Articles by Tom Mechler
Well-designed intrusion detection devices are capable of ignoring non-intruder events, thereby reducing false alarms Intrusion detection devices must maintain a delicate balance. Highly sensitive devices can cause too many false alarms while devices with insufficient sensitivity are easily defeated by sophisticated intruders. Innovations in intrusion detection technology have enabled significant advancements in performance, resulting in excellent catch performance while virtually eliminating false alarms. In this article, Tom Mechler, Product Marketing Manager for intrusion products for Bosch Security Systems in North America explains that well-designed intrusion detection devices have the capability to ignore non-intruder events such as pets and other animals, changes in room temperature or lighting conditions, moving shadows, moving electrical appliances and other harmless events. These detectors incorporate and analyze data from multiple sensors, including a long-range passive infrared (PIR) sensor, short-range PIR sensor, microwave sensor, white light sensor and temperature sensor. The concept of gathering data from multiple sensors isn’t new. Many detectors combine data from various sensors, but simply building multiple sensors into a detector does not increase its effectiveness. Using multiple sensors as checks and balances may increase a detector’s false alarm immunity but does so at the cost of catch performance. The critical difference is in the way this data is processed. Sensor data fusion collects information from all of the sensors and feeds it into a microprocessor that analyzes the data using complex algorithms. This enables the detector to balance sensors and adjust sensitivities in order to make truly intelligent decisions to determine valid alarm conditions. Sensor Data Fusion Technology in Intruder Detectors at Work Since white light sensors prevent false alarms, burglars try to trick detectors with a flashlight Following are a few examples of how data fusion from sensors works in practice in a wide range of conditions that otherwise have high potential for triggering false alarms. Car Headlights Sweep Across Detector As a car pulls into the parking lot at night, the headlights sweep across the detector’s mounting location. Because the PIR sensors are sensitive to slight temperature changes, they detect the headlights at both short and long range. Of course, the white light sensor detects the headlights too. The key to this scenario is the synchronization of the data from the PIR sensors and the white light sensor. The heat and light change in tandem each time the headlights sweep across the detector. The microprocessor algorithm is aware of this synchronization and determines that this is not a valid alarm condition. The security system does not go into alarm. Burglar Tries to Trick Detector Using Flashlight Aware of the white light sensor and its role in preventing false alarms, a burglar tries to trick the detector with a flashlight. Because of the location of the burglar, he appears only on the long-range PIR sensor, not the short-range. And since the disturbance is detected at long range, the sensitivity of the microwave sensor is increased and its alarm threshold lowered. Most importantly, the microprocessor algorithm is aware that the data from the PIR sensor, the white light sensor and the microwave sensor is not synchronized and determines that this is a valid alarm condition. Mouse Crosses Room 4.5m from Detector Many detectors combine data from various sensors, but simply building multiple sensors into a detector does not increase its effectiveness When a mouse is just 4.5 m from the detector, only the short-range PIR sensor reacts. A human intruder that close to the detector would reflect a large area to the microwave sensor, so when only the short-range PIR detects a signal, the microprocessor raises the microwave sensor’s threshold. The distance data provided by the two PIR sensors allows the microprocessor to vary the microwave sensor’s threshold. And because the mouse reflects a small area to the microwave sensor, the newly elevated threshold is not reached, and the security system does not go into alarm. These are just a few examples showing how sensor data fusion technology can work. There are innumerable scenarios where it comes into play to catch real intruders while minimizing false alarms. In addition to the sensor technology described above, there are other sensors that play an important role in intrusion detection. A description of these follows. Pet Immune Detectors Pet immune detectors use precise optics and specialized signal processing to distinguish between signals caused by humans and those caused by pets. This allows them to ignore signals caused by one or two pets up to approximately 45 kg or signals caused by numerous rodents. Temperature Sensors Some detectors with temperature sensors simply increase sensor gain as room temperature increases. This gain increase continues linearly as the room temperature exceeds the expected surface temperature of an intruder (33.3°C). Thus, the chance of false alarms climbs right along with the room temperature. With advanced detectors, the sensor gain increases as expected, but only until the room temperature reaches 33.3°C. Using two PIR sensors with multiple high-quality lenses, the signal-to-noise ratio can be increased only within that narrow temperature band. Once the room temperature exceeds the surface temperature of an