
OUT  
5
3
V
C
AS  
C
B
SENSE  
0.01 µF  
2
C
SENSE  
0.1 µF  
R
6
18 kΩ  
F
R
SENSE  
2.2Ω  
C
1
1 µF  
FIGURE 5-9:  
Design Example.  
With V set at 1.8V, the TC646 enters auto-shutdown  
5.8  
TC646 as a Microcontroller  
Peripheral  
AS  
when the controller's output code is 000[B]. Output  
codes 001[B] to 111[B] operate the fan from roughly  
40% to 100% of full speed. An open-drain output from  
the processor (I/O0) can be used to reset the TC646  
following detection of a fault condition. The FAULT out-  
put can be connected to the controller's interrupt input,  
or to another I/O pin, for polled operation.  
In a system containing a microcontroller or other host  
intelligence, the TC646 can be effectively managed as  
a CPU peripheral. Routine fan control functions can be  
performed by the TC646 without controller intervention.  
The microcontroller receives temperature data from  
one or more points throughout the system. It calculates  
a fan operating speed based on an algorithm specifi-  
cally designed for the application at hand. The proces-  
sor controls fan speed using complementary port bits  
I/O1 through I/O3. Resistors R through R (5% toler-  
1
6
ance) form a crude 3-bit DAC that translates the 3-bit  
code from the processor's outputs into a 1.6V DC con-  
trol signal. A monolithic DAC or digital pot may be used  
instead of the circuit shown in Figure 5-10.  
DS21446C-page 16  
2002 Microchip Technology Inc.  
TC646  
+12V  
+5V  
(RESET)  
Open-Drain  
Outputs  
(Optional)  
I/O0  
+5V  
Fan  
R
1
110 kΩ  
1
2
8
(MSB)  
V
C
V
I/O1  
I/O2  
I/O3  
IN  
DD  
+
C
B
C
R
2
240 kΩ  
B
Analog or Digital  
Temperature  
Data from one or  
more Sensors  
1 µF  
R
800Ω  
.01 µF  
CMOS  
Outputs  
9
7
R
3
360 kΩ  
F
V
OUT  
2N2222A  
+
+5V  
TC646  
1 µF  
R
7
33 kΩ  
(LSB)  
+5V  
R
10  
10 kΩ  
CMOS  
R
4
3
6
5
R
V
AS  
18 k  
5
FAULT  
Microcontroller  
C
B
+5V  
1.5 kΩ  
R
18 kΩ  
8
.01 µF  
0.1 µF  
4
R
6
SENSE  
GND  
1 kΩ  
R
11  
2.2Ω  
GND  
INT  
FIGURE 5-10:  
TC646 as a Microcontroller Peripheral.  
V
vs.Temperature  
RELEASE  
1.0  
0.9  
V
= 5.5V  
= 5.0V  
DD  
V
DD  
0.8  
0.7  
V
DD  
= 4.0V  
0.6  
V
= 3.0V  
DD  
0.5  
0.4  
0˚C  
25˚C  
TEMPERATURE  
85˚C  
FIGURE 5-11:  
VRELEASE vs. Temperature.  
2002 Microchip Technology Inc.  
DS21446C-page 17  
TC646  
6.0  
6.1  
PACKAGING INFORMATION  
Package Marking Information  
8-Lead PDIP (300 mil)  
Example:  
XXXXXXXX  
NNN  
TC646VPA  
025  
YYWW  
0215  
8-Lead SOIC (150 mil)  
Example:  
XXXXXXXX  
YYWW  
TC646VOA  
0215  
NNN  
025  
Example:  
8-Lead MSOP  
TC646E  
XXXXXX  
YWWNNN  
215025  
Legend: XX...X Customer specific information*  
YY  
WW  
NNN  
Year code (last 2 digits of calendar year)  
Week code (week of January 1 is week ‘01’)  
Alphanumeric traceability code  
Note:  
In the event the full Microchip part number cannot be marked on one line, it will  
be carried over to the next line thus limiting the number of available characters  
for customer specific information.  
*
Standard marking consists of Microchip part number, year code, week code, traceability code (facility  
code, mask rev#, and assembly code). For marking beyond this, certain price adders apply. Please check  
with your Microchip Sales Office.  
