Datasheet
Table Of Contents
- Figure 1. Application circuit
- 1 Pin settings
- 2 Maximum ratings
- 3 Electrical characteristics
- 4 Functional description
- 5 Application information
- 5.1 Input capacitor selection
- 5.2 Inductor selection
- 5.3 Output capacitor selection
- 5.4 Compensation network
- 5.5 Thermal considerations
- 5.6 Layout considerations
- 5.7 Application circuit
- Figure 18. Demonstration board application circuit
- Table 9. Component list
- Figure 19. PCB layout (component side)
- Figure 20. PCB layout (bottom side)
- Figure 21. PCB layout (front side)
- Figure 22. Junction temperature vs output current
- Figure 23. Junction temperature vs output current
- Figure 24. Junction temperature vs output current
- Figure 25. Efficiency vs output current
- Figure 26. Efficiency vs output current
- Figure 27. Efficiency vs output current
- Figure 28. Load regulation
- Figure 29. Line regulation
- Figure 30. Short circuit behavior
- Figure 31. Load transient: from 0.1 A to 0.7 A
- Figure 32. Soft-start
- 6 Application ideas
- 7 Package mechanical data
- 8 Order codes
- 9 Revision history
Application ideas L5980
34/42 Doc ID 13003 Rev 6
6 Application ideas
6.1 Positive buck-boost
The L5980 can implement the step up/down converter with a positive output voltage.
Figure 33 shows the schematic: one power MOSFET and one Schottky diode are added to
the standard buck topology to provide 12 V output voltage with input voltage from 2.9 V to 18
V.
Figure 33. Positive buck-boost regulator
The relationship between input and output voltage is:
Equation 30
So the duty cycle is:
Equation 31
The output voltage isn’t limited by the maximum operating voltage of the device (18 V),
because the output voltage is sensed only through the resistor divider. The external power
MOSFET maximum drain to source voltage, must be higher than output voltage; the
maximum gate to source voltage must be higher than the input voltage (in Figure 33, if V
IN
is
higher than 16 V, the gate must be protected through zener diode and resistor)
The current flowing through the internal power MOSFET is transferred to the load only
during the OFF time, so according to the maximum DC switch current (0.7 A), the maximum
output current for the buck boost topology can be calculated from the following equation.
V
OUT
V
IN
D
1D–
-------------
⋅=
D
V
OUT
V
OUT
V
IN
+
------------------------------=