FG-1025 Family - Technical Note - 1
Technology Overview
FG-1025 Family
Glassbreak Detectors
2 - FG-1025 Family - Technical Note
Technical Note
FG-1025 Family
Glassbreak Detectors
Overview
This T echnical Note is intended to explain in detail the technical advancement of the new FG1025 family of glassbreak detectors over the previous FG-730 family of products. Further, it is
intended to highlight the benefits of those enhancements to the customer . This Technical Note is
not confidential, and can therefore be provided to customers who have a technical interest in our
new FG-1025 family of glassbreak detectors.
Market Demand
The FlexGuard® FG-730 is the world’s best selling acoustic glassbreak detector, with well over
one million detectors installed worldwide. This popularity was achieved due to the detector’s
excellent glass break detection and false alarm immunity .
However , since the introduction of the FG-730, the market for glassbr eak detectors has changed.
The market now demands detectors without sensitivity adjustments for ease of installation, detectors which detect even the most minimal quiet breaks, and detectors with outstanding false alarm
immunity . Our new FG-1025 family meets these requirements.
Theory of Operation
Using a dual channel design, the FG-730 uses two technologies: listening for the acoustic sound
of glass breaking, and sensing the “flex” pressure generated when glass breaks. Signals are compared to set thresholds in the detector , and the detector alarms if the thr esholds are cr ossed. The
significant technical breakthrough of the FG-730 was sensing the flex, thus the name FlexGuard.
The FG-1025 family is based on the same flex/audio principle of dual technology sensing, but
with far more signal processing using an on-board micr ocontroller .
FlexGuard Signal Processing Design
C&K is a registered trademark of C&K Components, Inc. FlexGuard and IntelliSense are registered trademarks of IntelliSense Security Systems, Inc..
FG-1025
FG-1025ZFG-1025R
FG-1025 Family - Technical Note - 3
The FG-730 family of FlexGuard products are all analog devices. They route the signal from the
microphone through a series of discrete (individual) components on the circuit board. The signal
passes through circuitry gates which compare the signal to fixed threshold settings to see if the
amplitude (intensity) of the signal is greater than the threshold. The three threshold settings are:
Flex level threshold: Does the signal exceed a fixed level for the flex?
Audio level threshold: Does the signal exceed a fixed level for the audio?
Time coincidence: Are the two thresholds both crossed within a time window of less than 200 millisec-
onds?
If these three set conditions occur, then the detector alarms.
FG-1025 Signal Processing Design
FG-1025 glassbreak processing is an order of magnitude beyond the FlexGuard. The heart of the
FG-1025 family is a Motorola 68HC05 micr ocontroller . Using four on-board A to D converters, the
microcontroller converts the analog signal into a digital datastream. Only the FG-1025 family uses
an advanced microcontroller, providing 2,1 12 bytes of ROM, 128 bytes of RAM, an internal clock,
and 21 lines of input/output all on-board.
The FG-1025 family is more computer than detector . It uses 1,019 lines of assembly language
computer code, each one a separate instruction for processing the digitized signal from the microphone. This software program is executed within the central processor unit (CPU). The custom
software is permanently burned into the microcontroller’s ROM at the Motorola factory, virtually
eliminating the possibility of memory loss. The FG-1025 family is the only glassbreak to use factoryinstalled masked ROM microcontrollers. Other detectors on the market use OTP (EPROM) alterable memory , which can be subject to memory loss.
The FG-1025’s digitized signal is compared against eight thresholds:
Flex level threshold: Does the signal exceed a level for the flex?
Audio level threshold: Does the signal exceed a level for the audio?
Time coincidence: Are the two thresholds both crossed within the time window?
Flex/audio ratio: Is the ratio consistent with glass breaking?
Attack threshold: Does the signal match an attack profile?
Flex duration: Does the duration match a glass break profile?
Audio duration: Does the duration match a glass break profile?
Microphone overload: Does the signal represent a true glass break attack instead of microphone
overload?
If these eight conditions occur , then the detector alarms.
FG-1025
FG-1025R
4 - FG-1025 Family - Technical Note
Detector Intelligence Through Digital Signal Processing
The FG-730 is a “dumb” detector in that the signal is compared against three fixed thresholds.
The thresholds remain the same regardless of conditions because the thresholds are built out of
discrete components on the circuit board.
The FG-1025 family of glassbreaks are “intelligent” detectors. The software uses proprietary
mathematical formulas (algorithms) to process the signal and to adjust thresholds based on current
conditions. False alarm rejection algorithms identify and reject whole classes of false alarm sounds.