DS21446C-page 18  
2002 Microchip Technology Inc.  
TC646  
8-Lead Plastic Dual In-line (P) – 300 mil (PDIP)  
E1  
D
2
n
1
α
E
A2  
A
L
c
A1  
β
B1  
B
p
eB  
Units  
Dimension Limits  
INCHES*  
NOM  
MILLIMETERS  
MIN  
MAX  
MIN  
NOM  
8
MAX  
n
p
A
A2  
A1  
E
E1  
D
L
c
B1  
B
Number of Pins  
Pitch  
Top to Seating Plane  
Molded Package Thickness  
Base to Seating Plane  
Shoulder to Shoulder Width  
Molded Package Width  
Overall Length  
Tip to Seating Plane  
Lead Thickness  
Upper Lead Width  
Lower Lead Width  
Overall Row Spacing  
Mold Draft Angle Top  
Mold Draft Angle Bottom  
8
.100  
.155  
.130  
2.54  
3.94  
3.30  
.140  
.170  
.145  
3.56  
2.92  
4.32  
3.68  
.115  
.015  
.300  
.240  
.360  
.125  
.008  
.045  
.014  
.310  
5
0.38  
7.62  
6.10  
9.14  
3.18  
0.20  
1.14  
0.36  
7.87  
5
.313  
.250  
.373  
.130  
.012  
.058  
.018  
.370  
10  
.325  
.260  
.385  
.135  
.015  
.070  
.022  
.430  
15  
7.94  
6.35  
9.46  
3.30  
0.29  
1.46  
0.46  
9.40  
10  
8.26  
6.60  
9.78  
3.43  
0.38  
1.78  
0.56  
10.92  
15  
§
eB  
α
β
5
10  
15  
5
10  
15  
* Controlling Parameter  
§ Significant Characteristic  
Notes:  
Dimensions D and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not exceed  
.010” (0.254mm) per side.  
JEDEC Equivalent: MS-001  
Drawing No. C04-018  
2002 Microchip Technology Inc.  
DS21446C-page 19  
TC646  
8-Lead Plastic Small Outline (SN) – Narrow, 150 mil (SOIC)  
E
E1  
p
D
2
B
n
1
h
α
45×  
c
A2  
A
f
β
L
A1  
Units  
INCHES*  
NOM  
MILLIMETERS  
Dimension Limits  
MIN  
MAX  
MIN  
NOM  
8
MAX  
n
p
A
A2  
A1  
E
E1  
D
h
L
f
Number of Pins  
Pitch  
Overall Height  
8
.050  
.061  
.056  
.007  
.237  
.154  
.193  
.015  
.025  
4
1.27  
.053  
.069  
1.35  
1.32  
1.55  
1.42  
0.18  
6.02  
3.91  
4.90  
0.38  
0.62  
4
1.75  
Molded Package Thickness  
Standoff  
.052  
.004  
.228  
.146  
.189  
.010  
.019  
0
.061  
.010  
.244  
.157  
.197  
.020  
.030  
8
1.55  
0.25  
6.20  
3.99  
5.00  
0.51  
0.76  
8
§
0.10  
5.79  
3.71  
4.80  
0.25  
0.48  
0
Overall Width  
Molded Package Width  
Overall Length  
Chamfer Distance  
Foot Length  
Foot Angle  
c
Lead Thickness  
Lead Width  
.008  
.013  
0
.009  
.017  
12  
.010  
.020  
15  
0.20  
0.33  
0
0.23  
0.42  
12  
0.25  
0.51  
15  
B
α
β
Mold Draft Angle Top  
Mold Draft Angle Bottom  
0
12  
15  
0
12  
15  
* Controlling Parameter  
§ Significant Characteristic  
Notes:  
Dimensions D and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not exceed  
.010” (0.254mm) per side.  
