Robotron G3E Shortwave Receiver User Manual g3 user s manual
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WiNRADiO®
G303 Shortwave Receiver
User’s Guide
- ii -
Published by
WiNRADiO Communications
PO Box 6118, St Kilda Road, Melbourne 3004, Australia
© 2004 WiNRADiO Communications, Melbourne
All rights reserved. No part of this book may be reproduced or transmitted in any form or by
any means without the written permission of the publisher.
Trademarks
WiNRADiO, G3, G303 and Radio Basic are trademarks of WiNRADiO Communications
All other brand and product names are trademarks of their respective owners.
Patents
WiNRADiO technology is protected by US Pat. No. 6,289,207 and other pending US and
international patent applications.
Printed in Australia
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FCC Notice
The WiNRADiO G303 receiver has been tested and found to comply with the limits for a Class
B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide
reasonable protection against harmful interference in a residential installation. This equipment
generates, uses and can radiate radio frequency energy and, if not installed and used in
accordance with the instructions, may cause harmful interference to radio communications.
However, there is no guarantee that interference will not occur in a particular installation. If this
equipment does cause harmful interference to radio or television reception, which can be
determined by turning the equipment off and on, the user is encouraged to try to correct the
interference by one or more of the following measures:
• Reorient or relocate the receiving antenna
• Increase the separation between the equipment and the receiver
• Connect the computer into a different outlet so that the two devices are on different
branch circuits
• Consult an authorised dealer or an experienced radio/TV technician for help
Caution
To comply with the limits for the Class B digital device, pursuant to Part 15 of the FCC rules,
the WiNRADiO card must be installed in computer equipment certified to comply with the Class
B limits. Only peripherals certified to comply with the Class B limits may be attached to the
computer containing the WiNRADiO receiver. Operation with non-certified peripherals may
result in interference to radio and TV reception. Removal of ferrite cores from power or interface
cables is prohibited. Only original cables supplied by the manufacturer must be used.
Modifications
Any changes or modifications to the WiNRADiO receiver not expressly approved in this book
could void the user's authority to operate this equipment.
Limitation of Liability and Remedies
The information published in this book has been compiled from several sources. While every
effort has been made to ensure its accuracy, neither the authors nor the publisher can
guarantee that all information is entirely correct or up-to-date. Furthermore, neither the authors
nor the publisher can take any responsibility for the use of this information or any
consequences arising therefrom.
WiNRADiO Communications shall have no liability for any damages due to lost profits, loss of
use or anticipated benefits, or other incidental, special or punitive damages arising from the use
of, or the inability to use, the WiNRADiO receiver, whether arising out of contract, negligence,
tort or under any warranty, even if WiNRADiO Communications has been advised of the
possibility of such damages. In no event shall WiNRADiO Communications ' liability for
damages exceed the amount paid for this product. WiNRADiO Communications neither
assumes nor authorises anyone to assume for it any other liabilities.
Warning
In certain countries or states it may be illegal to monitor certain frequencies. We cannot accept
any responsibility for the consequences of your non-compliance with government regulations.
If you are in doubt about the regulations in your country or state, please contact your nearest
radio communications regulatory authority.
Introduction
3
Introduction
One could easily conclude that, in the era of the Internet and communication
satellites, short waves are destined for obsolescence. But the reality is quite
different. On the contrary, shortwave communications seem to be
experiencing a new period of revival and vigorous growth.
This revival is partially caused by the fact that shortwave is still the only
technology able to send signals around the globe with minimum power and
without the need for expensive, and potentially failure-prone or sabotage-
prone infrastructure. In the era of increased security concerns, this is an
important reason for the continuing interest in shortwave.
The other reasons include newly found applications, for example HF email,
and emerging new types of digital modulations (such as DRM broadcasting),
offering more reliable and higher quality communications than before.
All this will ensure that shortwave will remain what it has always been; an
amazing place of action, a cacophony of sounds; a babel tower of exotic
languages and music, alive with broadcasters both official and clandestine;
a haven of spies; a playground of pirates, terrorists and freedom fighters
alike; an exciting mix of the respectable, the serious, the crazy and the
dangerous. Long before the Internet, the shortwave world was always
borderless. And quite like the Internet, impossible to tame and control.
Welcome to shortwave and welcome to the WiNRADiO G303 receiver. Your
new receiver is a world-first in more than one respect. Most importantly, it is
the first commercially available Software Defined Receiver (SDR), where
the entire demodulator and the last intermediate frequency stage are
performed by software running on a personal computer rather than using
conventional hardware circuits, or a dedicated Digital Signal Processor.
Your PC probably has more power than even the fastest DSP had only a
few years ago. Your new WiNRADiO G303 receiver is now ready to take
advantage of that power. Enjoy!
WiNRADiO provides regular upgrades to our application software. Don’t
forget to register as a WiNRADiO user to receive news about new products,
accessories and software upgrades for your WiNRADiO G303 receiver. Use
our on-line registration form on www.winradio.com/register to take
advantage of this free service.
Installation
4
G303 Receiver Models
There are two basic models of the WiNRADiO G303 receiver:
• G303i (PCI card based “internal” model)
• G303e (USB based “external” model)
Both receivers have similar parameters and identical software user
interface. This manual covers the installation and operational aspects for
both types.
The G303i model has two connectors: the antenna connector (SMA type,
50 ohm) and 12 kHz IF (intermediate frequency) output:
The signal from the 12 kHz IF output is normally connected to the PC sound
card, where it is digitized, to be then processed by the PC.
The advantage of this model is that it does not require any external power
supply, and does not occupy any additional desk space. The receiver is very
well shielded to prevent any interference generated by the PC from entering
the receiver.
The receiver comes with a suitable “audio lead” to connect the 12 kHz IF
output to the sound card input.
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The external G303e model has three connectors:
The power jack accepts 12 V DC (the power adapter must be rated for
minimum 500 mA). To minimize interference, a linear-mode power adapter
is recommended (as supplied by WiNRADiO).
The antenna input is an SMA-type connector with 50 ohm impedance.
The IF output/control connector combines the 12 kHz IF (intermediate
frequency output), USB interface and serial interface. Normally, only the
USB interface cable is supplied, and the IF signal arrives from the receiver
to the PC already digitized, via the USB cable. This method is preferable,
because it relies on a high-quality analog-to-digital converter inside the
receiver, and guarantees optimum and consistent performance. The
installation is also simpler as it does not require adjustment of the 12 kHz IF
signal input level (this is set to optimum level inside the receiver).
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It is also possible to control the receiver via the serial (RS-232) interface,
which necessitates using the PC sound card for digitization of the IF signal.
WiNRADiO provides a special “serial interface option” cable which takes
care of all the appropriate connections, both to the serial port and the sound
card input.
G303e serial interface option
As this interfacing method relies on the sound card to provide the digitization
of the 12 kHz IF signal, it requires careful adjustment of the input signal
level. The performance will depend on the sound card quality.
It is a suitable method in situations where the receiver needs to be
controlled by computer systems without the USB interface.
Did you know?
DRM (Digital Radio Mondiale) is a new digital broadcasting system for
medium and short waves. By introducing sophisticated signal coding and
compression, this system offers a dramatic improvement in broadcast
quality. WiNRADiO has a DRM demodulator available for your G303
receiver. For more details please refer to www.winradio.com/drm.
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Installation
The WiNRADiO package contains the following items:
• WiNRADiO G303i or G303e receiver
• WiNRADiO software on a CD ROM
• Start-up indoor antenna
• Audio cable (G303i model only)
• Power adapter (G303e only)
• Interface cable (G303e only)
• This User’s Guide
• Warranty information
In order for the WiNRADiO receiver to function, your IBM PC compatible
computer must meet the minimum system requirements specified below.
System Requirements
Minimum Recommended
CPU 500 MHz,
Pentium III
1GHz or higher,
Pentium IV or Athlon
RAM 64 MB 256 MB or more
Display SVGA SVGA (16 mil. colors)
HD free space 20 MB 40 MB
Sound card SoundBlaster
compatible, 16 bit,
full duplex
Creative Sound Blaster,
16 or 32 bit
OS Windows
98/ME/NT/2000/XP
Windows 2000/XP
Hardware Installation
G303i model (PCI card-based)
1. Turn off the computer and disconnect the power cord.
2. Remove the computer case. Choose an empty PCI slot, as far as
possible from the power supply and from other cards.
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3. First touch the computer metalwork with your hand to drain any static
charge, then carefully insert the card into the vacant slot and push down
until it is firmly seated. Screw the metal bracket at the end of the card to
the computer case. (This must be done to provide proper grounding for
the card).
4. Replace the computer case and reconnect the power cord.
5. Connect the supplied audio lead between the receiver output (a
standard audio jack) and the sound card Line Input. (If there is no Line
input on your PC, as is the case with some laptops, you may use
alternative inputs, such as the Microphone input. This may be also
necessary with certain types of sound cards, such as Creative
Audigy 2.)
G303i receiver installed in a desktop PC
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G303e (external) model with standard USB interface
1. Connect the receiver to the USB port using the supplied cable.
2. Plug the supplied power adapter to the power outlet and connect its
output to the receiver.
3. Turn the receiver on using the power switch at front of the receiver. The
blue LED will blink to indicate that the receiver is ready.
G303e receiver with USB interface
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G303e (external) model with optional serial interface
1. Connect the receiver to the serial port using the supplied adapter,
which combines both the serial interface and the audio lead in one
cable.
