Rf front-end and mixer, Microcontroller, pll and vco circuits, If amplifiers and saw filters – Lectrosonics SRb_SRb5P User Manual

SRb5P and SRb Dual Receivers

LECTROSONICS, INC.

6

RF Front-End and Mixer

Each antenna signal is first passed through a high qual-

ity SAW filter to reject high power RF signals above and

below the operating frequency. A high current amplifier

follows the SAW filters and passes the signal to an in-

ternal splitter so that both antenna signals are available

to both receivers for SmartDiversity™ reception.
The mixer in each receiver takes the signal from the

PLL to generate the first IF signal, with both PLL circuits

fed from a common reference oscillator to maintain

signal phase through the IF sections.

Microcontroller, PLL and VCO Circuits

The 8-bit microprocessor is the “heart” of the SRb5P

and SRb receivers. It monitors user command inputs

from the front panel control buttons and numerous other

internal signals such as RF level, audio levels, pilot tone

levels and transmitter battery status. Outputs from the

microcontroller drive the LCD display and backlight, and

control the squelch, the audio output attenuator, the

PLL/VCO circuits and the antenna phase switch.

IF Amplifiers and SAW Filters

The first IF stage employs two SAW (surface acoustic

wave) filters. The use of two filters significantly increas-

es the depth of filtering while preserving sharp skirts,

constant group delay, and wide bandwidth. Though ex-

pensive, this special type of filter allows primary filtering

as early as possible, at as high a frequency as possible,

before high gain is applied, to deliver maximum image

rejection. Since these filters are made of quartz, they

are very temperature stable.
After the SAW filter, the IF signal is converted to 350

kHz in receiver 1 and 250 kHz in receiver 2. Only then

is the majority of the gain applied, just before the signal

is converted to audio with a pulse counting detector.

Although these IF frequencies are unconventional in a

wide deviation (±75 kHz) system, it offers outstanding

AM rejection over a very wide range of signal strengths

and improved noise performance.

Digital Pulse Counting Detector

The receiver uses an elegantly simple, yet highly effec-

tive digital pulse detector to demodulate the FM signal,

rather than a conventional quadrature detector. This

unusual design eliminates thermal drift, improves AM

rejection, and provides very low audio distortion.

DSP-Based Pilot Tone

The Digital Hybrid system design uses a DSP gener-

ated ultrasonic pilot tone to control the receiver audio

muting (squelch). The pilot tone frequency is different

for each of the 256 frequencies in the tuning range of a

system (frequency block). This eliminates squelch prob-

lems in multichannel systems where a pilot tone signal

can appear in the wrong receiver via intermodulation

products.

The DSP generated pilot tone also eliminates fragile

crystals, allowing the receiver to survive shocks and

mishandling much better than older analog-based pilot

tone systems.

Note: This description applies only to the Digital

Hybrid mode. In 200 Series, IFB and Mode 6

compatibility, only one pilot tone frequency is used

on all channels, emulating the original crystal-

based system. In other compatibility modes, no

pilot tone is used.

SmartSquelch

™

Any squelching system faces inevitable trade-offs:

squelch too aggressively and valuable audio information

may be lost. Squelch too little and excessive noise may

be heard. Respond too rapidly and the audio will sound

“choppy.” Respond too sluggishly and syllables or entire

words can be cut off.
SmartSquelch

TM

combines several techniques to achieve

an optimal balance, removing distracting noise, without

the squelching action itself becoming a distraction. One

of these techniques involves waiting for a word or syl-

lable to complete before squelching. Another technique

incorporates recent squelching history and recent signal

strength, adjusting squelching behavior dynamically for

the most serviceable result under variable conditions. Us-

ing these and other techniques, the SRa5P and SRa can

deliver acceptable audio quality from otherwise unusable

signals.

Smart Noise Reduction (SmartNR

™

)

Note: The SmartNR setting is user selectable

only in the Digital Hybrid compatibility mode. In

other modes, noise reduction is applied in such a

way as to emulate the original analog system as

accurately as possible and is not user adjustable.

The wide dynamic range of digital hybrid technology,

combined with flat response to 20 kHz, makes it pos-

sible to hear the -120 dBV noise floor in the mic pre-

amp, or the (usually) greater noise from the microphone

itself. To put this in perspective, the noise generated

by the recommended 4k bias resistor of many electret

lavaliere mics is –119 dBV and the noise level of the

microphone’s electronics is even higher. In order to

reduce this noise the receiver is equipped with a Smart

Noise Reduction algorithm, which removes hiss without

sacrificing audio high frequency response.
The Smart Noise Reduction algorithm works by at-

tenuating only those portions of the audio signal that fit

a statistical profile for randomness or “electronic hiss.”

Because it is much more than a sophisticated variable

low pass filter, the transparency of the audio signal is

preserved. Desired high frequency signals having some

coherence are not affected, such as speech sibilance

and tones.