RX5000 RFM, RX5000 Datasheet - Page 6

RX5000

Manufacturer Part Number

RX5000

Description

ASH RX 115.2 KBPS 433.92 MHZ

Manufacturer

RFM

Type

Receiverr

Datasheet

1.RX5000.pdf (10 pages)

Specifications of RX5000

Frequency

433.92MHz

Sensitivity

-109dBm

Data Rate - Maximum

115.2kbps

Modulation Or Protocol

ASK, OOK

Applications

General Data Transfer

Current - Receiving

3.8mA

Data Interface

PCB, Surface Mount

Antenna Connector

PCB, Surface Mount

Voltage - Supply

2.2 V ~ 3.7 V

Operating Temperature

-40°C ~ 85°C

Package / Case

SM-20L

Operating Frequency

434.12 MHz

Operating Supply Voltage

2.5 V or 3.3 V

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Mounting Style

SMD/SMT

Supply Current

3 mA

Lead Free Status / RoHS Status

Lead free by exemption / RoHS compliant by exemption

Features

Memory Size

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

583-1074-2

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

RX5000

Manufacturer:

MOT

Quantity:

310

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When the receiver is placed in the power-down (sleep) mode, the

output impedance of BBOUT becomes very high. This feature

helps preserve the charge on the coupling capacitor to minimize

data slicer stabilization time when the receiver switches out of the

sleep mode.

Data Slicers

The CMPIN pin drives two data slicers, which convert the analog

signal from BBOUT back into a digital stream. The best data slicer

choice depends on the system operating parameters. Data slicer

DS1 is a capacitively-coupled comparator with provisions for an

adjustable threshold. DS1 provides the best performance at low

signal-to-noise conditions. The threshold, or squelch, offsets the

comparator’s slicing level from 0 to 90 mV, and is set with a resistor

between the RREF and THLD1 pins. This threshold allows a trade-

off between receiver sensitivity and output noise density in the no-

signal condition. For best sensitivity, the threshold is set to 0. In

this case, noise is output continuously when no signal is present.

This, in turn, requires the circuit being driven by the RXDATA pin

to be able to process noise (and signals) continuously.

This can be a problem if RXDATA is driving a circuit that must

“sleep” when data is not present to conserve power, or when it its

necessary to minimize false interrupts to a multitasking processor.

In this case, noise can be greatly reduced by increasing the

threshold level, but at the expense of sensitivity. The best 3 dB

bandwidth for the low-pass filter is also affected by the threshold

level setting of DS1. The bandwidth must be increased as the

threshold is increased to minimize data pulse-width variations with

signal amplitude.

Data slicer DS2 can overcome this compromise once the signal

level is high enough to enable its operation. DS2 is a “dB-below-

peak” slicer. The peak detector charges rapidly to the peak value

of each data pulse, and decays slowly in between data pulses

(1:1000 ratio). The slicer trip point can be set from 0 to 120 mV

below this peak value with a resistor between RREF and THLD2.

A threshold of 60 mV is the most common setting, which equates

to “6 dB below peak” when RFA1 and RFA2 are running a 50%-

50% duty cycle. Slicing at the “6 dB-below-peak” point reduces the

signal amplitude to data pulse-width variation, allowing a lower 3

dB filter bandwidth to be used for improved sensitivity.

DS2 is best for ASK modulation where the transmitted waveform

has been shaped to minimize signal bandwidth. However, DS2 is

subject to being temporarily “blinded” by strong noise pulses,

which can cause burst data errors. Note that DS1 is active when

DS2 is used, as RXDATA is the logical AND of the DS1 and DS2

outputs. DS2 can be disabled by leaving THLD2 disconnected. A

non-zero DS1 threshold is required for proper AGC operation.

AGC Control

The output of the Peak Detector also provides an AGC Reset

signal to the AGC Control function through the AGC comparator.

The purpose of the AGC function is to extend the dynamic range

of the receiver, so that the receiver can operate close to its

transmitter when running ASK and/or high data rate modulation.

The onset of saturation in the output stage of RFA1 is detected and

generates the AGC Set signal to the AGC Control function. The

AGC Control function then selects the 5 dB gain mode for RFA1.