2. Connect the audio lead on the PC side to the sound card Line input. (If
there is no Line input on your PC, as is the case with some laptops, you
may use alternative inputs, such as the Microphone input. This may be
also necessary with certain types of sound cards, such as Creative
Audigy 2.)
3. Plug the supplied power adapter to the power outlet and connect its
output to the receiver.
4. Turn the receiver on using the power switch at front of the receiver. The
blue LED will blink to indicate that the receiver is ready.
G303e receiver with serial interface
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G303e LED status indication
The single blue LED on the front of the WiNRADiO G303e (external)
receiver can display a number of different states using various specific flash
patterns. Each pattern is repeated once per second.
In the following table, “black” in the pattern indicates that the LED is on in
that time interval.
Pattern Description Mode
Off No power
Long flash, equal
gap
No connection to computer
Single short flash Serial connection, radio off
Single long flash
Serial connection, radio on
Two short flashes
USB connection, radio off
One short flash
followed by a
long one
USB connection, radio on
Two short flashes
followed by a
long one
USB connected, but driver
not installed
Three short
flashes
USB connected, driver
installed, but application not
running yet
Did you know?
The blue LED is a semiconductor that glows blue when electricity is passed
through it. Of the three primary colors for light, the red and green LEDs were
invented more than 20 years earlier; the blue LED, however, proved to be
elusive. In 1993, the blue LED was developed and soon brought to market
owing to a new technology devised by Prof. Shuji Nakamura. Its world-wide
success in consumer markets has been spectacular – as fascinating as the
intensive and mysterious glow of the blue LED itself.
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Connecting the Antenna
Your WiNRADiO G303 receiver comes with a start-up antenna consisting of
a 3-meter length of coaxial lead-in cable, with an additional 3 meters of
insulated wire. The thinner, insulated wire at the end is the actual antenna.
The long lead-in cable is necessary for the antenna to be located as far
away from the PC as possible, to reduce interference from the PC.
Please note that this start-up antenna is supplied for immediate gratification
only and is not intended to replace a good shortwave antenna.
The best placement of the start-up antenna depends on your actual
situation, and will often involve some experimentation. However, the basic
rule is simple: Place the antenna as close to the window as you can, and
keep the active part of the antenna as far away from the PC, and other
electronic and electrical devices, and metal objects, as possible.
Something to consider?
WiNRADiO also manufactures antenna impedance
transformers (often referred to as “long-wire
baluns”). The WR-LWA-0130 adapter shown on the
left can be used to match the impedance of a long
wire shortwave antenna to the 50 ohm input
impedance of the WR-G303 receiver.
Such impedance matching usually results in a
significant signal strength increase compared to the long wire antenna connected
directly to the antenna input of the receiver. For more information on this product as
well as the WiNRADiO range of antennas, see the WiNRADiO Web site
www.winradio.com.
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An example of WiNRADiO start-up antenna placement
No matter how good a radio receiver is, the performance of the entire
receiving system will depend on the quality of the antenna. The same
applies to a WiNRADiO receiver. To make the most of your WiNRADiO
receiver, you should install a proper shortwave antenna.
Check out our antennas
There are many vendors offering shortwave antennas. WiNRADiO with our
extensive range of antennas may also be able to assist. Check out
especially our low-cost wire antenna AX-05E, which is particularly suitable
for the G303i receiver: www.winradio.com/home/antennas.htm
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Software Installation
1. If the PC is off, turn it on. Windows will find the receiver and
automatically start the usual New hardware found driver installation
routine. Insert the installation CD ROM into the drive, and follow on-
screen instructions. (Note: Windows NT will not automatically detect the
receiver, as it does not support Plug and Play.)
2. After installing the drivers, choose the Run command from the Start
menu in Windows and type D:\INSTALL (if the CD ROM is the D: drive
on your PC).
3. This will run the application installer, which will guide you in the
installation process.
4. After all the files have been installed to your hard disk, run the
WiNRADiO G303 application.
Note: If the receiver is not detected by Windows, you can simply skip the
driver installation procedure, insert the CD ROM, and run the installation
program, which will also install the drivers.
Setting up the Sound Card
This section refers to the G303i model, or the G303e model with serial
interface, only. The G303e model with the standard USB interface does
not require this set up and this entire section may be skipped.
After installing the hardware and software, you will now need to set-up the
sound card parameters. This is done both in the WiNRADiO application and
in the Windows sound card control panel – this provides the actual
connection between the receiver front-end and the PC back-end of your
radio system.
In computer terminology a sound card is a wave device. A computer may
have several such wave devices installed (for example a modem with voice
capabilities). That’s why you need to select the sound card as the desired
wave device first. Start the WiNRADiO G303 application and click on the
Setup button (located below the USB button) in the demodulator panel:
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The demodulator set-up window opens, as shown:
The Wave device drop-down list shows all the installed wave devices:
Windows default is the Control Panel setting specified under Start |
Settings | Control Panel | Multimedia Properties | Audio. If a sound card
is specified in this Control Panel setting for both playback and recording (this
is very likely, but not always necessarily so), then you can simply select
Windows Default as the wave device for the demodulator. Otherwise, the
specific name of the sound card should be selected.
The selected sound card must support duplex operation and the standard
44100 or 48000 samples/second sampling rates, 16 bits per sample, stereo.
Most modern sound cards do satisfy all these conditions, but some cards
may have a high level of distortion at 48000 samples per second; for such
cases, the 44100 samples/second sampling rate is provided.
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The next parameter to select is the mixer device associated with the already
selected sound card, using the Mixer device drop-down list, and the Mixer
line (the sound card input line). If the signal is arriving at the sound card via
an external cable, the cable should be physically connected to the Line
input of the sound card. If the receiver is connected internally, most probably
the input would be called Aux or CD Line.
In the drop-down list of sound card inputs, each line is available either as
normal, or Reversed. If the reversed line is selected, this means that the left
and right channels (of the sound card stereo input) are to be reversed.
Normally, you should not need to select any of these reverse inputs.
However, there is a very small number of sound cards where the left and
right inputs are swapped. Normally, the G303 Demodulator expects the
receiver output to be connected to the right sound card input. If it is to be
connected to the left input instead, the reverse input line needs to be
selected from the drop-down list.
With some laptops, only the Microphone input may be available and in such
case you will need to connect the receiver to the Microphone input instead,
and also select this input in the demodulator Setup panel. Certain sound
cards, in particular Creative Audigy 2, have a design problem which
prevents them from using the Line input in a full duplex mode. In such case,
you will also need to use the Microphone input.
If you are using the Microphone input instead of Line input, please check if
there is an Advanced button under the Microphone volume control in the
sound card control panel. If so, then click on it and uncheck the +20dB gain
check box if it exists. The extra large gain would result in overloading the
sound card, and cause distortion.
The last parameter to set is the Input level. Set it to half the maximum level
initially. When you then tune the receiver to your first station, you should
return to this, and adjust the Input level below the point when the Clipping
indicator turns red. If the signal still sounds distorted, reduce the level
further down until the distortion disappears.
While adjusting the Input level, you will also see the noise floor of the signal
spectrum shown in the main demodulator window rising proportionally.
This completes the software installation process. The G303 software then
automatically configures the sound card control panel. It may be interesting
to describe what it actually does and why:
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Firstly, in the sound card Playback volume control panel, the software
mutes the sound card input line the receiver is actually connected to. This is
the same line as selected in the WiNRADiO G303 demodulator Setup, i.e.
usually, this will be Line or Microphone input.
This may seem a bit unexpected: Why are we muting the input line? This is
because the signal coming from the receiver is not an audio signal, but
rather the intermediate frequency signal. It needs to be processed
(demodulated) by the PC first, before it is output back to the sound card.
That’s also why the sound card needs to be full duplex, to allow for such
simultaneous input/output processing.
Failure to mute this line would cause a high-pitched intermediate frequency
sound to be combined with the demodulated signal.
To see how the line is muted, click on the speaker icon in the task bar in the
bottom, to bring up the sound card Volume Control panel (consult
Appendix B – Sound Card Controls if you have difficulties locating the
sound card settings):
The same line will be selected in the Recording Control of the sound card
control panel. To get there, you need to select Options | Properties |
Recording in the top bar menu of the Volume Control panel.
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The Volume slider of the Recording Control is duplicated in the
demodulator Setup panel (where it is labeled Input level).
Please pay great attention to the sound card set-up, as most initial
problems associated with using this type of receiver can be attributed to an
incorrect sound card setting. Typical problems include:
• Not selecting the Mixer device or Mixer line correctly (which will
manifest itself by the absence of any signal appearing in the spectrum
scope);
• Failing to adjust the Input level properly, which may result either in low
(or no) audio output, or, on the other hand, distortion if the signal level is
too high.
Did you know?
The ubiquitous PC sound card was invented in Singapore by Sim Wong Hoo,
engineer and entrepreneur, who founded the Creative Technology company in 1981.
His first product, an Apple computer clone, did not take off. However, his second
product, the PC sound card, hit its target well: More than 120 million sound cards
have been shipped by Creative Technology, mostly under the Sound Blaster brand.