Glassbreak detection algorithms identify true glass break conditions for all glass types and attack
profiles. Thresholds ar e adjusted up and down as warranted by data received at the detector. In
sum, the FG-1025 family's reliability is the best on the market because it performs 20 times more
processing in the critical first 200 milliseconds of an event than that performed by the FG-730.
Patents have been filed on the FG-1025 family and its digital signal processing.
COMP ARISON CHART
FG-730/930 FG-1025/1025R FG-1025Z
flex level flex level flex level
audio level audio level audio level
timing coincidence timing coincidence timing coincidence
flex audio ratio flex audio ratio
attack threshold attack threshold
flex duration flex duration
audio duration audio duration
microphone overload microphone overload
time-of-arrival
The Latest Glassbreak Innovation - FG-1025Z
The newest member of the FG-1025 family of glassbreak detectors is the FG-1025Z. This is the first
glassbreak detector that only listens for sounds coming from the glass. The FG-1025Z uses patented
Time-of-Arrival (TOA) processing which is a giant leap forward in glass break detection and false
alarm immunity for our industry. Using two microphones and TOA processing, the detector
listens only for the sound of breaking glass arriving from the glass zone (front microphone), and
ignores sounds arriving from elsewhere in the room—the excluded zone (back microphone). Other
glassbreak detectors are space protection devices because they process sounds from the room interior , as well as sounds from the perimeter glass.
FG-1025Z
FG-1025 Family - Technical Note - 5
What Is Time Of Arrival (TOA)?
Time-Of-Arrival (TOA) is a method of processing sound to distinguish between true glass break
attacks and false alarm sounds. Sounds are received by two microphones, 180o opposed, and
processed differently depending on which microphone received the sound first. Sounds arriving
first from the glass zone (front microphone), are processed to determine if a true glass break attack
occurred. Sounds arriving first from the excluded zone (back microphone), are ignored as false
alarm sounds. This innovative technology dramatically increases accuracy, reliability and false
alarm immunity .
Additional FG-1025Z Enhanced Features
The FG-1025Z incorporates three additional enhancements: Remote LED Enable, T rouble Output, and Command Input. Focused on meeting worldwide compliance standards, the Remote
LED Enable feature allows remote operation of the LEDs. The Trouble Output allows remote
annunciations of any trouble conditions the detector may have. The Command Input feature
allows local and remote activation of the detector's self-test.
Solutions To Microphone Overload
Extremely loud glass break events, such as a bullet blowing out a huge window , can overload a
glassbreak detector microphone causing a detector to false alarm or causing a detector to miss a
detection, depending on the circumstances. The FG-930 was the world’s first detector to solve
microphone overload. In a now patented process, a second microphone with a mechanical filter is
able to filter out the overload, allowing the detector to respond normally to the glass break event,
and to reject loud burst false alarms. The FG-730 does not have this feature, so its design treats these
loud burst events as glass break events in order to maximize detection.
An even more ingenious solution is incorporated into the FG-1025 family. A digital filter inside
the microcontroller catches and converts overload signals to normal signals, virtually eliminating
burst related false alarms and significantly improving catch performance of previously “impossible
to detect” glass break events.
6 - FG-1025 Family - Technical Note
Verification Of Proper Operation
The yellow flex LED on the FG-730 detectors will flash if a wall is struck. This provides some
comfort to the end-user by providing visual feedback that the detector is still powered. Unfortunately, this test must be initiated by the end-user, and it is not an indication of the detector’s
operational status, only that the LED still works.
The FG-1025 family uses the microcontroller to conduct a continuous self-test of the detector . It
checks the ROM memory , RAM memory, controller logic, controller arithmetic, and the analog
circuitry surrounding the microcontroller . In the unlikely event of damage or failure, the LEDs
will begin to blink alternately in rapid succession to attract the attention of the end-user .
The end-user can also periodically test the detector’s power with a simple clap of the hands. The
green LED blinks, exercising the circuitry and providing the end-user with visual confirmation.
This simple test can be of great comfort to the end-user who wonders whether the detector is active,
since real glass break events are infrequent, and since breaking real windows as a test is rarely
practical.
CONTINUOUS SELF-TESTS OF:
4 ROM memory
4 RAM memory
4 controller logic
4 controller arithmetic
4 analog circuitry surrounding the microcontroller
Activation Of Test Mode
At installation, the range of the FG-730 can be easily tested using the FG-700 or the FG-701 handheld glassbreak simulator. Following a flex signal initiated by the installer , the FG-700 or the FG-701
produces an audio signal realistic enough that in combination with the flex it trips the detector
into alarm. This essentially is a false alarm which trips the detector .
