MAX3100EEE+ Maxim Integrated Products, MAX3100EEE+ Datasheet - Page 15

MAX3100EEE+

Manufacturer Part Number

MAX3100EEE+

Description

IC UART SPI/MICRWIRE COMP 16QSOP

Manufacturer

Maxim Integrated Products

Type

SPI/MICROWIRE-Compatible UARTr

Datasheet

1.MAX3100CEE.pdf (24 pages)

Specifications of MAX3100EEE+

Features

Low Power

Number Of Channels

1, UART

Fifo's

8 Byte

Protocol

RS232, RS485

Voltage - Supply

2.7 V ~ 5.5 V

With Irda Encoder/decoder

Yes

With False Start Bit Detection

Yes

With Cmos

Yes

Mounting Type

Surface Mount

Package / Case

16-SSOP (0.150", 3.90mm Width)

Package

16QSOP

Number Of Channels Per Chip

Maximum Data Rate

0.23 MBd

Transmit Fifo

16 Byte

Transmitter And Receiver Fifo Counter

Operating Supply Voltage

3.3|5 V

Minimum Single Supply Voltage

2.7 V

Maximum Processing Temperature

260|300 Â°C

Maximum Supply Current

1 mA

Data Rate

115.2 Kbps

Supply Voltage (max)

5.5 V

Supply Voltage (min)

2.7 V

Supply Current

0.27 mA

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Description/function

SPI/MICROWIRE-compatible UART

Mounting Style

SMD/SMT

No. Of Channels

Supply Voltage Range

2.7V To 5.5V

Operating Temperature Range

-40Â°C To +85Â°C

Digital Ic Case Style

QSOP

No. Of Pins

Uart Type

Asynchronous

Filter Terminals

SMD

Rohs Compliant

Yes

Data Rate Max

230Kbps

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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The MAX3100 X1 input can be driven directly by an

external CMOS clock source. The trip level is approxi-

mately equal to V

to X2 in this mode. If a TTL or non-CMOS clock source

is used, AC couple with a 10nF capacitor to X1. The

peak-to-peak swing on the input should be at least 2V

for reliable operation.

The MAX3100 supports a common multidrop communi-

cation technique referred to as 9-bit mode. In this mode,

the parity bit is set to indicate a message that contains a

header with a destination address. The MAX3100 parity

mask can be set to generate interrupts for this condition.

Operating a network in this mode reduces the process-

ing overhead of all nodes by enabling the slave con-

trollers to ignore most message traffic. This can relieve

the remote processor to handle more useful tasks.

In 9-bit mode, the MAX3100 is set up with 8 bits plus

parity. The parity bit in all normal messages is clear, but

is set in an address-type message. The MAX3100 pari-

ty-interrupt mask is enabled to generate an interrupt on

high parity. When the master sends an address mes-

sage with the parity bit set, all MAX3100 nodes issue an

interrupt. All nodes then retrieve the received byte to

compare to their assigned address. Once addressed,

the node continues to process each received byte. If the

node was not addressed, it ignores all message traffic

until a new address is sent out by the master.

Figure 9. IrDA Timing

NORMAL UART

NORMAL

IrDA

______________________________________________________________________________________

/ 2. No connection should be made

UART FRAME

DATA BITS

9-Bit Networks

SPI/MICROWIRE-Compatible

The parity/9th-bit interrupt is controlled only by the data

in the receive register, and is not affected by data in the

FIFO, so the most effective use of the parity/9th-bit

interrupt is with FIFO disabled. With the FIFO disabled,

received nonaddress words can be ignored and not

even read from the UART.

The MAX3100’s IrDA mode can be used to communicate

with other IrDA SIR-compatible devices, or to reduce

power consumption in opto-isolated applications.

In IrDA mode, a bit period is shortened to 3/16 of a

baud period (1.6µs at 115,200 baud) (Figure 9). A data

zero is transmitted as a pulse of light (TX pin = logic

low, RX pin = logic high).

In receive mode, the RX signal’s sampling is done

halfway into the transmission of a high level. The sam-

pling is done once, instead of three times, as in normal

mode. The MAX3100 ignores pulses shorter than

approximately 1/16 of the baud period. The IrDA device

that is communicating with the MAX3100 must be set to

transmit pulses at 3/16 of the baud period. For compati-

bility with other IrDA devices, set the format to 8-bit

data, one stop, no parity.

The MAX3100 was optimized for direct optocoupler

drive, whereas IrDA modules contain inverting buffers.

Invert the RX and TX outputs as shown in Figure 10.

Figure 10 shows the MAX3100 with an 8051 µC. This

circuit receives IrDA data and outputs standard RS-232

data. Although the 8051 contains an internal UART, it

does not support IrDA or high-speed communications.

The MAX3100 can easily interface to the 8051 to sup-

port these high-performance communications modes.

The 8051 does not have an SPI interface, so communi-

cation with the MAX3100 is accomplished with port pins

and a short software routine (Figure 12a).

The software routine polls the IRQ output to see if data

is available from the MAX3100 UART. It then shifts the

data out, using the 8051 port pins, and transmits it out

the RS-232 side through the MAX3221 driver. The 8051

simultaneously monitors its internal UART for incoming

communications from the RS-232 side, and transmits

this data out the IrDA side through the MAX3100. The

low-level routine (UTLK) is the core routine that sends

and receives data over the port pins to simulate an SPI

port on the 8051. This technique is useful for any 8051-

based MAX3100 port-pin-interfaced application.

8051 Example: IrDA to RS-232 Converter

UART in QSOP-16

SIR IrDA Mode

IrDA Module

MAX3100EEE+ Maxim Integrated Products, MAX3100EEE+ Datasheet - Page 15

MAX3100EEE+

Specifications of MAX3100EEE+

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