MAX13236EETE+T Maxim Integrated Products, MAX13236EETE+T Datasheet - Page 13

TXRX RS-232 250KBPS 1X1 16TQFN

MAX13236EETE+T

Manufacturer Part Number
MAX13236EETE+T
Description
TXRX RS-232 250KBPS 1X1 16TQFN
Manufacturer
Maxim Integrated Products
Type
Transceiverr
Datasheet

Specifications of MAX13236EETE+T

Number Of Drivers/receivers
1/1
Protocol
RS232
Voltage - Supply
3 V ~ 5.5 V
Mounting Type
Surface Mount
Package / Case
16-TQFN Exposed Pad
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
ESD performance depends on a variety of conditions.
Contact Maxim for a reliability report that documents
test setup, test methodology, and test results.
Figure 8a shows the Human Body Model and Figure 8b
shows the current waveform it generates when dis-
charged into a low impedance. This model consists of
a 100pF capacitor charged to the ESD voltage of inter-
est, which is then discharged into the test device
through a 1.5kΩ resistor.
The IEC 61000-4-2 standard covers ESD testing and
performance of finished equipment; it does not specifi-
cally refer to integrated circuits. The MAX13234E–
MAX13237E helps design equipment that meets Level
4 (the highest level) of IEC 61000-4-2, without the need
for additional ESD-protection components. The major
difference between tests done using the Human Body
Model and IEC 61000-4-2 is higher peak current in IEC
61000-4-2, because series resistance is lower in the
IEC 61000-4-2 model. Hence, the ESD withstand volt-
age measured to IEC 61000-4-2 is generally lower than
that measured using the Human Body Model. Figure 9a
shows the IEC 61000-4-2 model and Figure 9b shows
the current waveform for the 8kV, IEC 61000-4-2, Level
4, ESD Contact-Discharge Method.
The Air-Gap Method involves approaching the device
with a charged probe. The Contact-Discharge Method
connects the probe to the device before the probe is
energized.
The capacitor type used for C1–C4 is not critical for
proper operation; polarized or non-polarized capacitors
can be used. The charge pump requires 0.1µF capaci-
tors for V
ages, see Table 2 for required capacitor values. Do not
use values smaller than those listed in Table 2.
Increasing the capacitor values (e.g., by a factor of 2)
reduces ripple on the transmitter outputs and slightly
reduces power consumption. C2, C3, and C4 can be
increased without changing C1’s value. However, do
not increase C1 without also increasing the values
of C2, C3, C4, C
the proper ratios (C1 to the other capacitors). When
using the minimum required capacitor values, make
sure the capacitor value does not degrade excessively
with temperature. If in doubt, use capacitors with a
CC
= +3.3V operation. For other supply volt-
Applications Information
BYPASS1
______________________________________________________________________________________
, and C
ESD Test Conditions
Capacitor Selection
Human Body Model
BYPASS2
3Mbps RS-232 Transceivers with
IEC 61000-4-2
to maintain
larger nominal value. The capacitor’s equivalent series
resistance (ESR), usually rises at low temperatures
influencing the amount of ripple on V+ and V-.
Table 2. Required Minimum Capacitance
Values
In most circumstances, a 0.1µF V
and a 1µF V
cations that are sensitive to power-supply noise, use
capacitors of the same value as charge-pump capaci-
tor C1. Connect bypass capacitors as close to the IC
as possible.
Figure 10 shows two transmitter outputs when exiting
shutdown mode. As they become active, the two trans-
mitter outputs are shown going to opposite RS-232 lev-
els (one transmitter input is high, the other is low). Each
transmitter is loaded with 3kΩ in parallel with 1000pF.
The transmitter outputs display no ringing or undesir-
able transients as they come out of shutdown. Note that
the transmitters are enabled only when the magnitude
of V- exceeds approximately -3V.
Figure 10. Transmitter Outputs when Exiting Shutdown or
Powering Up
Low-Voltage Interface
5V/div
2V/div
5V/div
3.15 to 3.6
3.0 to 3.6
4.5 to 5.5
3.0 to 5.5
0
0
0
V
(V)
CC
V
C1–C4 = 0.1µF
CC
= 3.3V
Transmitter Outputs when Exiting
L
bypass capacitor are adequate. In appli-
C1, C
0.047
(µF)
0.22
0.22
BYPASS2
0.1
5µs/div
Power-Supply Decoupling
C
BYPASS1
(µF)
0.22
0.1
CC
1
1
bypass capacitor
FORCEON = FORCEOFF
T1OUT
T2OUT
READY
Shutdown
C2, C3, C4
0.22
0.33
(µF)
0.1
1
13

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