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Part: BA6819
Category:
Power Management
-> Motor Controller/Drivers
Description: 2-phase Half-wave Motor Driver
Company: ROHM Electronics
Datasheet: Download BA6819 datasheet File size : 150 kB
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Datasheet text preview:
Motor driver ICs
2-phase half-wave motor driver
BA6809F / BA6819AF
The BA6809F and BA6819AF are motor drivers designed for 3V and 5V fan motors. Built-in output transistors reduce the number of external components required. The ICs have an alarm output pin (BA6809F) and Hall output pin (BA6819AF). FApplications Fan motors FFeatures 1) Lock detection and rotational speed sensing mechanisms are built in. 2) Alarm output pin (BA6809F) and Hall output pin (BA6819AF). FAbsolute maximum ratings (Ta = 25_C)
3) Built-in thermal shutdown circuit. 4) Operation assured with a supply voltage as low as 2.7V. 5) Compact 8-pin SOP package.
FRecommended operating conditions (Ta = 25_C)
706
Motor driver ICs
FBlock diagram
BA6809F / BA6819AF
FPin descriptions
FHall input / output truth table
707
Motor driver ICs
FInput / output circuits
BA6809F / BA6819AF
FElectrical characteristics (unless otherwise noted, Ta = 25_C and VCC = 3V)
708
Motor driver ICs
FCircuit operation The BA6809F and BA6819AF have motor lock detection and automatic restart circuits. The timing of lock detection and automatic restart is determined by the external capacitor connected to the LD pin. The charge time of the external capacitor is given by : ton (Charge time)= toff (Discharge time)= C S (VLDCL*VLDCP) ILDC C S (VLDCL*VLDCP) ILDD
BA6809F / BA6819AF
(Typical value) where VLDCL is the LD-pin clamp voltage (1.90V), VLDCP is the LD-pin comparator voltage (0.73V), (2.2µA), ILDC is the LD-pin charge current (0.42µA), ILDD is the LD-pin discharge current C is the capacitance of the LD-pin external capacitor. For C=0.47µF, for example, the charge and discharge times are 0.25s (output ON) and 1.31s (output OFF), respectively.
FApplication example
709
Motor driver ICs
FOperation notes (1) Thermal shutdown circuit The IC has a built-in thermal shutdown circuit. The is a temperature difference of 20_C (typical) between the temperatures at which the circuit is activated and deactivated.
BA6809F / BA6819AF
(3)
Hall amplifier input voltage
The circuit is activated at the temperature of about 175_C (typical), so that all outputs are turned OFF. Normal operation resumes when the circuit is deactivated. (2) Power dissipation Power consumed in the IC can be calculated from the following equation : PC=PC1)PC2)PC3 PC1 is power consumed by the circuit current. PC1=VCC ICC PC2 is the output current consumption. PC2=VOL IO VOL is the LOW level output voltage of output pins 1 and 2, and IO is the sink current of pins 1 and 2. PC3 is power consumed by the AL and HO pins. PC3=VALL IAL (BA6809F) PC3=VHOL IHO / 2 (BA6819AF) where VALL is the AL-pin LOW level voltage, IAL is the AL-pin sink current, VHOL is the HO-pin LOW level voltage, IHO is the HO-pin sink current. Make sure that your application does not exceed the allowable power dissipation of the IC.
The R1 and R2 resistances must be set so as to maintain the Hall amplifier input bias voltage within the range of 0V to (VCC*2V) including the signal amplitude. The Hall device may be affected by power supply noise due to the PCB conductor pattern. If you have this problem, insert a capacitor C1 as shown in Fig. 5. If the conductor lines from the Hall device output terminals to the Hall inputs of the IC are particularly long, noise can be picked up and fed into the inputs. If you have this problem, insert a capacitor C2 as shown in Fig. 5. Note that the Hall inputs have no hysteresis in this IC. Hall current is given by= VCC R1)R2)RH
where RH is the Hall device impedance.
710
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