RXM-433-LR_ Linx Technologies Inc, RXM-433-LR_ Datasheet - Page 4

RXM-433-LR_

Manufacturer Part Number

RXM-433-LR_

Description

RECEIVER 433MHZ LR SERIES

Manufacturer

Linx Technologies Inc

Series

LRr

Datasheet

1.RXM-433-LR_.pdf (11 pages)

Specifications of RXM-433-LR_

Frequency

433MHz

Sensitivity

-112dBm

Data Rate - Maximum

10 kbps

Modulation Or Protocol

ASK, OOK

Applications

ISM, Garage Door Openers, RKE

Current - Receiving

5mA

Data Interface

PCB, Surface Mount

Antenna Connector

PCB, Surface Mount

Features

Long Range

Voltage - Supply

2.7 V ~ 3.6 V

Operating Temperature

-40°C ~ 70°C

Package / Case

Non-Standard SMD

Board Size

20.6 mm x 16 mm x 3.2 mm

Minimum Operating Temperature

- 40 C

Supply Voltage (min)

2.7 V

Product

RF Modules

Maximum Frequency

433.92 MHz

Supply Voltage (max)

3.6 V

Maximum Operating Temperature

+ 70 C

Memory Size

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Memory Size

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

RXM-433-LR
RXM-433-LR

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

RXM-433-LR_

Manufacturer:

LNX

Quantity:

391

Current page: 4 of 11
Download datasheet (474Kb)

POWER SUPPLY REQUIREMENTS

USING THE PDN PIN

USING THE RSSI PIN

Page 6

The module does not have an internal voltage regulator, therefore it requires a

clean, well-regulated power source. While it is preferable to power the unit from

a battery, it can also be operated from a power supply as long as noise is less

than 20mV. Power supply noise can significantly affect the receiver sensitivity,

therefore; providing clean power to the module should be a high priority during

design.

A 10Ω resistor in series with the supply followed by a

10µF tantalum capacitor from V

in cases where the quality of the supply power is poor.

Operation from 4.3V to 5.2V requires an external

330Ω series resistor to prevent V

3.6V. These values may need to be adjusted

depending on the noise present on the supply line.

The Power Down (PDN) line can be used to power down the receiver without the

need for an external switch. This line has an internal pull-up, so when it is held

high or simply left floating, the module will be active.

When the PDN line is pulled to ground, the receiver will enter into a low-current

(<40µA) power-down mode. During this time the receiver is off and cannot

perform any function. It may be useful to note that the startup time coming out of

power-down will be slightly less than when applying V

The PDN line allows easy control of the receiver state from external components,

like a microcontroller. By periodically activating the receiver, checking for data,

then powering down, the receiver’s average current consumption can be greatly

reduced, saving power in battery-operated applications.

Note: The voltage on the PDN line should not exceed V

voltage source, such as a 5V microcontroller, an open collector line should be used or a

diode placed in series with the control line. Either method will prevent damage to the

module by preventing 5V from being placed on the PDN line, while allowing the line to be

pulled low.

The receiver’s Received Signal Strength Indicator (RSSI) line serves a variety of

functions. This line has a dynamic range of 80dB (typical) and outputs a voltage

proportional to the incoming signal strength. It should be noted that the RSSI

levels and dynamic range will vary slightly from part to part. It is also important

to remember that RSSI output indicates the strength of any in-band RF energy

and not necessarily just that from the intended transmitter; therefore, it should be

used only to qualify the level and presence of a signal.

The RSSI output can be utilized during testing or even as a product feature to

assess interference and channel quality by looking at the RSSI level with all

intended transmitters shut off. The RSSI output can also be used in direction-

finding applications, although there are many potential perils to consider in such

systems. Finally, it can be used to save system power by “waking up” external

circuitry when a transmission is received or crosses a certain threshold. The

RSSI output feature adds tremendous versatility for the creative designer.

to ground will help

from exceeding

. When used with a higher

Figure 10: Supply Filter

Vcc IN

10Ω

Vcc TO

MODULE

10μF

THE DATA OUTPUT

Figure 11: LR Receiver and LS Decoder

RECEIVING DATA

The CMOS-compatible data output is normally used to drive a digital decoder IC

or a microprocessor that is performing the data decoding. In addition, the module

can be connected to an RS-232 level converter chip, like the MAX232, to a Linx

USB module for interfacing to a PC, or to a standard UART. Since a UART uses

high marking to indicate the absence of data, a designer using a UART may wish

to insert a logic inverter between the data output of the receiver and the UART.

The receiver’s output may appear to switch randomly in the absence of a

transmitter. This is a result of the receiver sensitivity being below the noise floor

of the board. This noise can be handled in software by implementing a noise-

tolerant protocol as described in Application Note AN-00160. If a software

solution is not appropriate, the squelch circuit in the figure below can be used

and the designer can make a compromise between noise level and range.

Once an RF link has been established, the challenge becomes how to effectively

transfer data across it. While a properly designed RF link provides reliable data

transfer under most conditions, there are still distinct differences from a wired link

that must be addressed. Since the LR modules do not incorporate internal

encoding / decoding, the user has tremendous flexibility in how data is handled.

It is always important to separate what types of transmissions are technically

possible from those that are legally allowable in the country of intended

operation. Application Notes AN-00125 and AN-00140 should be reviewed along

with Part 15, Section 231 for further details on acceptable transmission content.

If you want to transfer simple control or status signals, such as button presses or

switch closures, and your product does not have a microprocessor on board or

you wish to avoid protocol development, consider using an encoder and decoder

IC set. These chips are available from a wide range of manufacturers including

Linx, Microchip, and Holtek. These chips take care of all encoding and decoding

functions and generally provide a number of data pins to which switches can be

directly connected. In addition, address bits are usually provided for security and

to allow the addressing of multiple receivers independently. These ICs are an

excellent way to bring basic remote control / status products quickly and

inexpensively to market. Additionally, it is a simple task to interface with

inexpensive microprocessors such as the Microchip PIC or one of many IR,

remote control, DTMF, and modem ICs.

RSSI

0.1μ

500k

VCC

LMV393

VCC

200k

DATA

VCC

Squelched Data

MAX4714

Page 7

RXM-433-LR_ Linx Technologies Inc, RXM-433-LR_ Datasheet - Page 4

RXM-433-LR_

Specifications of RXM-433-LR_

Available stocks

Related parts for RXM-433-LR_