ncp1395 ON Semiconductor, ncp1395 Datasheet - Page 16
ncp1395
Manufacturer Part Number
ncp1395
Description
High Performance Resonant Mode Controller
Manufacturer
ON Semiconductor
Datasheet
1.NCP1395.pdf
(27 pages)
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34
frequency and the minimum switching frequency. In LLC
configurations, for circuits working above the resonant
frequency, a high precision is required on the minimum
frequency, hence the "3% specification. This minimum
switching frequency is actually reached when no feedback
closes the loop. It can happen during the startup sequence,
a strong output transient loading or in a short−circuit
condition. By installing a resistor from pin 1 to AGND, the
minimum frequency is set. Using the same philosophy,
wiring a resistor from pin 2 to AGND will set the maximum
frequency excursion. To improve the circuit protection
features, we have purposely created a dead zone, where the
feedback loop has no action. This is typically below 1.3 V.
Figure 34 details the arrangement where the internal
voltage (that drives the VCO) varies between 0 and 3.6 V.
However, to create this swing, the feedback pin (to which
the optocoupler emitter connects), will need to swing
typically between 1.3 V and 6.0 V.
in case the FB pin cannot rise above 1.3 V (to actually close
the loop) in less than a duration imposed by the
programmable timer. Please refer to the fault section for
detailed operation of this mode.
VCO control voltage will be constrained between 0 V and
3.6 V, whereas the feedback loop will drive pin 5 (FB)
between 1.3 V and 6.0 V. If we take the external excursion
numbers, 1.3 V = 50 kHz, 6.0 V = 1.0 MHz, then the VCO
slope will then be
The designer needs to program the maximum switching
Figure 34. The OPAMP arrangement limits the VCO
This technique allows us to detect a fault on the converter
As shown in Figure 34, the internal dynamics of the
internal modulation signal between 0 and 5.0 V.
V
CC
VFB = 1.3−6 V
FB
Rfb
1 Meg−50 k
4.7
+ 202 kHz V.
+
1.3 V
+
−
To VCO
0 to 3.6 V
http://onsemi.com
NCP1395A/B
16
depending on the feedback pin voltage level in a different
frequency clamp combination.
now been reduced to 300 k/5.0 = 62.5 kHz/V. This offers
a mean to magnify the feedback excursion on systems
where the load range does not generate a wide switching
frequency excursion. Due to this option, we will see how
it becomes possible to observe the feedback level and
implement skip cycle at light loads. It is important to note
that the frequency evolution does not have a real linear
relationship with the feedback voltage. This is due to the
deadtime presence which stays constant as the switching
period changes.
Figures 35 and 36 portray the frequency evolution
Fault
Fault
area
area
Fault
Fault
area
area
Please note that the previous small signal VCO slope has
Fmax
Fmax
Fmax
Fmax
Figure 35. Maximal default excursion, Rt = 120 kW
Fmin
Fmin
Fmin
Fmin
was programmed as well as a different maximum
Figure 36. Here a different minimum frequency
F
F
F
F
Î
Ì
Ó Ó
Ö Ö
A&B
A&B
A&B
A&B
0.6 V
0.6 V
0.6 V
0.6 V
on pin 1 and Rfmax = 35 kW on pin 2.
1.3 V
1.3 V
1.3 V
1.3 V
frequency excursion.
D VFB = 4.7V
D VFB = 4.7V
D VFB = 4.7 V
D VFB = 4.7 V
Ï Ï Ï Ï
Ñ Ñ Ñ Ñ
Ï Ï Ï Ï
Ñ Ñ Ñ Ñ
Ï Ï Ï Ï
Ñ Ñ Ñ Ñ
Ô Ô Ô Ô
Ò Ò Ò Ò
Ô Ô Ô Ô
Ò Ò Ò Ò
6 V
6 V
6 V
6 V
No variations
No variations
No variations
No variations
D Fsw = 950 kHz
D Fsw = 950 kHz
D Fsw = 300 kHz
D Fsw = 300 kHz
VFB
VFB
VFB
VFB
1 MHz
1 MHz
50 kHz
50 kHz
450 kHz
450 kHz
150 kHz
150 kHz
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