The AGC Comparator will send a reset signal when the Peak

Detector output (multiplied by 0.8) falls below the threshold voltage

for DS1.

A capacitor at the AGCCAP pin avoids AGC “chattering” during the

time it takes for the signal to propagate through the low-pass filter

and charge the peak detector. The AGC capacitor also allows the

hold-in time to be set longer than the peak detector decay time to

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avoid AGC chattering during runs of “0” bits in the received data

stream. Note that AGC operation requires the peak detector to be

functioning, even if DS2 is not being used. AGC operation can be

defeated by connecting the AGCCAP pin to Vcc. The AGC can be

latched on once engaged by connecting a 150 kilohm resistor

between the AGCCAP pin and ground in lieu of a capacitor.

Receiver Pulse Generator and RF Amplifier Bias

The receiver amplifier-sequence operation is controlled by the

Pulse Generator & RF Amplifier Bias module, which in turn is

controlled by the PRATE and PWIDTH input pins, and the Power

Down (sleep) Control Signal from the Bias Control function.

In the low data rate mode, the interval between the falling edge of

one RFA1 ON pulse to the rising edge of the next RFA1 ON pulse

interval can be adjusted between 0.1 and 5 µs. In the high data rate

mode (selected at the PWIDTH pin) the receiver RF amplifiers

operate at a nominal 50%-50% duty cycle. In this case, the start-

to-start period t

PRATE resistor over a range of 0.1 to 1.1 µs.

In the low data rate mode, the PWIDTH pin sets the width of the

ON pulse t

width t

the low data rate mode). The ON pulse width t

between 0.55 and 1 µs. However, when the PWIDTH pin is

connected to Vcc through a 1 M resistor, the RF amplifiers operate

at a nominal 50%-50% duty cycle, facilitating high data rate

operation. In this case, the RF amplifiers are controlled by the

PRATE resistor as described above.

Both receiver RF amplifiers are turned off by the Power Down

Control Signal, which is invoked in the sleep mode.

Receiver Mode Control

The receiver operating modes – receive and power-down (sleep),

are controlled by the Bias Control function, and are selected with

the CNTRL1 and CNTRL0 control pins. Setting CNTRL1 and

CNTRL0 both high place the unit in the receive mode. Setting

CNTRL1 and CNTRL0 both low place the unit in the power-down

(sleep) mode. CNTRL1 and CNTRL0 are CMOS compatible

inputs. These inputs must be held at a logic level; they cannot be

left unconnected.

Receiver Event Timing

Receiver event timing is summarized in Table 1. Please refer to

this table for the following discussions.

Turn-On Timing

The maximum time t

operational at turn on is influenced by two factors. All receiver

circuitry will be operational 5 ms after the supply voltage reaches

2.2 Vdc. The BBOUT-CMPIN coupling-capacitor is then DC

stabilized in 3 time constants

stable receiver operation for a 10 ms power supply rise time is:

Sleep and Wake-Up Timing

The maximum transition time from the receive mode to the power-

down (sleep) mode t

both low (1 µs fall time).

The maximum transition time t

receive mode is 3*t

coupling-capacitor time constant. When the operating temperature

is limited to 60 oC, the time required to switch from sleep to receive

is dramatically less for short sleep times, as less charge leaks

away from the BBOUT- CMPIN coupling capacitor.

PRI

= 15 ms + 3*t

is set by a resistor between the PRATE pin and ground. The

PW2

PW1

to RFA2 is set at 1.1 times the pulse width to RFA1 in

PRC

to RFA1 with a resistor to ground (the ON pulse

BBC

for ON pulses to RFA1 are controlled by the

required for the receive function to become

, where t

is 10 µs after CNTRL1 and CNTRL0 are

BBC

(3*t

from the sleep mode to the

BBC

is the BBOUT-CMPIN

). The total turn-on time to

PW1

can be adjusted

RX5000 - 4/7/08

Page 6 of 10

RX5000 RFM, RX5000 Datasheet - Page 6

RX5000

Specifications of RX5000

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