MAX3040–MAX3045
±10kV ESD-Protected, Quad 5V RS-485/RS-422
Transmitters
_______________________________________________________________________________________
9
IEC 1000-4-4 Burst/Electrical Fast
Transient Test Levels
(For Communication Lines)
The stresses are applied while the MAX3040–MAX3045
are powered up. Test results are reported as:
1) Normal performance within the specification limits.
2) Temporary degradation or loss of function or perfor-
mance which is self-recoverable.
3) Temporary degradation, loss of function or perfor-
mance requiring operator intervention, such as sys-
tem reset.
4) Degradation or loss of function not recoverable due
to damage.
The MAX3040–MAX3045 meets classification 2 listed
above. Additionally, the MAX3040–MAX3045 will not
latchup during the IEC burst stress events.
Hot-Swap Capability
Hot-Swap Inputs
When circuit boards are plugged into a “hot” back-
plane, there can be disturbances to the differential sig-
nal levels that could be detected by receivers
connected to the transmission line. This erroneous data
could cause data errors to an RS-485/RS-422 system.
To avoid this, the MAX3040–MAX3045 have hot-swap
capable inputs.
When a circuit board is plugged into a “hot” backplane
there is an interval during which the processor is going
through its power-up sequence. During this time, the
processor’s output drivers are high impedance and will
be unable to drive the enable inputs of the
MAX3040–MAX3045 (EN, EN, EN_) to defined logic lev-
els. Leakage currents from these high impedance dri-
vers, of as much as 10A, could cause the enable
inputs of the MAX3040–MAX3045 to drift high or low.
Additionally, parasitic capacitance of the circuit board
could cause capacitive coupling of the enable inputs to
either GND or VCC. These factors could cause the
enable inputs of the MAX3040–MAX3045 to drift to lev-
els that may enable the transmitter outputs (Y_ and Z_).
To avoid this problem, the hot-swap input provides a
method of holding the enable inputs of the
MAX3040–MAX3045 in the disabled state as VCC
ramps up. This hot-swap input is able to overcome the
leakage currents and parasitic capacitances that may
pull the enable inputs to the enabled state.
Hot-Swap Input Circuitry
In the MAX3040–MAX3045 the enable inputs feature
hot-swap capability. At the input there are two NMOS
devices, Q1 and Q2 (Figure 9). When VCC is ramping
up from 0, an internal 10s timer turns on Q2 and sets
the SR latch, which also turns on Q1. Transistors Q2, a
700A current sink, and Q1, an 85A current sink, pull
EN to GND through a 5.6k
resistor. Q2 is designed to
pull the EN input to the disabled state against an exter-
nal parasitic capacitance of up to 100pF that is trying to
enable the EN input. After 10s, the timer turns Q2 off
and Q1 remains on, holding the EN input low against
three-state output leakages that might enable EN. Q1
remains on until an external source overcomes the
U = HIGH-VOLTAGE SOURCE
RC = CHARGING RESISTOR
CE = ENERGY STORAGE CAPACITOR
RS = PULSE DURATION SHAPING RESISTOR
RM = IMPEDANCE MATCHING RESISTOR
CD = DC BLOCKING CAPACITOR
SPARK GAP
U
RC
RS
RM
CD
CE
50
COAXIAL
OUTPUT
Figure 7. Simplified Circuit Diagram of a Fast Transient/Burst
Generator
REPETITION PERIOD (DEPENDS ON THE TEST VOLTAGE LEVER,
IN CONFORMITY WITH THE VALUES INDICATED IN 6.1.2).
BURST
BURST DURATION
BURST PERIOD 300ms
PULSE
15ms
Figure 8. General Graph of a Fast Transient Burst