Datasheet
characteristics required. Resistor R discharges tube
capacitance C to 10% of the initial voltage in 2.3 x RC
seconds. So, for example, a 15kW value for R discharges
100pF tube grid or anode from 40V to 4V in 3.5µs, but
draws an additional 2.7mA from the driver when either
output is high.
Power Dissipation
Take care to ensure that the maximum package dissipa-
tion ratings for the chosen package are not exceeded.
Over-dissipation is unlikely to be an issue when driving
static tubes, but the peak currents are usually higher for
multiplexed tubes. When using multiple driver devices,
try to share the average dissipation evenly between the
drivers.
Determine the power dissipation (P
D
) for the MAX6922/
MAX6932/MAX6933/MAX6934 for static tube drivers with
the following equation:
P
D
= (V
CC
x I
CC
) + (V
BB
x I
BB
) + ((V
BB
- V
H
) x
I
ANODE
x A))
where:
A = number of anodes driven (maximum of 32 with the
MAX6922/MAX6934).
I
ANODE
= maximum anode current.
(V
BB
- V
H
) is the output voltage drop at the given maxi-
mum anode current I
OUT
.
A static tube dissipation example follows:
V
CC
= 5V ±5%, V
BB
= 10V to 18V, A = 32, I
OUT
= 2mA
P
D
= (5.25V x 1.5mA)+ (18V x 2.2mA) +
((2.5V x 2mA/25mA) x 2mA x 32) = 60mW
Determine the power dissipation (PD) for the MAX6922/
MAX6932/MAX6933/MAX6934 for multiplex tube drivers
with the following equation:
P
D
= (V
CC
x I
CC
) + (V
BB
x I
BB
) + ((V
BB
- V
H
) x
I
ANODE
x A) + ((V
BB
- V
H
) x I
GRID
))
where:
A = number of anodes driven.
G = number of grids driven.
I
ANODE
= maximum anode current.
I
GRID
= maximum grid current.
The calculation presumes all anodes are on, but only one
grid is on. The calculated P
D
is the worst case, presum-
ing one digit is always being driven with all its anodes lit.
Actual P
D
can be estimated by multiplying this P
D
figure
by the actual tube drive duty cycle, taking into account
interdigit blanking and any PWM intensity control.
A multiplexed tube dissipation example follows:
V
CC
= 5V ±5%, V
BB
= 36V to 42V, A = 20, G = 12,
I
ANODE
= 0.4mA, I
GRID
= 24mA
P
D
= (5.25V x 1.5mA)+ (42V x 2.2mA) +
((2.5V x 0.4mA/25mA) x 0.4mA x 20) +
((2.5V x 24mA/25mA) x 24mA) = 158mW
Thus, for a 44-pin PLCC package (T
JA
= 1/0.0133 =
75.188°C/W from Absolute Maximum Ratings), the maxi-
mum allowed ambient temperature T
A
is given by:
T
J(MAX)
= T
A
+ (P
D
x T
JA
) = +150°C = T
A
+ (0.158 x
75.188°C/W)
So T
A
= +138°C.
This means that the driver can be operated in this
application with a PLCC package up to the +125°C
maximum operating temperature.
Power-Supply Considerations
The MAX6922/MAX6932/MAX6933/MAX6934 operate
with multiple power-supply voltages. Bypass the V
CC
,
V
BB
, and V
SS
(MAX6932/MAX6933/MAX6934 only) pow-
er-supply pins to GND with 0.1µF capacitors close to the
device. The MAX6932/MAX6933/MAX6934 may be oper-
ated with V
SS
tied to GND if a negative bias supply is not
required. For multiplex applications, it may be necessary
to add an additional bulk electrolytic capacitor of 1µF or
greater to the V
BB
supply.
Power-Supply Sequencing
The order of the power-supply sequencing is not import-
ant. These ICs are damaged if any combination of V
CC
,
V
BB
, and V
SS
is grounded while the other supply or
supplies are maintained up to their maximum ratings.
However, as with any CMOS device, do not drive the logic
inputs if the logic supply V
CC
is not operational because
the input protection diodes clamp the signals.
Cascading Drivers
(MAX6922/MAX6932/MAX6934 Only)
Multiple driver ICs may be cascaded, as shown in the
Typical Application Circuit, by connecting each driver’°s
DOUT to DIN of the next drivers. Devices may be cas-
caded at the full 5MHz CLK speed when V
CC
≥ 4.5V.
When V
CC
<4.5V, the longer propagation delay (t
DO
)
limits the maximum cascaded CLK to 4MHz.
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MAX6922/MAX6932/
MAX6933/MAX6934
27-, 28-, and 32-Output, 76V,
Serial-Interfaced VFD Tube Drivers