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Getting Started
There is often a degree of understandable impatience when exciting new
equipment such as a new WiNRADiO receiver is acquired. The following
fast-forward introduction makes it possible for you to start using your new
acquisition as quickly as possible. Detailed operation is described in the
subsequent chapter Using WiNRADiO G303 Receiver. We hope you will
return to that chapter, as the WiNRADiO G303 receiver has many fine
features which it would be a shame to miss.
Start the WiNRADiO G303 receiver application (double clicking on the
WiNRADiO icon). The WiNRADiO G303 receiver control panel will appear
as shown below.
WiNRADiO G303 Receiver Control Panel
The WiNRADiO G303 receiver control panel has some elements similar to
conventional shortwave receivers, and many additional features as well.
The quickest way to get started with this receiver is to check its operation on
local AM stations.
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Using the keyboard, type in the frequency of one your local AM stations:
For example, for 774 kHz, type in 7 7 4 , then k for kHz, then press Enter.
The typed-in frequency will appear on the digital frequency display. Then
select the AM mode by clicking on the AM button. At this point, you should
hear the station. You can adjust the volume using the two buttons next to
the small Volume display. (Note also the little slider between these two
buttons: you can drag it up and down to change the volume faster.)
Manual tuning can be done in several ways. Let’s start with the tuning knob:
Place the mouse cursor to the upper half of the tuning knob, at which point
you will see the cursor change to a curved double ended arrow. Hold down
the right or left mouse buttons to increase or decrease the frequency, and
the knob will rotate clockwise or anti-clockwise, respectively. If you place
your cursor in the bottom half of the tuning knob, the direction of the rotation
will reverse.
The rotation increment of the tuning knob is 0.5 kHz. This can be changed
easily using the Shift, Ctrl or Alt keys: If you press the Shift key while tuning,
the increment will increase ten times (to 5 kHz). Pressing Ctrl will increase
the increment a hundred times (50 kHz). On the other hand, if you use the
Alt key, the increment becomes ten times finer: 50 Hz.
If you are still unable to tune to any stations at this point, please refer to
Appendix A - Troubleshooting.
There are also several other ways to tune the WiNRADiO receiver other
than typing the frequency or using the tuning knob. These will be explained
in detail in the Using WiNRADiO G303 Receiver chapter.
Did you know?
The first commercial shortwave station was Radio Luxembourg. It was the
first station to target areas outside of its own country with programs in other
languages. For most of the 20th century, this was the most powerful
shortwave station in Europe.
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Using WiNRADiO G303
Tuning to a Frequency
To change frequency, simply type the new frequency into the keyboard. As
soon as you press a digit or decimal point, the frequency display will
activate, waiting for a frequency to be typed. You can also click on the
display to type in a new frequency. After typing the new frequency, press
Enter and the receiver will instantly retune. To abort, press Esc.
To enter units, such as kHz or MHz, simply press H for Hz, K for kHz or M
for MHz after entering the digits. Any invalid keystrokes are ignored.
Frequencies outside the receiver limit (9 kHz to 30 MHz) will not be
accepted and the display will revert to the previous frequency.
WiNRADiO G303 Receiver Frequency Display
The up and down buttons under the individual digits make it possible to
quickly step up or down the frequency in the corresponding positions. (The
little slider buttons between the buttons can be used for faster adjustment.)
Under these buttons there is a band description window. This shows the
band allocation of the currently tuned frequency. These band descriptions
are based on those applicable to North America. However, these
allocations are based on international treaties and therefore are generally
applicable worldwide.
Note that the default band allocation can be overridden with a call sign or a
user-defined description of a frequency stored in memory. The default band
description is also user modifiable: it resides in the file bands.csv in the
WiNRADiO installation folder. This file can be edited using a spreadsheet
application, such as Microsoft Excel.
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Fine Tuning
The Fine Tune knob makes it possible to finely adjust the frequency in
0.5 kHz steps.
WiNRADiO G303 Receiver Tuning Knob
To use the tuning knob, position the mouse cursor over the knob (the cursor
will turn into a curved double ended arrow) and click on either the left or right
mouse button. If the cursor is on the top half of the knob, the left button will
decrease the frequency, and the right button will increase the frequency. If
the cursor is in the lower half, the opposite will occur (and the cursor will
invert its shape).
Using the keyboard only, the frequency can be similarly adjusted using the
up/down cursor keys.
To speed up tuning, the step size can be increased ten or one hundred
times by holding the Shift or Ctrl keys respectively, while clicking the tuning
knob with the mouse button or using the up/down keyboard keys. This is a
very convenient feature if you wish to tune quickly across a frequency range:
hold the mouse button and accelerate the movement by pressing the Shift
or Ctrl keys. On the other hand, pressing the Alt key will reduce the tuning
step ten times (to 50 Hz).
Note that the Tuning Knob can also be conveniently rotated using a wheel-
equipped mouse, or any other standard Windows-supported pointing device.
Taking advantage of this facility, it is possible to emulate the “feel” of a
conventionally tuned receiver.
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Fast Tuning Pad
This unique fast-tuning facility is located under the Attenuator, IF Gain and
Squelch settings.
Fast Tuning Pad
If you place the cursor inside the long horizontal window of the Fast Tuning
Pad, you will see a frequency increment displayed, which can vary from 1
Hz to 1 MHz in convenient steps. The value of this increment can be
changed quickly by moving the cursor horizontally within the Fast Tuning
Pad. The current increment value is always shown under the pad. You can
quickly change between incrementing and decrementing by alternating the
left and right mouse buttons. The sign of the displayed increment value will
also change accordingly.
By combining horizontal movement of the mouse with alternating of the left
and right mouse buttons, you can quickly tune to any frequency, and step
through the band with the appropriate step size.
The row of yellow squares under the Fast Tuning Pad serves a similar
purpose, providing convenient increment sizes in a narrower band between
1 Hz and 10 kHz. These increments are selected by placing the mouse
cursor over the yellow squares, and using the left or right mouse buttons for
incrementing or decrementing.
Setting the Modulation Mode
To select the modulation mode, click on the appropriate Mode button in the
Demodulator panel:
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WiNRADiO G303 Standard Demodulator Panel
The real-time spectrum display shows the output of the receiver (i.e. the
intermediate frequency signal) as it is applied to the PC sound card. When
you press the mode buttons, you will note that the central highlighted region
of the spectrum changes its width. This corresponds to the IF (intermediate
frequency) filter bandwidth associated with the different modulation modes.
For example, standard AM mode has 6 kHz bandwidth, while narrow AM
(AMN) uses 4 kHz bandwidth. The CW mode uses a narrow bandwidth of
500 Hz. You will see the trace color change from white to yellow where the
spectrum falls within the filter bandwidth. This indicates that you are only
receiving the yellow part of the displayed spectrum and the surrounding
frequencies are rejected.
If you mistune the receiver somewhat, you will see the spectrum shifting.
This assists you to tune the receiver right to the center of the transmitter
frequency, and to select the correct AM mode to avoid interference from
adjacent signals.
If you also purchased the optional Professional Demodulator, you can
select this demodulator from the Demodulators top bar menu. The basic
functions such as volume control, audio muting and mode selection are
identical to the standard demodulator.
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WiNRADiO G303 Professional Demodulator
For details of the many additional functions such as continuous IF bandwidth
adjustment and other special features of the Professional Demodulator,
please refer to Appendix E - Professional Demodulator.
Volume Control
The Volume control is also located in the demodulator panel. The volume
can range from 0 (no sound) to 31 (full volume). To enter a value directly,
click on the display and type in the new volume level. The volume can be
also increased or decreased by clicking on the up or down buttons next to
the volume display.
Another convenient way of changing the volume is by using the small slider
button between the up and down buttons. Place the mouse cursor on it and
see the cursor shape change, to indicate a ‘slider’ type of control. Hold
down the left mouse button to drag the slider up or down and the volume will
change accordingly.
Finally, another convenient way of changing the volume is by using the left
and right cursor keys on the keyboard.
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Mute Control
Next to the Volume control is the Mute button, which allows you to switch
off the audio output quickly. It is faster to use than setting the volume to
zero, with the added benefit of not changing the set volume level. To use the
mute control, simply click on this button. Click again to release.
AGC
The AGC (Automatic Gain Control) has four settings: Off, Slow, Medium
and Fast. These make it possible to disable the AGC, or to select the speed
with which the AGC reacts. Typically, the AGC would be in the Medium
position.
AGC Control
The receiver must process a considerable variation of signals, ranging from
very weak to very strong. This requires the sensitivity of the receiver to vary
according to the incoming signal strength.
The incoming signal can vary in intensity, with changing propagation
conditions, and also depending on the modulation type and content. For
example, with CW signals (where information is transmitted by keying the
transmitter on and off), the signal strength will vary substantially during the
transmission. The demodulated signal will then sound better with a slow
AGC (as the receiver will not have time to increase the gain during the “off”
intervals, and increase the background noise and causing a raspy sound).
On the other hand, use fast AGC when listening to especially weak signals
buried in static and noise. Otherwise, each new burst of noise would
desensitize the receiver for a long time and you could miss long periods of
useful transmissions.
If unsure, use the medium speed AGC setting.
It is easy to forget that AGC has been disabled. If the signal sounds
distorted, or, on the other hand, if the sensitivity appears to be very low,
check the AGC setting first.
- 27 -
IF Gain
The AGC can be turned off using the AGC Off button. The receiver gain
must then be adjusted manually. This is done using the IF Gain control.