JEDEC Equivalent: MS-012  
Drawing No. C04-057  
DS21446C-page 20  
2002 Microchip Technology Inc.  
TC646  
8-Lead Plastic Micro Small Outline Package (MS) (MSOP)  
E
p
E1  
D
2
B
n
1
α
A2  
A
c
φ
A1  
(F)  
L
β
Units  
Dimension Limits  
INCHES  
NOM  
MILLIMETERS*  
NOM  
MIN  
MAX  
MIN  
MAX  
8
n
p
Number of Pins  
Pitch  
8
.026  
0.65  
Overall Height  
Molded Package Thickness  
A
A2  
A1  
E
E1  
D
.044  
1.18  
0.97  
0.15  
.5.08  
3.10  
3.10  
0.70  
1.00  
6
.030  
.034  
.038  
.006  
.200  
.122  
.122  
.028  
.039  
0.76  
0.05  
0.86  
Standoff  
§
.002  
.184  
.114  
.114  
.016  
.035  
Overall Width  
Molded Package Width  
Overall Length  
Foot Length  
Footprint (Reference)  
Foot Angle  
.193  
.118  
.118  
.022  
.037  
4.90  
3.00  
3.00  
0.55  
0.95  
4.67  
2.90  
2.90  
0.40  
0.90  
L
F
φ
0
6
0
c
Lead Thickness  
Lead Width  
Mold Draft Angle Top  
Mold Draft Angle Bottom  
.004  
.010  
.006  
.012  
.008  
.016  
0.10  
0.25  
0.15  
0.30  
0.20  
0.40  
B
α
β
7
7
7
7
*Controlling Parameter  
§ Significant Characteristic  
Notes:  
Dimensions D and E1 do not include mold flash or protrusions. Mold flash or protrusions shall not  
exceed. 010" (0.254mm) per side.  
Drawing No. C04-111  
2002 Microchip Technology Inc.  
DS21446C-page 21  
TC646  
6.2  
Taping Form  
Component Taping Orientation for 8-Pin MSOP Devices  
User Direction of Feed  
PIN 1  
W
P
Standard Reel Component Orientation  
for 713 Suffix Device  
Carrier Tape, Number of Components Per Reel and Reel Size  
Package  
Carrier Width (W)  
Pitch (P)  
Part Per Full Reel  
Reel Size  
8-Pin MSOP  
12 mm  
8 mm  
2500  
13 in  
Component Taping Orientation for 8-Pin SOIC (Narrow) Devices  
User Direction of Feed  
PIN 1  
W
P
Standard Reel Component Orientation  
for 713 Suffix Device  
Carrier Tape, Number of Components Per Reel and Reel Size  
Package  
Carrier Width (W)  
Pitch (P)  
Part Per Full Reel  
Reel Size  
8-Pin SOIC (N)  
12 mm  
8 mm  
2500  
13 in  
DS21446C-page 22  
2002 Microchip Technology Inc.  
TC646  
ON-LINE SUPPORT  
Microchip provides on-line support on the Microchip  
World Wide Web site.  
SYSTEMS INFORMATION AND  
UPGRADE HOT LINE  
The Systems Information and Upgrade Line provides  
system users a listing of the latest versions of all of  
Microchip's development systems software products.  
Plus, this line provides information on how customers  
can receive the most current upgrade kits.The Hot Line  
Numbers are:  
1-800-755-2345 for U.S. and most of Canada, and  
1-480-792-7302 for the rest of the world.  
The web site is used by Microchip as a means to make  
files and information easily available to customers. To  
view the site, the user must have access to the Internet  
®
®
and a web browser, such as Netscape or Microsoft  
Internet Explorer. Files are also available for FTP  
download from our FTP site.  
ConnectingtotheMicrochipInternetWebSite  
The Microchip web site is available at the following  
URL:  
092002  
www.microchip.com  
The file transfer site is available by using an FTP ser-  
vice to connect to:  
ftp://ftp.microchip.com  
The web site and file transfer site provide a variety of  
services. Users may download files for the latest  
Development Tools, Data Sheets, Application Notes,  
User's Guides, Articles and Sample Programs. A vari-  
ety of Microchip specific business information is also  
available, including listings of Microchip sales offices,  
distributors and factory representatives. Other data  
available for consideration is:  
• Latest Microchip Press Releases  
Technical Support Section with Frequently Asked  
Questions  
• Design Tips  
• Device Errata  
• Job Postings  
• Microchip Consultant Program Member Listing  
• Links to other useful web sites related to  
Microchip Products  
• Conferences for products, Development Systems,  
technical information and more  
• Listing of seminars and events  
2002 Microchip Technology Inc.  
DS21446C-page23  
TC646  
READER RESPONSE  
It is our intention to provide you with the best documentation possible to ensure successful use of your Microchip prod-  
uct. If you wish to provide your comments on organization, clarity, subject matter, and ways in which our documentation  
can better serve you, please FAX your comments to the Technical Publications Manager at (480) 792-4150.  
Please list the following information, and use this outline to provide us with your comments about this document.  
To:  
Technical Publications Manager  
Reader Response  
Total Pages Sent ________  
RE:  
From:  
Name  
Company  
Address  
City / State / ZIP / Country  
Telephone: (_______) _________ - _________  
FAX: (______) _________ - _________  
Application (optional):  
Would you like a reply?  