intruder, the sensor gain decreases again to minimize false alarms. Anti-mask Technology Anti-mask technology alarms when an intruder attempts to defeat the detector by masking it with infrared-blocking material, such as paper, tape, film or spray. Typically, an intruder employs these strategies during normal business hours when the security system is disarmed, then returns later with the knowledge that the motion detectors are compromised. Multi-point anti-mask with integrated spray detection technology recognizes masking attempts from black paper, aluminum and acrylic sheets, white polystyrene foam, clear self-adhesive vinyl, spray-on plastic skin, clear lacquer (brush applied), spray paint and more. This is accomplished with the following technologies. Bounce-Back Technology determines if the detector is covered or blocked by an object, such as a shoe box or a piece of paper. With bounce-back technology, the detector creates a bubble of infrared energy extending approximately 30 cm in front of the detector. This bubble radiates from the IR emitter. If the detector is blocked, an above-normal level of IR energy reflects back through the detector’s lenses. The detector uses multiple IR photodiodes to detect the extra IR energy levels, and then sends a trouble signal to the security system indicating that someone masked the detector. Retro Reflector Technology determines if someone attempts to compromise the detector with a sprayed-on material, such as paint. The detector’s LED light pipe contains the Retro Reflector’s advanced multi-prismatic structure. In normal conditions, the Retro Reflector structure reflects IR energy back into the detector where it is detected by a dedicated IR sensor. When the prismatic structure is coated with a spray material, the reflective properties of the prisms are negated, allowing the IR energy to pass through the prisms and out of the detector. A dedicated IR photodiode senses the reduced reflected IR energy level and then sends a trouble signal to the security system. Through-the-Lens technology determines if a material is placed directly on the detector lens, such as tape or any other IR-opaque material. The detector emits IR energy back upon itself from two specialized prisms located at the bottom of the detector. If the lens is masked, a photodiode receives reduced IR energy levels. The detector then sends a trouble signal to the security system indicating that someone has masked the detector. As you can see, there have been many innovations in intrusion detection technology over the last decade. Conventional intrusion detection devices that degrade catch performance for false-alarm immunity or vice versa are being replaced by technology that eliminates the need to compromise between the two critical functions. Look closely at the technology in the detectors you use for your next project, so you can be sure you’re providing your customers with the best performance for their security systems. Not all detectors are the same.
The cloud is an enabling technology that brings new opportunity to security dealers and integrators and a way to provide popular services to customers in every market vertical. A seamless integration between Bosch B and G Series Control Panels and Connect ONE by Connected Technologies LLC makes it simple for dealers to add intrusion detection and access control services from a single panel while using one interface to manage every customer. Bosch-Connected Tech Integration “We’re excited to be working with Connected Technologies to offer this service to our dealers, whose feedback has been extremely positive as they continue to add customers,” said Tom Mechler, Regional Marketing Manager for Bosch. “This integration provides a complete intrusion and access control service along with mobile credentialing.” Mike Simon, Managing Partner and Co-Founder of Connected Technologies said Connect ONE enhances the Bosch panels, which are great platforms for dealers to offer value add services and increase their monthly recurring revenue streams. The integration between Bosch panels and Connect ONE allows dealers to customize services that meet their business goals and customer’s needs" Bosch Panels And Connect ONE “The integration between Bosch panels and Connect ONE allows dealers to customize services that meet their business goals and customer’s needs—from residential to both small and large commercial projects,” said Simon. “It’s a complete, robust platform for intrusion and access control, with no need for a separate access control panel or hardware. Given the industry’s ongoing challenge in finding skilled technicians, it also allows dealers to standardize with Bosch panels, which is extremely important for training and inventory control.” Remote Connect Cloud Service Connect ONE also works in conjunction with the Remote Connect Cloud Service from Bosch, offering cloud-based connectivity to its B and G Series intrusion panels for remote programming and end-user app connectivity. This capability makes it easier to connect and program control panels without extensive IT experience or dedicated IT personnel. Remote Connect Cloud Service eliminates the need to change customer router settings, incoming firewall rules or use Domain Name Service (DNS) to access the systems remotely. Connect One customers can easily add and delete codes and multiple locations can be seamlessly managed, viewed and controlled all simultaneously on one screen.
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