Note that by setting an excessive gain, the receiver will overload and the
demodulated signal will be distorted. On the other hand, if the gain is too
low, it will make the receiver appear “deaf”.
Manual IF Gain setting is useful when hunting for very weak signals buried
in noise.
Manual IF Gain Control
The IF Gain control is only enabled when the AGC is switched off. The gain
“value” ranges from 0 to 100, where 100 corresponds to maximum gain. The
gain can be adjusted in three ways: by typing the value directly in the edit
box, or using the up and down arrow buttons, or by dragging up or down the
centre slider.
Audio AGC
The Audio AGC facility is available in the Demodulator panel, and provides a
supplementary function to the main AGC. (The main AGC employs a
hardware circuit, while the Audio AGC works in software.)
Audio AGC
Audio AGC is useful to compensate for audio volume changes when the
antenna signals are so weak that the main AGC is not yet activated, or when
the main AGC is disabled and the manual IF gain is used.
- 28 -
Attenuator
The Attenuator makes it possible to reduce the receiver sensitivity by 18 dB
(i.e. 6 times).
Attenuator
Why would you ever need to reduce the sensitivity? This is because
unusually strong signals from local stations may occasionally cause
overloading. This overloading can make the reception worse, and even
cause stations to appear on frequencies, where none exist (ghost stations).
See Appendix C - Dealing with Interference for more information on this
phenomenon.
If a received signal is too strong, causing overloading, distortion or the
appearance of ghost stations, you should reduce its level by pressing the
Attenuator button.
Squelch Control
The Squelch control can be used to automatically mute the receiver when
no signal is being received. Without a signal, all you will usually hear is
noise. Squelch is provided to cut out the noise until a station is found,
making the receiver more comfortable to use.
Squelch Control and Squelch Defeat Button
The squelch setting controls the signal level at which muting occurs. Muting
will occur when the signal level drops below the squelch level. When a
signal of a higher level returns, the sound will be restored immediately.
- 29 -
The squelch is always shown in dBm units. To adjust the squelch control,
first tune to an unoccupied frequency that produces only noise. Increase the
squelch until the receiver is muted. You will see the red-colored segment of
the S-meter growing until it gets higher than the current S-meter value. At
that moment the receiver will be muted and the word “squelched” will be
displayed on the S-meter. Add a few dB extra (to allow a margin for
background noise fluctuation on the band). Now when you tune to an
occupied frequency, if its signal strength is higher than the squelch level, the
receiver will be unmuted.
Next to the squelch setting is the Squelch Defeat (Def) button. When
activated, the squelch action will be turned off (it is the same as if the
squelch was set to its lowest level, but more convenient). The red segment
in the S-meter will turn blue to indicate this condition.
It is easy to forget that squelch is active. If the receiver doesn’t seem to be
operational (no sound from the speaker), check the squelch and mute
settings first.
Frequency Stepping
The Frequency Stepping facility makes it possible to specify an arbitrary
frequency step size. To change the step size, click on the associated display
and enter the required value (from 1 Hz to 1 MHz). You can also use the up
and down buttons on the right of the display, to select from commonly used
step sizes. For convenience, you can also use the small slider between the
two buttons.
Frequency Stepping Panel
When the step size is selected, you can step up or down from the currently
displayed frequency using the left/right arrow buttons under the Step size
display. The double-arrow buttons further down will cause stepping by a
step size ten times larger. Stepping can also be done using the keyboard
Pg Up/Down keys.
- 30 -
For example, if you wish to browse the AM broadcast band (approx. 530 to
1620 kHz), set the step size to 10 kHz (for North and South America) or
9 kHz (for the rest of the world), which is the channel separation for AM
broadcast stations. Tune manually to any station first, then step up or down
to browse the band. To browse the shortwave broadcast stations (2.3 to
30 MHz), 5 kHz works well.
This type of fixed-size stepping is convenient if you wish to explore a
frequency band where the channels are equally separated. However, you
should ensure that the stepping frequencies fall on the actual channel
frequencies in the band. If you know the channel separation but are unsure
about the exact frequency of the first channel, tune to an active channel
using manual tuning first, and only then step up or down in fixed steps.
The Auto button engages Auto-stepping, which provides a significant
enhancement over fixed stepping. When properly configured, auto-stepping
will automatically set the step size according to the frequency you are tuned
to. Auto-stepping can also be used to associate particular mode and squelch
settings with specified frequency ranges.
To configure the auto-stepping ranges, go to Options | Autostepping in the
top bar menu. The following window opens:
You can use the New button to add a new range. For each range, you need
to specify the Lower and Upper ends of the range, Step size, and optionally
Mode, Squelch and Description. You can specify as many such bands as
you like. When done, close the window.
Next time when you tune to a frequency, and the Auto button is pressed,
the step size (and optionally mode and squelch) will be set to the predefined
value if the new frequency falls within a specified auto-step range.
- 31 -
Frequency Memory
The WiNRADiO G303 receiver has the ability to store up to one thousand
frequencies in one memory file. It also allows you to load and save different
memory files for a huge amount of total storage, limited only by the size of
your hard disk.
Memory Control Panel
Storing a Frequency into Memory
With each frequency, you can store several attributes: mode, callsign, user
comment, group assignment, squelch and a hotkey.
To store a frequency into memory, the receiver must first be tuned to that
frequency (and the appropriate mode must be selected if you also wish to
store the mode). Next click on the S button in the Memory Control Panel
as shown above.
A Store frequency dialog box will pop up, allowing you to assign a memory
number to the current frequency.
Did you know?
Unlike medium wave or FM broadcast stations, shortwave stations change
their frequencies and program schedules very often. One of the best
publications providing regular frequency updates and transmitting schedules
is the Monitoring Times magazine (www.monitoringtimes.com).
- 32 -
Storing Frequency to Memory
At the top of the dialog box is the frequency you are storing. The next line
shows the next available memory number. You can change this to another
memory number if you wish (including one which is already allocated).
The third item contains the group assignment buttons. You can assign the
frequency to one or more of 16 different groups (whose meaning you define
yourself). When you are searching or scanning for a particular type of
frequencies (for example “Airforce”), the group assignment will allow you to
confine the searching and scanning to that particular type.
Note that a frequency may be associated with more than one group at the
same time.
There are also several additional items that can be optionally stored with
each frequency:
• Most stations have a name or callsign. You can store up to 11
characters in the Callsign field.
- 33 -
• For quick tuning to your favorite stations, you can assign
Hotkeys (function keys F2 to F12) for up to eleven different
frequencies. If you then press a hotkey, the associated
frequency will be instantly recalled. Hotkeys which are already
assigned will be shown in this dialog box as ‘used’, however
you can overwrite the previous assignment with a new one if
you wish.
• User Comments can also be stored with a frequency. The size
of the comments is limited to 31 characters.
• The Mode and the Squelch values can also be stored, which
will then be set automatically when the frequency is recalled.
• Finally, a Memory Scan Lock-out can be set for each
memory, which means that the memory will not be included in a
memory scan. In the memory Recall window, such memories
will be shown with a small ‘x’ preceding the memory number.
Finally, when everything has been set, click on OK or press Enter, to save
the new frequency.
Recalling a Frequency from Memory
There are several ways to recall a frequency from memory:
• Using Memory Recall
• Typing a number into the memory number display
• Using a hotkey
• Memory stepping
To recall a frequency, click on the R button. A dialog box will pop up
showing a list of all memory frequencies.
To select a frequency, click on an item in the list, and the frequency will be
tuned. Then close the window. Alternatively, use the up or down cursor
keys to choose the frequency and press Enter.
- 34 -
Recall Frequency from Memory
The assigned memory groups are shown as color bars for a quick visual
overview of which frequencies are associated with which groups (see the
corresponding colors in the Store frequency window). When you position the
mouse cursor over a highlighted memory, the actual group numbers will be
displayed in a floating ‘hint’ box.
Editing Memory
To change the settings for a particular frequency, open the Recall frequency
dialog box as described in the previous section. Select the item you want to
edit and click on Edit (alternatively, double-click on the item). A dialog box
will pop up showing the current settings. All the settings except the memory
number can be edited. After the entry has been edited, click on OK.
Deleting a Frequency
To remove a frequency, open the Recall frequency dialog box. Select the
frequency you wish to delete, and click on Delete. You will be asked to
confirm that you want to delete this frequency from memory.
To delete all frequencies, select Clear from the Memory file sub-menu in
the File menu. You will be asked to confirm that you want to clear all the
frequencies in the memory.
- 35 -
Saving a Memory File
Each memory file, containing up to one thousand frequencies, is stored
separately, allowing different memory files to be loaded and saved. To save
the current memory file, simply select Save from the Memory file sub-menu
in the File menu. If you wish to save it with a different name, select Save as
instead, and a dialog box will pop up allowing you to specify the file name.
When you exit the WiNRADiO G303 application, all memory changes are
automatically saved; there is no need to use the Save command before exit.
Opening a Memory File
When WiNRADiO starts up, the most recently used memory file will be
opened automatically.
To open a different memory file, select Open from the Memory file sub-
menu in the File menu. A dialog box will pop up allowing you to choose a
memory file to load.
Memory Stepping
Memory stepping makes it possible to step through frequencies stored in the
current memory file.
To step through memory frequencies use the left or right arrow buttons
located under the memory S and R buttons. The double-arrow buttons
located further down make it possible to advance ten frequencies up or
down (or to the start/end of the memory list if it is less than ten frequencies
away).