Y
N
Literature Number:  
DS21446C  
Device:  
TC646  
Questions:  
1. What are the best features of this document?  
2. How does this document meet your hardware and software development needs?  
3. Do you find the organization of this document easy to follow? If not, why?  
4. What additions to the document do you think would enhance the structure and subject?  
5. What deletions from the document could be made without affecting the overall usefulness?  
6. Is there any incorrect or misleading information (what and where)?  
7. How would you improve this document?  
DS21446C-page24  
2002 Microchip Technology Inc.  
TC646  
PRODUCT IDENTIFICATION SYSTEM  
To order or obtain information, e.g., on pricing or delivery, refer to the factory or the listed sales office.  
PART NO.  
Device  
X
/XX  
Examples:  
Temperature Package  
Range  
a)  
b)  
c)  
d)  
TC646VOA: PWM Fan Speed Controller w/  
Auto Shutdown and Fault Detection, SOIC  
package.  
TC646VUA: PWM Fan Speed Controller w/  
Auto Shutdown and Fault Detection, MSOP  
package.  
TC646VPA: PWM Fan Speed Controller w/  
Auto Shutdown and Fault Detection, PDIP  
package.  
TC646EOA713: PWM Fan Speed Controller  
w/Auto Shutdown and Fault Detection, SOIC  
package, Tape and Reel.  
Device:  
TC646:  
PWM Fan Speed Controller w/Auto Shutdown  
and Fault Detection  
Temperature Range:  
Package:  
V
E
=
=
0°C to +85°C  
-40°C to +85°C  
PA  
OA  
UA  
=
=
=
Plastic DIP (300 mil Body), 8-lead *  
Plastic SOIC, (150 mil Body), 8-lead  
Plastic Micro Small Outline (MSOP), 8-lead  
* PDIP package is only offerred in the V temp range  
Sales and Support  
Data Sheets  
Products supported by a preliminary Data Sheet may have an errata sheet describing minor operational differences and recom-  
mended workarounds. To determine if an errata sheet exists for a particular device, please contact one of the following:  
1. Your local Microchip sales office  
2. The Microchip Corporate Literature Center U.S. FAX: (480) 792-7277  
3. The Microchip Worldwide Site (www.microchip.com)  
Please specify which device, revision of silicon and Data Sheet (include Literature #) you are using.  
New Customer Notification System  
Register on our web site (www.microchip.com/cn) to receive the most current information on our products.  
2002 Microchip Technology Inc.  
DS21446C-page25  
TC646  
NOTES:  
DS21446C-page 26  
2002 Microchip Technology Inc.  
Information contained in this publication regarding device  
applications and the like is intended through suggestion only  
and may be superseded by updates. It is your responsibility to  
ensure that your application meets with your specifications.  
No representation or warranty is given and no liability is  
assumed by Microchip Technology Incorporated with respect  
to the accuracy or use of such information, or infringement of  
patents or other intellectual property rights arising from such  
use or otherwise. Use of Microchip’s products as critical com-  
ponents in life support systems is not authorized except with  
express written approval by Microchip. No licenses are con-  
veyed, implicitly or otherwise, under any intellectual property  
rights.  
Trademarks  
The Microchip name and logo, the Microchip logo, KEELOQ,  
MPLAB, PIC, PICmicro, PICSTART and PRO MATE are  
registered trademarks of Microchip Technology Incorporated  
in the U.S.A. and other countries.  
FilterLab, microID, MXDEV, MXLAB, PICMASTER, SEEVAL  
and The Embedded Control Solutions Company are  
registered trademarks of Microchip Technology Incorporated  
in the U.S.A.  
dsPIC, dsPICDEM.net, ECONOMONITOR, FanSense,  
FlexROM, fuzzyLAB, In-Circuit Serial Programming, ICSP,  
ICEPIC, microPort, Migratable Memory, MPASM, MPLIB,  
MPLINK, MPSIM, PICC, PICDEM, PICDEM.net, rfPIC, Select  
Mode and Total Endurance are trademarks of Microchip  
Technology Incorporated in the U.S.A. and other countries.  
Serialized Quick Turn Programming (SQTP) is a service mark  
of Microchip Technology Incorporated in the U.S.A.  
All other trademarks mentioned herein are property of their  
respective companies.  
© 2002, Microchip Technology Incorporated, Printed in the  
U.S.A., All Rights Reserved.  
Printed on recycled paper.  
Microchip received QS-9000 quality system  
certification for its worldwide headquarters,  
design and wafer fabrication facilities in  
Chandler and Tempe, Arizona in July 1999  
and Mountain View, California in March 2002.  
