Datasheet
FUNCTIONAL DEVICE OPERATION
SUPPLIES
Analog Integrated Circuit Device Data
Freescale Semiconductor 73
MC13892
The Buck regulator topology includes an integrated synchronous rectifier, meaning that the rectifying diode is implemented on
the chip as a low ohmic FET. The placement of an external diode is therefore not required, but overall switcher efficiency may
benefit from this. The buck regulators permit a 100% duty cycle operation.
During normal operation, several power modes are possible depending on the loading. For medium and full loading,
synchronous PWM control is the most efficient, while maintaining a constant switching frequency. Two PWM modes are
available: the first mode sacrifices low load efficiency for a continuous switching operation (PWM-NPS). The second mode offers
better low load efficiency by allowing the absence of switching cycles at low output loading (PWM-PS). This pulse skipping
feature improves efficiency by reducing dynamic switching losses by simply switching less often.
In its lowest power mode, the switcher can regulate using hysteresis control known as a Pulse Frequency Modulation (PFM)
control scheme. The frequency spectrum in this case will be a function of input and output voltage, loading, and the external
components. Due to its spectral variance and lighter drive capability, PFM mode is generally reserved for non-active radio modes
and Deep Sleep operation.
Buck modes of operation are programmable for explicitly defined or load-dependent control (Adaptive). Refer to the Buck
regulators section in Power Control System for details.
Common control bits available to each buck regulator may be designated with a suffix “x” within this specification, where x
stands for 1, 2, 3, or 4 (i.e., SWx
= SW1, SW2, SW3, and SW4).
The output voltages of the buck regulators are SPI configurable, and two output ranges are available, individually programmed
with SWxHI for SW2, SW3, and SW4 bucks, SW1 is limited to only one output range. Presets are available for both the Normal
and Standby operation. SW1 and SW2 also include pin controlled DVS operation. When transitioning from one voltage to
another, the output voltage slope is controlled in steps of 25
mV per time step (time step as defined for DVS stepping for SW1
and SW2, fixed at 4.0 μs for SW3 and SW4). This allows for support of dynamic voltage scaling (DVS) by using SPI driven voltage
steps, state machine defined modes, and direct DVSx pin control.
When initially activated, switcher outputs will apply controlled stepping to the programmed value. The soft start feature limits
the inrush current at startup. A built-in current limiter ensures that during normal operation, the maximum current through the coil
is not exceeded. This current limiter can be disabled by setting the SWILIMB bit.
Point of Load feedback is intended for minimizing errors due to board level IR drops.
SWITCHING FREQUENCY
The switchers are driven by a high frequency clock. By default, the PLL generates an effective 3.145728 MHz signal based
upon the 32.768 kHz oscillator signal by multiplying it by 96. To reduce spurious radio channels, the PLL can be programmed
via PLLX[2:0] to different values as shown in
Table 44.
To reduce overall current drain, the PLL is automatically turned off if all switchers are in a PFM mode or turned off, and if the
PLL clock signal is not needed elsewhere in the system. The clocking system provides nearly instantaneously, a high frequency
clock to the switchers when the switchers are activated or exit the PFM mode for PWM mode. The PLL can be configured for
continuous operation by setting the SPI bit PLLEN
= 1.
Table 44. PLL Multiplication Factor
PLLX[2:0]
Multiplication
Factor
Switching Frequency (Hz)
000 84 2 752 512
001 87 2 850 816
010 90 2 949 120
011 93 3 047 424
100 (default) 96 3 145 728
101 99 3 244 032
110 102 3 342 336
111 105 3 440 640