The false alarm rejection algorithms in the FG-1025 family of detectors are too good to be fooled
by the FG-700 or the FG-701 simulator . The detectors do not trip to this false alarm. These detectors
must obviously still be range-tested, so a test mode is used. In test mode, the false alarm rejection
algorithms are bypassed, while leaving the glass break detection algorithms in place. In this way,
test mode provides a valid test of detector range.
FG-701
Glassbreak
Simulator
FG-1025 Family - Technical Note - 7
Using Hand-held Testers To Confirm Detector Range
The old FG-700 tester can be used on the new FG-1025 family of glassbreak detectors. The
installer opens the detector, shorts across the two pads with a scr ewdriver, and the detector goes
into test mode for 10 minutes, after which it automatically reverts to normal mode. Once in test
mode, the installer tests the detector's range using the FG-700 Glassbreak Simulator .
An easier method is to use the new orange colored FG-701 tester . Rather than climbing a ladder ,
the installer puts any of the FG-1025 family into test mode by firing the tester at the detector from a
distance of up to 10 feet (3 meters) away . The detector can then be tested for range. After 10 minutes
the detector automatically reverts to normal mode. Also, the detector can be taken out of test mode
by firing the tester at the detector .
The activation sound which places the FG-1025 into test mode is a sequence of seven short clicks.
The time interval between each click is unique, and the detector listens for this unique pattern.
One fear is that the detector might go into test mode on its own due to hearing a sound similar to the
test mode activation sound. The consequence would be that false alarm immunity for the detector
would be reduced for 10 minutes. Fortunately, this is very unlikely to occur due to the unique
timing sequence between the seven clicks. Calculating for even worst-case noise conditions, the odds of
a sound causing a false activation into test mode is one in two billion.
Improved Ease Of Installation
With over one million FG-730 detectors installed worldwide, we have received many suggestions on how to make a glassbreak detector easier to install. The FG-1025 family reflects these
suggestions:
No sensitivity adjustment, the detector is lick and stick
A large, centered wiring hole for easy threading of wires
Huge wiring space and 45 degree gate type terminal blocks for quick hookup
Dip switches to eliminate the frustration of lost jumpers
Inside plastic cover protects the electronics from accidental damage
Terminal block positions and room for wiring EOL resistors
A hinged cover which snaps off for easier access if needed
25 foot (7.6 m) range without adjustment covers almost any room
No restriction on how close the detector can be mounted to the glass
No restriction on where the detector can be mounted in the room
Hidden LEDs for a beautiful appearance
8 - FG-1025 Family - Technical Note
Benefits Of The FG-1025 Family Of Glassbreak Detectors
1. The microcontrollers false alarm rejection algorithms eliminate most known false alarm sources.
Compared to the FG-730, which has excellent false alarm immunity, false alarm sources are reduced by
two-thirds. Comprehensive tests show that the FG-1025 family has the best false alarm immunity on the
market.
2. The microcontrollers algorithms provide superior detection of breaking glass, including very
challenging breaks such as quiet breaks. Compared to the FG-730, which has excellent glass break
detection, the FG-1025's detection of very challenging breaks is increased an additional 50%. Again,
comprehensive tests show that the FG-1025 family has the best detection on the market.
3. The hand clap feature provides the end-user with peace of mind. The end-user can instantly check a
magnetic contact by opening a door, or a motion detector by walking across the room, but no one wants to
break a window to test the glassbreak detector. A simple hand clap will tell the end-user if the detector is
active. Although the clap test is only a limited test, it does verify the detector is powered, the microphone
is operational, and the microcontrollerthe heart of the detectoris functioning and executing its
program. If there was a problem, the LEDs would flash repeatedly indicating the microcontrollers
continuous self-test had found a problem.
4. Hiding the LEDs behind the cover provides for a more attractive appearance, and for about 10% of the
installations, attractive products are what sells the end-user.
5. The new FG-1025Z only listens for sounds coming from the glass. Using two microphones and
Time-Of-Arrival processing, the detector listens only for the sound of breaking glass arriving from the glass
zone, and ignores sounds arriving from elsewhere in the room (excluded zone).
6. FG-1025 family detectors are a safer installation for the installer and the customer. The installer will not
always know the exact type and thickness of the glass to be protected. FG-1025 family detectors have the
industry's widest specification for glass types and thicknesses, increasing the likelihood that the detector
will perform as expected regardless of the glass installed in the room.
Plate glass T empered glass
Wired glass Sealed insulating
glass
Laminated &
coated glass
Widest specification for
glass types and thicknesses
© 1995 C&K Systems, Inc. 5-052-401-00 Rev A
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