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TC962 Datasheet, PDF (3/5 Pages) TelCom Semiconductor, Inc – HIGH CURRENT CHARGE PUMP DC-TO-DC CONVERTER
HIGH CURRENT CHARGE PUMP
DC -TO-DC CONVERTER
1
TC962
APPLICATIONS INFORMATION
Theory of Operation
The TC962 is a capacitive pump (sometimes called a
switched capacitor circuit), where four MOSFET switches
control the charge and discharge of a capacitor.
The functional diagram (page 1) shows how the switch-
ing action works. SW1 and SW2 are turned on simulta-
neously, charging CP to the supply voltage, VIN. This as-
sumes that the on resistance of the MOSFETs in series
with the capacitor results in a charging time (3 time con-
stants) that is less than the on time provided by the oscilla-
tor frequency as shown:
3 (RDS(ON) CP) <CP/(0.5 fOSC)
In the next cycle, SW1 and SW2 are turned off and
after a very short interval of all switches being off (this
prevents large currents from occurring due to cross con-
duction), SW3 and SW4 are turned on. The charge in CP is
then transferred to CR, BUT WITH THE POLARITY IN-
VERTED. In this way, a negative voltage is now derived.
Page 1 shows a functional diagram of the TC962. An
oscillator supplies pulses to a flip-flop that is then fed to a
set of level shifters. These level shifters then drive each set
of switches at one-half the oscillator frequency.
The oscillator has two pins that control the frequency of
oscillation. Pin 7 can have a capacitor added that is re-
turned to ground. This will lower the frequency of the
oscillator by adding capacitance to the timing capacitor
internal to the TC962. Grounding pin 6 will turn on a
current source and double the frequency. This will double
the charge current going into the internal capacitor, as well
as any capacitor added to pin 7.
A zener diode has been added to the TC962 for use as
a reference in building external regulators. This zener runs
from pin 1 to ground.
Capacitors
In early charge pump converters, the capacitors were
not considered critical due to the high RDS(ON) of the MOS-
FET switches. In order to understand this, let’s look at a
model of a typical electrolytic capacitor (Figure 1).
Note that one of its characteristics is ESR (equivalent
series resistance). This parasitic resistance winds up in
series with the load. Thus, both voltage conversion effi-
ciency and power conversion efficiency are compromised if
a low ESR capacitor is not used.
In the test circuit, for example, just changing two capaci-
tors, CP and CR, from capacitors with unspecified ESR to low
ESR-type output, impedance changes from 36Ω to 28Ω, an
improvement of 23%!
TELCOM SEMICONDUCTOR, INC.
This applies to all types of capacitors, including film
2 types (polyester, polycarbonate, etc.).
Some applications information suggest that the capaci-
tor is not critical and attribute the limiting factor of the
capacitor to its reactive value. Let's examine this:
XC = 1
2πf C
and
ZC =
XC ,
DS
where DS (duty cycle) = 50%.
3 Thus, ZC ≈ 2.6Ω at f = 12kHz, where C = 10µF.
For the TC962, f = 12,000 Hz, and a typical value of C
would be 10µF. This is a reactive impedance of Ϸ 2.6Ω. If
the ESR is as great as 5Ω, the reactive value is not as critical
as it would first appear, as the ESR would predominate.
The 5Ω value is typical of a general-purpose electrolytic
capacitor.
ESL
ESR
C
4
Figure 1. Typical Electrolytic Capacitor
Latch Up
5 All CMOS structures contain a parasitic SCR. Care must
be taken to prevent any input from going above or below the
supply rail, or latch up will occur. The result of latch up is an
effective short between VDD and VSS. Unless the power
supply input has a current limit, this latch-up phenomena will
result in damage to the device. (See Application Note 31 for
additional information.)
TEST CIRCUIT
6
690Ω
NC
1
8
2
7
+ 10µF
CP
3
TC962
4
5
C OSC
IS V+
I L (+5V)
RL
VOUT
(–5V)
CR + 10µF
7
8
4-39