RXM-433-LC-S Linx Technologies Inc, RXM-433-LC-S Datasheet - Page 6

RXM-433-LC-S

Manufacturer Part Number

RXM-433-LC-S

Description

RECEIVER RF 433MHZ SMT

Manufacturer

Linx Technologies Inc

Series

LCr

Datasheet

1.RXM-433-LC-S.pdf (9 pages)

Specifications of RXM-433-LC-S

Frequency

433MHz

Sensitivity

-95dBm

Data Rate - Maximum

5 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

Voltage - Supply

2.7 V ~ 4.2 V

Operating Temperature

-30°C ~ 70°C

Package / Case

Non-Standard SMD

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Features

Memory Size

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

H&T Electronics

Part Number:

RXM-433-LC-S

Quantity:

361

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BOARD LAYOUT CONSIDERATIONS

Page 10

Basic Remote Control Receiver Circuit

1. No conductive items should be placed within 0.15

2. A groundplane should be placed under the

3. Keep receiver module away from interference sources. Any frequency of

If you are at all familiar with RF devices you may be

concerned

requirements. Fortunately, because of the care

taken by Linx in designing the LC Series,

integrating an LC-S receiver is very straightforward.

This ease of application is a result of the advanced

multi-layer isolated construction of the module. By

adhering to good layout principles and observing a

few basic design rules you can enjoy a

straightforward path to RF success.

Figure

example of a basic remote

control receiver utilizing a

decoder chip from Holtek.

When a key is pressed at

the transmitter, a corres-

ponding pin at the receiver

goes high. A schematic for

the

circuit may be found in

the LC transmitter guide.

These circuits can be

easily modified and clearly

demonstrate the ease of

using the Linx LC modules

for remote control appli-

cations.

in. of the module’s top or sides.

module as shown. In most cases, it will be placed

on the bottom layer. The amount of overall plane area is also critical for the

correct function of many antenna styles and is covered in the next section.

sufficient amplitude to enter the receiver’s front end will reduce system range,

cause bit errors, and may even prevent reception entirely. There are many

possible sources of internally generated interference. High speed logic is one of

the worst in this respect, as fast logic edges have harmonics which extend into

the UHF band and the PCB tracks radiate these harmonics most efficiently.

Microprocessors with external busses are generally incompatible with sensitive

radio receivers. Single-chip microprocessors do not generally pose a problem.

Switching power supplies, oscillators, even relays can also be significant

sources of potential interference. Here again, the single best weapon against

such problems is attention to placement and layout. Filter the supply with a high-

frequency bypass capacitor as described above. Place adequate groundplane

under all potential sources of noise.

transmitter/encoder

about

shows

specialized

Figure 16: Basic Remote Control Receiver

board

layout

adequate groundplane

Always incorporate

GROUNDPLANE

ON LOWER LAYER

GND

VCC

PDN

DATA

HT658

GND

ANT

RECEIVER ANTENNA CONSIDERATIONS

4. Observe appropriate layout practice between the module and its antenna. A

The choice of antennas is one of the most critical and often overlooked design

considerations. The range, performance, and legality of an RF link is critically

dependent upon the type of antenna employed. Proper design and matching of

an antenna is a complex task requiring sophisticated test equipment and a

strong background in principles of RF propagation. While adequate antenna

performance can often be obtained by trial and error methods, you may also

want to consider utilizing a professionally designed antenna such as those

offered by Linx. Our low-cost antenna line is designed to ensure maximum

performance and compliance with Part 15 attachment requirements.

simple trace may suffice for runs of less than 0.25" but longer distances should

be covered using 50 coax or a 50 microstrip transmission line. This is

because the trace leading to the module can effectively contribute to the length

of the antenna, thus lowering its resonant bandwidth. In order to minimize loss

and detuning, a microstrip transmission line is commonly utilized. The term

microstrip refers to a PCB trace running over a groundplane, the width of

which has been calculated to serve as a 50 transmission line between the

module and antenna. This effectively removes the trace as a source of

detuning.The correct trace width can be easily calculated using the information

below.

Figure 17: Microstrip Formulas (Er = Dielectric constant of pc board material)

Dielectric

Constant

2.55

4.8

Width/Height

(W/d)

1.8

Dielectric Characteristic

Constant

Effective

3.59

3.07

2.12

Impedance

50.0

51.0

48.0

Page 11

RXM-433-LC-S Linx Technologies Inc, RXM-433-LC-S Datasheet - Page 6

RXM-433-LC-S

Specifications of RXM-433-LC-S

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