Memory stepping will only work if there are frequencies stored in memory. If
no frequencies have been stored, nothing will happen if you try to step
through the memory.
Scanning
The WiNRADiO G303 application contains a comprehensive set of scan
functions to enable the user to search for stations which are currently on the
air. There are three basic types of scanning: Immediate Scanning
(Searching), Range Scanning and Memory Scanning.
- 36 -
The scanning method is selected using the appropriate button in the
Scanning Control Panel:
Scanning Control Panel
Immediate Scanning (Searching)
This is the simplest scanning method. Click on the Search button to select
this scanning mode, then use the [>>] or [<<] buttons to scan either forward
or backward from the currently tuned frequency. To stop scanning, press the
Stop button (marked with a green square). To pause, press the Pause
button (marked with two vertical bars).
A signal is considered ‘found’ when the signal level is higher than squelch.
Correct setting of the squelch value is therefore essential for scanning.
If you set the squelch level too low, then scanning will stop even if there is
no signal (the background noise will be higher than the squelch level). On
the other hand, if the squelch level is set too high, then a useful signal may
be missed because it will fall short of the squelch level. With a bit of trial and
error, you will need to adjust the optimum setting for the squelch level
(usually a few dB above the background noise floor).
Scanner Configuration
When a signal strength level is higher than the squelch level, this indicates
that a signal has been found. You can configure the software to specify what
action you want to be taken at this point. To access this configuration facility,
go to Options | Scanning in the top bar menu.
- 37 -
Scan Settings
There are two basic actions the software can do when a signal is found:
Pause scanning or Stop scanning. If Pause is selected, then you need to
further specify the conditions under which the scanning will Resume. The
conditions to resume can be one of the following:
1. When the signal disappears (i.e. the scanning resumes immediately
when the signal disappears);
2. After a certain user-defined Delay time (i.e. no matter if the signal
disappears during this Delay Time or not, the software will always wait
for the Delay Time interval, then resume);
3. When the signal disappears during Delay time (i.e. the scanning will
resume after Delay time, or earlier if the signal disappears);
4. When there is no signal during the Delay time (i.e. the scanning will
resume if there is a no-signal gap equal to, or longer than, Delay time).
The Delay time interval can be set from 1 to 100 seconds.
The Scan rate controls the speed at which scanning occurs, by specifying
the maximum number of scanning steps per second.
- 38 -
Note that the upper scanning speed limit may be restricted by the available
CPU resources of your computer.
When a signal is found and scanning pauses, waiting for the pre-set Delay
time to expire, the countdown timer will appear inside the [<<] or [>>]
buttons. If no Delay time was set and scanning is pausing until the signal
disappears, then the [<<] or [>>] button will flash.
Groups
The Groups setting is useful for Memory Scanning, which will be described
later: it serves to restrict Memory Scanning to particular memory groups
only.
Exclusions
Sometimes it is desirable to exclude certain frequencies from scanning. This
means that such specified frequencies should be ignored even if the signal
level on these frequencies is higher than the squelch.
The WiNRADiO G303 receiver application makes it possible for multiple
frequency ranges to be excluded. This is done using the Exclusions button.
When you press this button, you will open an Exclusions editor window,
allowing you to enter a range of frequencies to be excluded.
For these exclusions to become active, check the Enable excluding while
scanning checkbox in this window.
Frequency Range Scanning
To be able to use Frequency Range Scanning, you need to set up the
desired scanning ranges first. This is done using the Ranges button in the
Options | Scanning top-bar menu.
- 39 -
Setting up Scan Ranges
Enter a new range using the New button. This will open a dialog box, where
you will be asked to specify lower and upper limit frequencies of the range,
the modulation mode, squelch level, and, optionally, a description. You can
enter as many such ranges as you like:
Adding a New Range
- 40 -
When the range definition is done, close this window, then close the scanner
settings. Then activate the Range button in the Scanning control panel:
Scanning Control Panel
When you press the Scan Forward button [>>], the scanner will commence
scanning from the start frequency of the first range. When the last frequency
of the first range is reached, it will then continue onto the next range, etc.
When it reaches the end of the last range, it will go back to the start of the
first range and continue looping infinitely until a signal is found, or until
manually stopped or paused. If you use the Scan Backward button [<<],
the process will be exactly reversed (i.e. starting from the top frequency of
the last range and working its way downwards).
You can stop or pause this activity using the Stop or Pause buttons. If you
use the Pause button, then restarting scanning using Scan Forward or
Scan Backward buttons will resume the action from the paused frequency.
If you stop scanning with the Stop button, then using the Scan Forward or
Scan Backward buttons will recommence scanning from the initial (or the
last) frequency again.
If no ranges are specified in the Ranges list, then activating scanning in the
Range mode will result in no action.
An additional useful feature of frequency range scanning is that all found
frequencies can be automatically stored in memory, even if the receiver is
left unattended. To do this, enable the Auto Store checkbox in the Scan
ranges set-up window, and specify the memory range to which the
frequencies should be written. You can also specify a special Group Number
to be assigned to such frequencies.
When using the Auto Store option, you should also set the appropriate
conditions for scanning when the signal is found (for example, pause when
signal found, and resume after the minimum delay time will provide the
fastest scanning and writing into memory).
- 41 -
Note that if more signals are found than there are allocated memories, the
excess frequencies will not be stored.
Memory Scanning
The last scanning method is Memory Scanning. Here the receiver will step
through memory frequencies, starting from the first one to the last one, and
repeating the loop until a signal is found or until manually stopped.
If a squelch value is stored with a memory, its value will be used to compare
with the current signal level. If there is no value stored, the current squelch
value will be assumed.
It is possible to restrict scanned frequencies to particular memory groups
only. These groups can be selected from the Options | Scanning | Groups
window, accessible from the top bar menu. Groups can be enabled/disabled
using the check box Enable group restriction in the same window.
S-meter
The WiNRADiO G303 receiver Signal Strength Meter (S-meter) makes it
possible to measure signal strength in either S-units, dBm or µV
(microvolts). The units are selected by correspondingly marked buttons on
the right side of the display. In the microvolt mode, the p-p button is also
enabled, making it possible to select peak-to-peak values rather than the
default RMS (Root Mean Square) values.
S-meter
The S-meter also shows the currently selected value of the squelch (the red
section at the bottom side of the scale). When the signal strength falls under
- 42 -
the squelch level (i.e. the needle falls in the red region and turns red also),
the receiver audio will be muted and “squelched” will be displayed.
The squelch value is always indicated in dBm units (even if the signal
strength is displayed in S-units or microvolts).
Note that when the AGC is off (and manual IF gain control is activated), the
S-meter is disabled. This is because the S-meter relies on the AGC for its
proper function.
Power Switch
The On/Off power switch, located at the bottom-right corner of the
application window, controls the receiver power. When it is off, the receiver
circuitry will be powered down and no sound will be heard through the
speaker or headphones.
When you exit and restart the WiNRADiO application, the power status at
exit will be remembered.
Date and Time Displays
The clock display, located under the Fast Tuning Pad, indicates the current
time and date.
The UTC clock shows Universal Coordinated Time, formerly called GMT
(Greenwich Mean Time), which is the standard time used around the world.
This is provided because most shortwave stations announce their broadcast
times in UTC. Both displays derive their information from the PC clock. The
time difference is determined by Windows Time Zone setting (Start |
Settings | Control Panel | Date/Time Properties | Time Zone tab).
- 43 -
Spectrum Scope
In addition to the narrow-band real-time spectrum scope, which is located
inside the demodulator panel, the G303 receiver also has a wide-band
spectrum scope which operates by fast tuning the receiver across the user-
specified frequency range.
Click on the yellow triangle button on the left of the Power switch and the
Spectrum Scope display will slide out at the bottom:
To set up spectrum “sweeping”, enter the Start and End frequencies, to
specify the start and end of the sweeping range, respectively. Next specify
the frequency Step.
Spectrum Scope
The sweeping is controlled using a set of buttons similar to a tape recorder:
The Start button (with a triangle) starts sweeping. The Stop button (with a
square), stops sweeping, while the Pause button pauses it. The button with
a red round arrow selects continuous sweeping, which means that the
sweep will continue from the start frequency when the end frequency is
reached, and continue in this loop until manually stopped.
The Min, Man and Diff buttons enable the display of minimum, maximum
and differential values when continuous sweeping is selected. (A scale for
the differential trace will be displayed on the right-hand side whenever the
Diff button is pressed.) The differential trace is very useful when examining
long-term activity on a given band. The receiver can be left unattended in
the continuous sweeping mode, and any activity on the band will be clearly
visible on the differential trace.
- 44 -
There are also two Zoom in/out buttons performing their self-explanatory
functions, and a Clear button, which clears the graph and the min/max
values.
Clicking anywhere on the spectrum graph tunes the receiver to the
corresponding frequency. You can also drag the mouse horizontally across
the spectrum and continuously tune the receiver.
To hide the Spectrum Scope, use the yellow triangle button next to the
power switch again.
Did you know?
During the cold war, the Soviet Union and other Communist countries used
to jam shortwave transmissions such as the BBC, Voice of America, Radio
Free Europe and Deutsche Welle to their own citizens. The Soviet Union
alone was spending about $1 billion per year on jamming, and had 200
jamming stations that were continuously pumping out 600 Megawatts of
power.
