NCP590
http://onsemi.com
9
APPLICATION INFORMATION
Output Regulator
The output is controlled by a precision trimmed
reference and error amplifier. The output has saturation
control for regulation while the input voltage is low,
preventing over saturation. Current limit and voltage
monitors complement the regulator design to give safe
operating signals to the processor and control circuits.
Standard linear regulator design circuitry consists of
only an active output driver providing current at the
regulated voltage with resistors from the regulated output
to ground (used in the feedback loop). This provides good
turn-on characteristics from the active PFET output driver,
but turn-off characteristics are determined by the output
capacitor values and impedance of the load in parallel with
the internal resistors in the feedback loop. The turn-off
time in the situation with high impedance loads will be
slow. The NCP590 has active pull-down transistors which
turn on during device turn-off creating efficient fast
turn-offs independent of loading.
Stability Considerations
The input capacitor Cin in Figure 3 is necessary to
provide low impedance to the input of the regulator.
The output or compensation capacitor Coutx helps
determine three main characteristics of a linear regulator:
start-up delay, load transient response and loop stability.
The capacitor value and type should be based on cost,
availability, size and temperature constraints. The
aluminum electrolytic capacitor is the least expensive
solution, but, if the circuit operates at low temperatures
(-25°C to -40°C), both the value and ESR of the capacitor
will vary considerably. The capacitor manufacturer's data
sheet usually provides this information.
Stability is guaranteed at values COUT = 0.7 mF to 4.7 mF
and any ESR within the operating temperature range.
Calculating Power Dissipation in a Dual Output Linear
Regulator
The maximum power dissipation for a dual output
regulator (Figure x) is:
PD = (VIN – VOUT1) x IOUT1 + (VIN – VOUT2 ) x IOUT2
+ VIN x IGND (1)
where:
VIN is the maximum input voltage,
VOUT is the output voltage for each output,
IOUT is the output current for each output in the application,
and
IGND is the quiescent or ground current the regulator
consumes at IOUT
.
Once the value of PD(max) is known, the maximum
permissible value of RqJA can be calculated:
RqJA +(125oC*TA)ńPD(eq. 1)
The value of RqJA can then be compared with those in the
thermal resistance section of the data sheet. Those board
areas with RqJA
's less than the calculated value in equation
2 will keep the die temperature below 125°C. In some
cases, none of the circuit board areas will be sufficient to
dissipate the heat generated by the IC, and an external heat
sink will be required. The current flow and voltages are
shown in the Measurement Circuit Diagram. A chart
showing thermal resistance vs. pcb heat spreader area is
shown below.
Enable
Enabling the two outputs is controlled by two
independent pins, EN1 and EN2. A high (above the high
input threshold) on these logic level input pins causes the
outputs to turn on.
Normal operation allows for input voltages to these pins
to 0.3 V above VIN. It is sometimes necessary to interface
logic outputs from different operating voltages into these
pins. This happens when standard operating system
voltages must interface together (i.e., 5 V to 3.3 V systems).
For example, a 5 V control voltage is needed to control
the NCP590 operating with VIN = 3.6 V. The input current
into the ENx pin can be kept to safe levels by adding a 100 k
resistor in series with the 5 V control drive voltage. This
will keep the input voltage in compliance with the
maximum ratings and will allow control of the output. Use
of this setup will affect turn-on time and will increase the
enable current higher than the input current specified in the
electrical parameter tables.