The Company’s quality system processes and  
procedures are QS-9000 compliant for its  
®
PICmicro 8-bit MCUs, KEELOQ® code hopping  
devices, Serial EEPROMs, microperipherals,  
non-volatile memory and analog products. In  
addition, Microchip’s quality system for the  
design and manufacture of development  
systems is ISO 9001 certified.  
2002 Microchip Technology Inc.  
DS21446C - page 27  
M
WORLDWIDE SALES AND SERVICE  
Japan  
AMERICAS  
ASIA/PACIFIC  
Microchip Technology Japan K.K.  
Benex S-1 6F  
Corporate Office  
Australia  
2355 West Chandler Blvd.  
Microchip Technology Australia Pty Ltd  
Suite 22, 41 Rawson Street  
Epping 2121, NSW  
3-18-20, Shinyokohama  
Kohoku-Ku, Yokohama-shi  
Kanagawa, 222-0033, Japan  
Tel: 81-45-471- 6166 Fax: 81-45-471-6122  
Chandler, AZ 85224-6199  
Tel: 480-792-7200 Fax: 480-792-7277  
Technical Support: 480-792-7627  
Web Address: http://www.microchip.com  
Australia  
Tel: 61-2-9868-6733 Fax: 61-2-9868-6755  
Korea  
Rocky Mountain  
China - Beijing  
Microchip Technology Korea  
168-1, Youngbo Bldg. 3 Floor  
Samsung-Dong, Kangnam-Ku  
Seoul, Korea 135-882  
2355 West Chandler Blvd.  
Chandler, AZ 85224-6199  
Tel: 480-792-7966 Fax: 480-792-4338  
Microchip Technology Consulting (Shanghai)  
Co., Ltd., Beijing Liaison Office  
Unit 915  
Bei Hai Wan Tai Bldg.  
Tel: 82-2-554-7200 Fax: 82-2-558-5934  
Atlanta  
No. 6 Chaoyangmen Beidajie  
Beijing, 100027, No. China  
Tel: 86-10-85282100 Fax: 86-10-85282104  
500 Sugar Mill Road, Suite 200B  
Atlanta, GA 30350  
Singapore  
Microchip Technology Singapore Pte Ltd.  
200 Middle Road  
Tel: 770-640-0034 Fax: 770-640-0307  
China - Chengdu  
#07-02 Prime Centre  
Boston  
Microchip Technology Consulting (Shanghai)  
Co., Ltd., Chengdu Liaison Office  
Rm. 2401, 24th Floor,  
Singapore, 188980  
2 Lan Drive, Suite 120  
Westford, MA 01886  
Tel: 978-692-3848 Fax: 978-692-3821  
Tel: 65-6334-8870 Fax: 65-6334-8850  
Taiwan  
Ming Xing Financial Tower  
Microchip Technology (Barbados) Inc.,  
Taiwan Branch  
Chicago  
No. 88 TIDU Street  
333 Pierce Road, Suite 180  
Itasca, IL 60143  
Chengdu 610016, China  
11F-3, No. 207  
Tel: 86-28-86766200 Fax: 86-28-86766599  
Tung Hua North Road  
Taipei, 105, Taiwan  
Tel: 630-285-0071 Fax: 630-285-0075  
China - Fuzhou  
Dallas  
Microchip Technology Consulting (Shanghai)  
Co., Ltd., Fuzhou Liaison Office  
Unit 28F, World Trade Plaza  
Tel: 886-2-2717-7175 Fax: 886-2-2545-0139  
4570 Westgrove Drive, Suite 160  
Addison, TX 75001  
Tel: 972-818-7423 Fax: 972-818-2924  
No. 71 Wusi Road  
EUROPE  
Austria  
Detroit  
Fuzhou 350001, China  
Tri-Atria Office Building  
Tel: 86-591-7503506 Fax: 86-591-7503521  
Microchip Technology Austria GmbH  
Durisolstrasse 2  
32255 Northwestern Highway, Suite 190  
Farmington Hills, MI 48334  
Tel: 248-538-2250 Fax: 248-538-2260  
China - Shanghai  
Microchip Technology Consulting (Shanghai)  
Co., Ltd.  