- 45 -
Appendix A - Troubleshooting
Problem (G303i or G303e with serial interface option only): My PC
does have a Line input, but there is no such Line input shown in the mixer
line list in the demodulator set-up window.
Solution: The mixer line list is provided by Windows. It shows all
available mixer channels which are capable of full duplex operation. It
appears that the Line input of your sound card is not capable of full duplex
operation. This is the case with certain sound cards, most notably with
Creative Audigy 2. You will need to use the Microphone input instead. See
also the related problem below.
Problem: I have connected the receiver to the Microphone input, but
the sound is severely distorted.
Solution: You need to disable the microphone preamplifier – this is
located in the sound card control panel (note the button Advanced under
the microphone volume control). See also the problem below for another
possible cause of this problem.
Problem: I can hear the audio and tune the receiver, but the sound is
distorted.
Solution: Check if the AGC is switched on (i.e. either the Slow, Med
or Fast buttons are down – typically, the Med setting is used).
G303i or G303e with serial interface option only: Check the Input gain
in the demodulator set-up panel: it should be set just below the clipping level
(sometimes a bit lower if the sound card starts distorting before the clipping
is detected). If both settings are correct, try to reduce the sampling rate from
48000 samples/second to 44100 (also in the demodulator set-up). (Using
48000 samples/second should provide better performance if good quality
sound cards are used, but some sound cards are not able to provide good
quality sampling at this sampling rate.)
- 46 -
Problem: I can hear the audio and tune the receiver, but the volume is
too low, even if I adjust the Volume control to maximum.
Solution: Engage the Audio AGC in the demodulator front panel
(typically, the Med setting is used).
G303i or G303e with serial interface option only: Also check the Input
gain in the demodulator Setup panel: it should be set as high as possible,
just below the clipping level.
Problem (G303i or G303e with serial interface option only): The
WiNRADiO application installed OK, but there is no sound coming from the
speaker.
Solution: Check if you see any noise appearing in the demodulator
spectrum scope (under the AM, AMS, etc., mode selection buttons). If there
is a flat line or only very little noise visible, check the following:
• The receiver output is connected to the sound card Line input using the
supplied cable. (If your PC sound card does not have a Line input, you
can use alternative inputs such as Microphone or Aux but the
software settings need to be changed accordingly.)
• The sound card has been set up correctly. Especially make sure that the
Recording Line input has been enabled (you will find this panel under
Options | Recording in your sound card volume control panel – click on
the speaker icon in the bottom bar to get to the volume control panel
first):
- 47 -
Note: If you have difficulties accessing the sound card control panels (for
example if there is no speaker icon), refer to Appendix B – Sound Card
Controls.
• The receiver demodulator has not been set up properly. Make sure that
the sound card type and the audio input are properly selected (this panel
is accessible under the Setup button in the demodulator panel):
• The sound card has the left and right inputs reversed. Normally, the
G303 Demodulator expects the receiver to be connected to the Right
input. Using the reverse input makes the demodulator use the Left input
instead. (This is a very rare problem, so use this only when all other
possible remedies have been explored.)
• Make sure the squelch is not activated.
- 48 -
Problem: I can tune the receiver and see the signal peaks in the
spectrum scope, but I can’t hear any sound at all.
Solution: Check that your speaker or headphone is connected to the
speaker output of the sound card. Set the volume to medium (say 15), the
squelch to the lowest value (-130 dBm) or defeat the squelch by clicking on
the Def button. Make sure the Mute button in the demodulator panel is
released, too, and the speaker output of the sound card is unmuted in the
sound card control panel.
Problem (G303i or G303e with serial interface option only): I can hear
the audio, but it is not a pleasant sound. There is an interfering high pitch
tone.
Solution: You need to mute the Line input in the sound card control
panel - see the panel on the next page. (What you are probably listening to
is the intermediate frequency signal mixed with the demodulated audio
signal.)
Sound Card Volume Control Panel
- 49 -
Problem: I can hear the audio and tune the receiver, but the audio
drops-out occasionally, and the display is very sluggish, sometimes it even
freezes.
Solution: Close all other simultaneously running programs to reduce
the burden on the CPU. If the CPU usage shows consistently more than
80%, this may indicate insufficient CPU resources for the G303 application.
(Check the CPU usage under the Setup button in the demodulator window.
The CPU resource meter is at bottom left.)
Problem: I can hear the audio and tune the receiver, but the audio is
very noisy. The background noise level displayed on the spectrum scope
appears very high.
Solution: Make sure the Attenuator is switched off. Check that your
antenna is properly connected, the connector is not loose and that the
antenna cable is not damaged. Does the noise floor drop significantly if you
disconnect the antenna? If so, then the antenna is picking up too much
ambient noise. Try to improve the antenna, or move it further away from the
PC. (Additional noise-defeating measures may be in order; see also
Appendix C – Dealing With Interference.)
Problem: Reception is obscured with a buzzing interference.
Solution: Check for the sources of interference in your surroundings:
it could be fluorescent lights, a lamp dimmer, or some other household
appliance. Your PC (especially the monitor) could be also the culprit.
Unless you can suppress the interference at the source (which is not always
possible), the only solution is to install a better antenna, preferably an
outdoor one. Computer networks are especially noisy and if your PC is
connected to one, you will almost certainly need an outdoor antenna. If the
interference level varies periodically with peaks about 30-100 kHz apart, the
most likely culprit is the monitor or the video card. Switch the monitor off - if
the interference disappears then the cause is the monitor. Modern LCD
monitors generate much lower levels of interference than CRT ones. (See
also Appendix C – Dealing With Interference.)
- 50 -
Appendix B – Sound Card Controls
Sound card control panels and their settings can be somewhat confusing.
They are also rather inconsistent from one version of Windows to another.
WiNRADiO G303 receivers require a full duplex sound card, meaning that
the card must be able to simultaneously process signals in two directions
(i.e. record and playback) at the same time. The majority of modern Sound
Blaster compatible cards are indeed like that. However, some older cards
may not be full duplex.
The Recording section of a sound card is used to input and digitize the IF
(Intermediate Frequency) signal arriving from the receiver (only the Right
channel is used, of the Left and Right stereo channels). The Playback
section is then used to output the demodulated audio signal to the
speaker(s).
For the WiNRADiO G303 application, there is a need to independently
control both sound card sections: The Recording section volume needs to
be adjusted to provide the correct IF signal level for the demodulation
process; the Playback section control is needed to be able to control the
speaker volume.
Typically, you would access the Playback volume control panel by clicking a
speaker icon in the Windows task bar. From this panel, you can get to the
Recording control panel by selecting Options | Properties | Recording in
the top bar menu.
If the speaker icon is missing, an alternative way of accessing the
Recording/Playback controls is via the Windows Control Panel. Here you
can also enable or disable the speaker icon.
The table on the following page shows how to enable/disable the speaker
icon, and how to get to the recording/playback controls from within the
Windows control panel. The methods vary depending on the version of
Windows you are using.
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Windows Enable “speaker” icon Recording/playback volume controls
NT Control Panel |
Multimedia
Audio-tab
Checkbox: “Show
volume control on the
taskbar”
Make sure the speaker icon is displayed, then
double-click on the speaker icon in task bar to
display the Volume Control dialog.
Sound Playback: Select Options | Properties |
Playback
Sound Recording: Select Options | Properties |
Recording
98 Control Panel |
Multimedia
Audio-tab
Checkbox: “Show
volume control on the
taskbar”
Control Panel | Multimedia
Audio-tab
Sound Playback: Click on button
Sound Recording: Click on button
ME Control Panel |
Sounds and Multimedia
Sounds-tab
Checkbox: “Show
volume control on the
taskbar”
Control Panel | Sounds and Multimedia
Audio-tab
Sound Playback Æ Volume button
Sound Recording Æ Volume button
2000 Control Panel |
Sounds and Multimedia
Sounds-tab
Checkbox: “Show
volume control on the
taskbar”
Control Panel | Sounds and Multimedia
Audio-tab
Sound Playback Æ Volume button
Sound Recording Æ Volume button
XP Control Panel / Sounds
and Audio Devices |
Sounds-tab
Checkbox: “Place
volume icon in the
taskbar”
Control Panel | Sounds and Multimedia
Audio-tab
Sound Playback Æ Volume button
Sound Recording Æ Volume button
- 52 -
Appendix C - Dealing with Interference
Electromagnetic Interference (EMI) is what prevents us from receiving a
clear signal, even when the receiver should be sensitive enough to receive
it. There are many types of interference you can experience with radio
receivers, emanating from both natural and man-made sources.
Natural interference is produced by atmospheric phenomena such as storms
and sun activity.
Not so surprisingly, man-made interference is often worse. Sources include
electric motors, power lines, passing cars, welders, fluorescent lights, fax
machines, computer networks, etc. Receiving antennas should always be as
far away from sources of electromagnetic interference as possible.
One significant source of man-made electromagnetic interference is the
personal computer, and the video monitor in particular. Since the
WiNRADiO G303 receiver requires a personal computer to operate, this
creates a potential paradox. The WiNRADiO receiver itself is designed to be
substantially immune to PC interference. However, any receiver needs to be
connected to an antenna, and antennas can’t discriminate between useful
signals and interference. The interference from your PC can either radiate
directly to the antenna, or it can be conducted to it along the outer conductor
of the lead-in cable. Even in professional radio receiving stations, a lot of
care and effort is always needed, if this type of self-interference is to be
avoided.
