Ap3585a/b/c, New prod uc t functional descriptions – Diodes AP3585A/B/C User Manual
Page 11
AP3585A/B/C
Document number: DS36819 Rev.
1 - 2
11 of 18
January 2014
© Diodes Incorporated
AP3585A/B/C
A Product Line of
Diodes Incorporated
NEW PROD
UC
T
Functional Descriptions
(Cont.)
Thermal Shutdown
If the junction temperature of the device reaches the thermal shutdown limit of +160°C, the PWM and the oscillator are turned off and UGATE and
LGATE are driven low, turning off both MOSFETs. When the junction cools to the required level (+140°C nominal), the PWM initiates soft start as
during a normal power-up cycle.
Output Voltage Selection
The output voltage can be programmed to any level between the 0.8V (for AP3585A) internal reference (0.6V for AP3585B/C) to the 80% of V
IN
supply. The lower limitation of output voltage is caused by the internal reference. The upper limitation of the output voltage is caused by the
maximum available duty cycle (80%). This is to leave enough time for over-current detection. Output voltage out of this range is not allowed.
A voltage divider sets the output voltage (Refer to the typical application circuit). In real applications, choose R1 in 100Ω to 10kΩ range and
choose appropriate R2 according to the desired output voltage.
AP3585A
AP3585B/C
PCB Layout Considerations
High speed switching and relatively large peak currents in a synchronous-rectified buck converter make the PCB layout a very important part of
design. Switching current from one power device to another can generate voltage spikes across the impedances of the interconnecting bond wires
and circuit traces. The voltage spikes can degrade efficiency and radiate noise, which results in over-voltage stress on devices. Careful
component placement layout a printed circuit design can minimize the voltage spikes induced in the converter.
Follow the below layout guidelines for optimal performance of AP3585A/B/C.
1. The turn-off transition of the upper MOSFET prior to turn-off, the upper MOSFET was carrying the full load current. During turn-off, current stops
flowing in the upper MOSFET and is picked up by the low side MOSFET. Any inductance in the switched path generates a large voltage spike
during the switching interval. Careful component selections, layout of the critical components, and use shorter and wider PCB traces help in
minimizing the magnitude of voltage spikes.
2. The power components and the PWM controller should be placed firstly. Place the input capacitors, especially the high-frequency ceramic
decoupling capacitors, close to the power switches. Place the output inductor and output capacitors between the MOSFETs and the load. Also
locate the PWM controller near MOSFETs.
3. Use a dedicated grounding plane and use vias to ground all critical components to this layer. Use an immediate via to connect the component to
ground plane including GND of AP3585A/B/C.
4. Apply another solid layer as a power plane and cut this plane into smaller islands of common voltage levels. The power plane should support
the input power and output power nodes. Use copper filled polygons on the top and bottom circuit layers for the PHASE node.
5. The PHASE node is subject to very high dV/dt voltages. Stray capacitance between this island and the surrounding circuitry tend to induce
current spike and capacitive noise coupling. Keep the sensitive circuit away from the PHASE node and keep the PCB area small to limit the
capacitive coupling. However, the PCB area should be kept moderate since it also acts as main heat convection path of the lower MOSFET.
6. The PCB traces between the PWM controller and the gate of MOSFET and also the traces connecting source of MOSFETs should be sized to
carry 2A peak currents.
R2
R2
R1
0.8V
V
OUT
R2
R2
R1
0.6V
V
OUT