LB1921 Ver la hoja de datos (PDF) - SANYO -> Panasonic
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LB1921 Datasheet PDF : 10 Pages
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LB1921
12. External Resistors
• R4 and R5
The resistors R4 and R5 exist to apply a high-level input to the F/R pin. Since the F/R input has a pull-down
resistor of about 50 kΩ, it is at the low level when open. Apply a voltage of over 4.0 V and under 6.3 V to input a
high level.
• R15
The resistor R15 exists to apply a high-level input to the S/S pin. Since the S/S input has a pull-down resistor of
about 50 kΩ, it is at the low level when open. Apply a voltage of over 4.0 V and under 6.3 V for the start state high
level input. Although dividing the voltage with two resistors, as is done with the F/R input, would improve the
resistance to noise since a lower input impedance can be set up, when noise is not a problem the high level can be
set by connecting a single resistor such as R15. A value of 180 kΩ is recommended.
If VCC rises slowly (less than about 10 V/ms) when power is first applied, the motor may rotate somewhat (in stop
mode). This is because the S/S pin input voltage is resistor divided and the input voltage will be under 2.6 V (the
start input level) when VCC is under 12 V. If the rise rate cannot be increased and this phenomenon is a problem, it
can be resolved by connecting a capacitor between VCC and the S/S pin.
13. Through Currents due to the Direct PWM Scheme
In the direct PWM scheme, through currents flow in the outputs due to transistor switching in applications
implemented with either discrete components or the LB1822. This is due to output transistor delays and parasitic
capacitances. Previously, when this was a problem, additional capacitors were used to resolve the problem. However,
since the LB1921 resolves this problem at the circuit level, no additional external components are required. During
switching, whiskers of less than about 10 ns may be observed on the RF voltage waveform, but these are not a
problem.
14. Oscillator Element
Normally, a crystal oscillator is used with this IC. If the speed control characteristic requirements are not stringent, a
ceramic oscillator could be used. To avoid problems, consult the manufacturer of the oscillator element when
selecting the oscillator element and determining the values of the external resistors and capacitors.
15. Sample IC Internal Power Dissipation Calculation (calculated for VCC = 24 V and typical rated values)
• Power dissipation due to current drain (ICC)
Start mode:
P1 = VCC × ICC1 = 24 × 34 m = 0.82 W
Stop mode:
P2 = VCC × ICC2 = 24 × 8 m = 0.19 W
• Power dissipation when –10 mA is drawn from the 7-V fixed voltage power supply
P3 = (VCC – 7) × 10 m = 17 × 10 m = 0.17 W
• Power dissipation due to output drive current (when the output on duty is 100%)
P4 = {(VCC – 1)2/8 k} + {(VCC – 2)2/10 k}
= (232/8 k) + (222/10 k) = 0.12 W
• Power dissipation in the output drive transistors (when IO = 2 A and the output on duty is 100%)
P5 = VO sat2 × IO = 2.7 × 2 = 5.4 W
Therefore, the total power dissipation for the whole IC is:
In stop mode:
P = P2 = 0.19 W
In start mode:
P = P1 + P3 + P4 + P5 = 6.51 W
(For a output on duty of 100%)
16. IC Temperature Rise Measurement Techniques
• Thermocouple measurement
Attach the thermocouple to a fin on the heat sink when using a thermocouple to measure the IC temperature. This
technique is simple but is subject to large measurement errors when the heat generation is not consistent.
• Measurement using IC internal diode characteristics
We recommend using the parasitic diode that exists between the INT.IN and ground in this IC. (According to
Sanyo data, the temperature characteristic of this diode is about 1.8 V/°C for ID = 1 mA.) The external resistor
must be removed during testing.
No. 5439-9/10
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