Some computers are worse than others in terms of generated
electromagnetic interference. The worst culprits are usually video monitors,
which radiate radio frequencies at multiples of horizontal deflection
frequencies. These frequencies range from about 30 to 100 kHz, and you
can sometimes hear their harmonics right across the entire shortwave band.
If you find strong signals sounding somewhat like a tractor engine, spaced
between approximately 30 and 100 kHz apart (on modern hi-resolution
monitors, the typical frequency is around 94 kHz), your monitor is most likely
the cause.
To check this, tune to one of the interfering signals, then switch off the
monitor and see if the signal disappears. You could continue using the
WiNRADiO receiver, and live with the fact that some useful frequencies will
be obscured by your monitor’s interference, or you can replace your monitor
with a ‘quieter’ one (modern LCD displays are far quieter than old CRT
- 53 -
monitors), or you can try to relocate your antenna further away from your
computer.
A good remedy to try is to wind five to ten turns of the antenna lead-in cable
through a large ferrite core (the doughnut shaped toroid type), near the PC
end of the cable. This suppresses common-mode interference, which is a
typical but curable problem with PC-controlled receivers.
Another type of interference which you may encounter is intermodulation
interference. This is usually caused by strong local stations, whose
frequencies combine to create ‘ghost’ signals on frequencies which are
arithmetic combinations of the stations’ frequencies. These ‘ghost’ signals
can sometimes coincide with useful frequencies, rendering them partially or
completely unusable. They will usually disappear when you switch on the
Attenuator in the receiver control panel. You may also try shortening the
antenna.
If you live very close to a strong local transmitter, these measures may be
insufficient. In such case, you should be able to eliminate intermodulation by
fitting a special filter to your antenna, to reduce the level of the signals
causing the interference. The design and application of such filters falls
beyond the scope of this book, since the large majority of WiNRADiO users
should not experience this problem (after all, not too many of us live next
door to a radio station). However, broadcast frequency filters and tunable
preselectors are standard items and can be obtained from good radio
equipment suppliers.
Did you know?
The first shortwave transmission from space took place on October 4, 1957,
when the first Russian satellite, the Sputnik, was launched. The Sputnik
transmitted amplitude modulated signals on 20,008 kHz. The characteristic
beeping of Sputnik’s telemetry was listened to by millions, ushered in a new
era of political, military, technological, and scientific developments, and
marked the start of the US-USSR space race.
- 55 -
Appendix D - Inside WR-G303
Technically minded users may like to explore the WiNRADiO G303 Receiver
and experiment with some of the innovative concepts of Software Defined
Radio.
The WiNRADiO G303 Receiver is the world’s first commercially available
Software Defined Radio, where the Demodulator function is fully performed
in software running on a standard PC. The G303i model is also the world’s
first shortwave radio on a PCI card, while the G303e model is the first PC-
based shortwave radio with the USB interface. The potential for
experimentation is therefore substantial. This receiver and its software have
been indeed designed to promote and encourage such experimentation.
The WiNRADiO G303 receiver represents only one half of the entire radio.
The other half is your PC.
The receiver hardware contains the following functional blocks:
The incoming signal from the antenna (in the 9 kHz to 30 MHz range) is
filtered and amplified, then fed into a mixer. Here it is mixed with the first LO
(local oscillator), which is performed by a DDS (Direct Digital Synthesizer),
with a PLL (Phase Locked Loop). The resulting 45 MHz intermediate
frequency is filtered using a 4-pole 45 MHz crystal filter with an IF bandwidth
of 15 kHz, and then amplified.
- 56 -
The second mixer again uses a DDS with a PLL to mix the 45 MHz signal
down to the last intermediate frequency, which is 12 kHz.
Both DDS circuits derive their reference frequency from a 20 MHz reference
oscillator.
The 12 kHz IF output is then fed to the right channel of the Line input of the
PC sound card. You can hear what it sounds like if you use the sound card
mixer panel to listen directly to this input (rather than using the G303
Demodulator software).
The AGC is performed in the first IF stage, based on the level of the last IF
output (at 12 kHz IF). As the IF bandwidth of the first IF stage is 15 kHz, the
AGC action is delayed until the dynamic range of the first IF stage is fully
utilized – this is in order not to cause desensitization of the receiver in the
presence of neighboring strong signals, falling within the 15 kHz IF
bandwidth. The resulting variation in audio output is then compensated for in
software, using Audio AGC in the software demodulator.
The final IF bandwidth is then adjusted entirely in software. If the
Professional Demodulator is used, this bandwidth is continuously variable
from 1 Hz to 15 kHz.
Did you know?
The largest shortwave transmitters nowadays operate with 250,000 –
500,000 Watts of power. Using the CW mode, and in suitable atmospheric
conditions, radio amateurs make regular contact around the world with only
a very tiny fraction of this power: reports exist of round-the-world
communications achieved with less than five Watts of power.
- 57 -
Appendix E – Professional Demodulator
The WiNRADiO G303 receiver has provision for additional demodulators, in
place of the supplied standard one. Installed demodulators can be selected
via the Demodulators top bar menu. Check the WiNRADiO Web site
www.winradio.com periodically, for available demodulators.
The Professional Demodulator which is available as an optional extra,
takes the concept of software-defined shortwave receiver a step further. The
main differences between the Standard and the Professional demodulator
are as follows:
• Additional demodulation modes (DSB and ISB)
• Continuously variable IF bandwidth (from 1 Hz to 15 kHz)
• User-adjustable IF filter coefficients and other parameters
• User-adjustable audio AGC
• User-definable IF bandwidth presets
• Interactive demodulator structure with two spectrum scopes and a
vector voltmeter
• Additional instrumentation (SINAD and THD meter)
• AF Squelch for FM mode
WiNRADiO G303 Professional Demodulator
- 58 -
The front panel of the Professional Demodulator looks similar to the
standard one. Note in particular the added DSB and ISB modes, the
continuous IF filter bandwidth control, enhanced Audio AGC (the time
constants are user definable in the Setup window), and a row of IF
bandwidth preset buttons at the bottom. The numbers on top of the IF
bandwidth preset buttons indicate the associated bandwidth (in kHz). These
presets, too, are entirely user-definable.
To change the IF bandwidth, you can type the desired value (in Hz) directly
in the IF bandwidth editbox, or use the associated up/down buttons.
Do not overlook the small but very significant slider located between the
bandwidth up/down arrow buttons: It allows you to change the IF bandwidth
within a large range, by moving the slider cursor up and down, with a very
impressive effect:
In the real-time spectrum scope, the currently selected IF bandwidth is
indicated using a different background color. The portion of the real-time
signal spectrum falling within the IF bandwidth is shown in yellow.
Adjusting Demodulator Parameters
Each demodulation mode has its own associated set-up panel, accessible
under the Setup button (located under the CW mode button). By selecting
the mode either using the front panel or the tabs at top-right of the
demodulator set-up window, you can see and adjust the filter settings
applicable to the selected modes.
The meaning of each filter is best understood looking at the demodulator
structure (under the View demodulator structure button). The cut-off
frequencies and lengths of these filters can be adjusted and optimized by
the user, either by direct typing in the parameter or using the sliders.
Each filter length (i.e. the number of its taps), can be an odd number
between 3 and 255. The more taps, the better the filter characteristics, and
the better the performance of the receiver, but the computing task for the
CPU is harder. Therefore, while increasing the filter lengths, always watch
the CPU usage (shown at bottom left of the demodulator Setup window) in
order not to starve the operating system of CPU resources (80% is a good
- 59 -
upper limit). Starving the system of CPU resources manifests itself by the
computer becoming sluggish or possibly "freezing" entirely.
The first parameter, the IF bandwidth filter length, is the length of the first
filter in the digital path, which is responsible for much of the receiver
selectivity. The factory default length is 63. Reducing this value will
decrease the receiver selectivity and make the receiver more prone to
interference from nearby strong signals. However, for slower computers it
may be necessary to compromise on this figure if the demodulator appears
too slow (to the point of the panel "freezing" or drop-outs of audio) because
of insufficient CPU resources. If your CPU speed allows it, then we would
recommend to set this value to its maximum limit (255):
The Post-mixer filter length parameter refers to the post-mixer low-pass
filter, whose cut-off frequency is automatically related to the currently
selected IF bandwidth. For AM, AMN, AMS, CW, DSB, ISB, FM3, FM6 and
FMN modes, the post-mixer filters bandwidth is half of the IF bandwidth,
while for LSB and USB both bandwidths are equal to the IF bandwidth.
Again, if your CPU speed allows it, we would recommend to set this
parameter to its maximum value (255).
If you have a preference for particular IF bandwidths, you can associate
them with any of the ten preset buttons (located at the bottom of the
demodulator front panel) by double clicking the Bandwidth column of the IF
bandwidth presets table, and then typing in the numerical bandwidth value in
- 60 -
Hz. The buttons are numbered (1 to 10) from left to right. The factory default
values can be restored at any time, by pressing the Restore default
settings button. Each modulation mode has a separate set of IF bandwidth
presets.
For the AM, AMN, FM3, FM6 and FMN demodulators, a supplementary
low-pass filter is introduced in the audio output path, to reduce harmonic
distortion generated in the demodulation process and improve the overall
signal-to-noise ratio under bad receiving conditions. This filter’s length is
adjustable under the Audio filter length parameter.