A-4600 Wels  
Austria  
Kokomo  
Room 701, Bldg. B  
Tel: 43-7242-2244-399  
Fax: 43-7242-2244-393  
Denmark  
2767 S. Albright Road  
Kokomo, Indiana 46902  
Tel: 765-864-8360 Fax: 765-864-8387  
Los Angeles  
Far East International Plaza  
No. 317 Xian Xia Road  
Shanghai, 200051  
Microchip Technology Nordic ApS  
Regus Business Centre  
Lautrup hoj 1-3  
Tel: 86-21-6275-5700 Fax: 86-21-6275-5060  
18201 Von Karman, Suite 1090  
Irvine, CA 92612  
China - Shenzhen  
Microchip Technology Consulting (Shanghai)  
Co., Ltd., Shenzhen Liaison Office  
Rm. 1315, 13/F, Shenzhen Kerry Centre,  
Renminnan Lu  
Ballerup DK-2750 Denmark  
Tel: 949-263-1888 Fax: 949-263-1338  
Tel: 45 4420 9895 Fax: 45 4420 9910  
New York  
France  
150 Motor Parkway, Suite 202  
Hauppauge, NY 11788  
Microchip Technology SARL  
Parc d’Activite du Moulin de Massy  
43 Rue du Saule Trapu  
Shenzhen 518001, China  
Tel: 631-273-5305 Fax: 631-273-5335  
Tel: 86-755-2350361 Fax: 86-755-2366086  
San Jose  
China - Hong Kong SAR  
Batiment A - ler Etage  
Microchip Technology Inc.  
2107 North First Street, Suite 590  
San Jose, CA 95131  
Microchip Technology Hongkong Ltd.  
Unit 901-6, Tower 2, Metroplaza  
223 Hing Fong Road  
91300 Massy, France  
Tel: 33-1-69-53-63-20 Fax: 33-1-69-30-90-79  
Germany  
Tel: 408-436-7950 Fax: 408-436-7955  
Kwai Fong, N.T., Hong Kong  
Microchip Technology GmbH  
Steinheilstrasse 10  
Tel: 852-2401-1200 Fax: 852-2401-3431  
Toronto  
6285 Northam Drive, Suite 108  
Mississauga, Ontario L4V 1X5, Canada  
Tel: 905-673-0699 Fax: 905-673-6509  
India  
D-85737 Ismaning, Germany  
Tel: 49-89-627-144 0 Fax: 49-89-627-144-44  
Microchip Technology Inc.  
India Liaison Office  
Italy  
Divyasree Chambers  
Microchip Technology SRL  
Centro Direzionale Colleoni  
Palazzo Taurus 1 V. Le Colleoni 1  
20041 Agrate Brianza  
1 Floor, Wing A (A3/A4)  
No. 11, O’Shaugnessey Road  
Bangalore, 560 025, India  
Tel: 91-80-2290061 Fax: 91-80-2290062  
Milan, Italy  
Tel: 39-039-65791-1 Fax: 39-039-6899883  
United Kingdom  
Microchip Ltd.  
505 Eskdale Road  
Winnersh Triangle  
Wokingham  
Berkshire, England RG41 5TU  
Tel: 44 118 921 5869 Fax: 44-118 921-5820  
08/01/02  
DS21446C-page 28  
2002 Microchip Technology Inc.  

TC646EUATR 相关器件

型号 制造商 描述 价格 文档
TC646VOA MICROCHIP PWM Fan Speed Controller with Auto-Shutdown and FanSense⑩ Technology 获取价格
TC646VOA713 MICROCHIP BRUSHLESS DC MOTOR CONTROLLER, PDSO8, 0.150 INCH, PLASTIC, SOIC-8 获取价格
TC646VOA713G MICROCHIP BRUSHLESS DC MOTOR CONTROLLER, PDSO8, 0.150 INCH, PLASTIC, SOIC-8 获取价格
TC646VOAG MICROCHIP BRUSHLESS DC MOTOR CONTROLLER, PDSO8, 0.150 INCH, PLASTIC, SOIC-8 获取价格
TC646VPA MICROCHIP PWM Fan Speed Controller with Auto-Shutdown and FanSense⑩ Technology 获取价格
TC646VUA MICROCHIP PWM Fan Speed Controller with Auto-Shutdown and FanSense⑩ Technology 获取价格
TC646VUA713 MICROCHIP BRUSHLESS DC MOTOR CONTROLLER, PDSO8, PLASTIC, MSOP-8 获取价格
TC646VUATR MICROCHIP 暂无描述 获取价格
TC647 MICROCHIP PWM Fan Speed Controller with FanSense Technology 获取价格
TC647B MICROCHIP PWM Fan Speed Controllers With Minimum Fan Speed, Fan Restart and FanSense⑩ Technology for Fault Detection 获取价格

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