Finally, a noise-derived squelch is implemented for frequency modulation
modes, FM3, FM6 and FMN. The energy of the noise present above the
useful voice baseband is used as a signal presence indicator. The
user can modify the length of the high-pass filter separating that noise,
Squelch filter length. The squelch control appears on the demodulator
front panel when any of the FM modes is selected. This makes it possible to
adjust the noise threshold level at which the squelch will mute the audio.
Finally, all demodulated audio output is scaled up by an Audio gain factor.
The scaled audio signal level is further adjusted with the Volume control in
the demodulator main panel. However, when the Audio AGC is active, the
fixed Audio gain setting is ignored, and the software will automatically
adjust the audio level according to the AGC reference level setting.
If you are experiencing audio distortion when using the Audio AGC, this is
probably because the AGC reference level is set too high.
The attack and decay times for the three possible Audio AGC speeds (slow,
medium and fast) can be also configured, under AGC Speed Constants on
the left of the demodulator settings window:
- 61 -
Demodulator Structure
The G303 Professional Demodulator implements the general quadrature
representation of all narrow-band modulated signals. Such signals can
always be considered as the sum of two amplitude-modulated carriers
having a 90 degree offset, usually referred to as I and Q. Users familiar with
Software Defined Radio digital signal processing concepts, will find the
G303 Professional Demodulator to be a useful tool for experimentation and
study, where the effects of various filter settings can be easily observed and
optimized.
The entire demodulation process can be observed in the demodulator
structure window, accessible from within the demodulator settings (press the
Setup button under the CW mode button), then the large View
Demodulator Structure button). Each mode has its own associated
structure. By selecting the mode either using the front panel or the tabs at
top-right of the set-up window, you can observe the different structures
applicable to the selected modes. Each mode also has its own set of filter
settings available for experimentation.
AM Demodulator Structure
- 62 -
The demodulator structure windows include two spectrum analyzers, making
it possible to view signal spectra in real-time. Each analyzer can be
"connected" to any of the test points shown as green dots in the diagram. To
connect the left spectrum analyzer to a particular test point, left-click on the
green test point. Its color will change to red. Right-clicking on a dot will
connect it to the right analyzer, and the color will change to blue. If both
displays are connected to the same test point, the point color will turn
magenta.
Within the displayed spectra, a red color frequency cursor can be manually
dragged, using the left mouse button, over a particular spectral component.
The two Vector Voltmeter displays labeled Left/Right indicate the relative
amplitude and phase difference between the two spectral components at the
cursor frequency.
There are two additional tools provided in this window: THD (total harmonic
distortion) and SINAD (signal-plus-noise-plus-distortion to noise-plus-
distortion) meters. They can be used to test the overall receiver performance
as well as provide indication of the sound card quality. To use these
facilities, a pure tone-modulated signal must be applied to the receiver
antenna input, and the frequency of the modulating tone must be equal to
the Test freq setting.
When either of the THD or SINAD buttons is activated, the right-hand
spectrum display will be automatically connected to the end of the
demodulator chain (i.e. right-clicking on any other test points will not work
until both the THD and SINAD buttons are released).
For synchronous demodulation of amplitude modulated signals (the AMS
mode) without carrier or with a fluctuating one, the G303 Professional
Demodulator uses a digital carrier recovery technique based on the so-
called Costas loop:
Synchronous AM Demodulator Structure
- 63 -
The LSB and USB demodulators have basically the same topology:
USB Demodulator Structure
ISB can be thought of as a combination of LSB and USB, where each of the
sound card channels is used for one of the independent side bands.
The CW received signals are first down-converted to zero Hz, and then,
after additional channel filtering, up-converted to a convenient audio
frequency. This frequency (a digital BFO) is user-adjustable, by changing
the value of the CW tone frequency parameter in the demodulator set-up.
CW Demodulator Structure
Did you know?
The impressive sensitivity of the G303 receiver and the continuous IF
bandwidth adjustment facility make it possible to precisely match the
bandwidth of the receiver to that of the received signal and extract even the
weakest CW signals from background noise.
- 64 -
Finally, all FM demodulators have the same block diagram. The only
differences between these demodulators are the bandwidth values of the
input IF filter and the two post-mixer filters:
FM Demodulator Structure
Did you know?
All the software-implemented digital filters used in the G303 receiver are of
the linear phase FIR (Finite Impulse Response) type, with maximum 255
taps, providing a filter shape far superior to conventional analog hardware
filters.
- 65 -
Appendix F - Developer Support
WiNRADiO has always extensively supported third-party software
development efforts with all our receivers, and the WiNRADiO G303
receiver is no exception. We provide technical details for developers to be
able to develop the following:
1. Third-party applications controlling the WiNRADiO G303 receiver.
We do this by providing API information making it possible to access the
receiver hardware from third party software. (See
http://www.winradio.com/home/developer.htm).
2. Plug-ins to provide enhanced functionality. For this, we have developed
a special interfacing standard called XRS (Extensible Radio
Specification). All our receivers conform to this standard, and many
plug-ins are already available for various applications (see
http://xrs.winradio.com).
3. New types of demodulators. The G303 demodulators in fact represent a
special type of XRS plug-in. Detailed information is also available at
http://xrs.winradio.com).
4. Support under alternative operating systems. See for example
http://www.linradio.com.
5. Support under Radio Basic, an easy to use specialized programming
language for radio receivers. See http://www.rbasic.com.
Have you registered yet? WiNRADiO provides regular upgrades to our
application software. Use our on-line registration form on
www.winradio.com/register to take advantage of this free service.
- 66 -
Appendix G – Frequency Calibration
The G303 receiver series features an excellent frequency accuracy and
stability for a receiver of its class. It is however possible to improve this
accuracy yet further, by individual calibration.
The receiver calibration is accomplished by inserting a reference frequency
parameter in the wrg3.ini file which resides in the Windows directory. The
reference frequency parameter consists of two lines of the following format:
[ClockCalibration]
receiver_serial_number=reference_frequency
The receiver serial number can be obtained from the About box in the G303
application. The reference frequency is the actual frequency of the internal
reference oscillator in Hz. This is nominally 20 MHz, i.e. 20000000 Hz.
Each receiver is factory calibrated, so a correction to the nominal 20 MHz
reference frequency already exists and is stored in the receiver's internal
memory. This correction can be overridden by the new parameter in the
wg3.ini file. To determine the true offset from a perfect tuning, firstly use
20000000 (i.e. the nominal reference frequency in Hz) as the new
reference_frequency parameter. Say your receiver serial number is
02L27011:
[ClockCalibration]
02L27011=20000000
Open the existing wrg3.ini file, add the above two lines, then save the file
and start the G303 application. The frequency error will now be much worse
because this new parameter overrides the original factory calibration. Then
tune the receiver to a known frequency standard. A high-accuracy signal
generator can be used, or one of the WWV Time and Frequency Standard
stations. Observe the peak with the spectrum scope and listen to the beat
frequency in the CW mode with a minimum IF bandwidth. Typically, this will
be a negative number (for example, -652 Hz at 10 MHz).
Then scale the frequency difference to 20 MHz. For example, if the
frequency difference is -652 Hz at 10 MHz, it will be -1304 Hz at the 20 MHz
reference frequency.
- 67 -
Then subtract the frequency difference from 20000000. In our example, the
resulting reference_frequency will be 20000000-(-1304)=20001304. The
entire reference frequency parameter in the wrg3.ini file will be then as
follows:
[ClockCalibration]
02L27011=20001304
Save the wrg3.ini file, then restart the G303 application and observe the
difference.
To return to the original factory frequency calibration, simply delete the
inserted two lines in the wrg3.ini file. You can also delete the entire file
(which will however result in losing all current receiver settings and return to
factory defaults for all of them).
Did you know?
The WWV Time and Frequency Standard stations which broadcast on 2.5,
5, 10, 15 and 20 MHz, have a long history that dates back to the very
beginning of radio broadcasting. The call letters WWV were assigned to the
US National Institute of Standards and Technology (then called the National
Bureau of Standards) in October 1919. By December 1922, it was decided
that the station’s purpose would be the transmission of standard frequency
signals. The accuracy of the transmitted frequency was quoted as being
better than 0.3 per cent. Nowadays the station frequency is controlled within
one part in 1013, which represents frequency accuracy thirty billion times
better.
- 68 -
Declaration of Conformity
This device, trade name WiNRADiO Communications Receiver, model
number WR-G303 complies with Part 15 of the FCC Rules. Operation is
subject to the following conditions: (1) This device may not cause harmful
interference, and (2) this device must accept any interference received,
including interference that may cause undesired operation.
I have determined and warrant that the above described device has been
shown to comply with the requirements of the FCC Part 15, by having a
device tested at an accredited testing laboratory. Each unit marked is
identical to the device as tested. Compliance assumes no unauthorized
changes will be made to the equipment and it will be maintained and
operated properly. A test report has been generated. A technical file
containing the test report will be maintained for a period of at least 2 years
after manufacturing ceases. It is also understood that characteristics of this
equipment will require retesting.
Please forward all correspondence related to this matter to:
Compliance Manager
Rosetta Laboratories Pty.Ltd.
15 Stamford Road
Oakleigh 3166
Australia
Tel: +61 3 9568 2568
Fax: +61 3 9568 1377