A bed bug attracting assembly is positioned at an upper location. A bed bug killing assembly is positioned at an intermediate location beneath the attracting assembly. A base assembly is positioned at a lower location beneath the killing assembly for maximizing the number of bed bugs attracted and killed. A control assembly has a user visible digital UPC code, a battery power percentage indicator with an ON/OFF button and a sound activated switch, a cell phone with a macro-lens, and two light emitting diode positioned adjacent thereto to illuminate bed bugs. An electric grid triggers a camera detector. A CO2 self-emitting device includes graphite and an electrical charge. A platform with pores holds a lure over a miniature fan. A programmable computer is preprogrammed to modulate attraction modalities. A GPS transmitter is activated to sent to receives to secure the area of infestation.

A bedbug trap that has a series of stacked containers. The top container holds a quantity of water, sugar and yeast, which generates carbon dioxide. The central container holds a small heating pad to attract the bedbugs and to heat the water and yeast mixture to aid in the fermentation. A hose with a water trap system brings the generated carbon dioxide from the upper chamber to the bottom chamber. This chamber sits in a bowl that has a rough exterior and a smooth interior. Holes, formed around the base of the bottom chamber allow the carbon dioxide to escape into the room, which attracts the bedbugs. The assembled unit is large, to trap as many bedbugs as possible in the shortest amount of time. Finally, the water, sugar and yeast are common household items that are easily and cheaply replenished as needed.

The external trap for the small hive beetle A. tumida is composed of an opened on top plywood box and a grid of metal sheet with holes closes the box. The grid can be removed for inspection. Two angle aluminum hang the trap to the front wall of the beehive to catch the larva when it leaves the hive for pupation. The grid addresses the larvae inside the box filled with ground and nematodes that destroy them.

A sleep security method comprises the steps of providing a bed; providing at least one sensor for the detecting of a sleeping condition and for generating a signal in response to such detecting, the at least one sensor being located in operative proximity to the bed; providing a printer; providing a transceiver; operatively coupling the at least one sensor to the printer through the transceiver; and creating a written record by the printer of the detecting of the sleeping condition.

A mite trap for the purpose of early detection, viewing and assessment of mite infestation.

A mite trap that includes a mite attracting material.

A mite trap made of transparent plastic including a mite attractant.

Inside the trap is a compartment containing double sided tape or adhesive, hydrated super absorbent polymer, the pheromone neryl propionate, fish food flakes and fabric to absorb the attractants.

The absorbent material may be made of cotton, paper, wool, nylon or any other absorbent material.

The trap has an opening to allow mites to enter the trap and get stuck on double sided tape or adhesive in such a way that they can be easily viewed with the aid of a magnifying device.

The absorbent material that contains the mite attractant is positioned in the center of the trap with double sided tape or adhesive on each side of the mite attractant.

The attractant and double sided tape or adhesive are placed between transparent plastic slides and are visible through the trap.

The modular pest trap assembly of the present application includes a modular relatively planar structure that is configured to be adaptable for different methods and areas of a structure for the capture of pests. The assembly includes a modular structure having a main body with a first face and a second face. The modular structure also includes a corner and a plurality of sides. An adhesive layer extends across a portion of the second face of the modular structure. A detachable film cover lays across the adhesive layer to permit handling without contact of the adhesive layer. Additionally, an attachment member is selectively located adjacent to at least one of the plurality of sides of the modular structure for the purpose of securing the modular structure to a corner structure. Flaps extend inward into the corner structure to extend available adhesive internally to the total void space.

An insect trap may include a first housing; a reservoir at least partially defined by the first housing; a protrusion disposed within the reservoir and extending inward from an interior surface of the first housing, the protrusion configured to pierce a package disposed within the reservoir; an actuator connected to the protrusion such that when the actuator is moved, the protrusion moves with the actuator within the reservoir; a second housing moveably engaging the first housing; a trap chamber partially formed by the first and second housings; an inlet into the trap chamber; and wherein the second housing is movable between a first position where the inlet is open and a second position where the inlet is closed. The trap may include a package enclosing an attractant composition. The package has a release rate of the attractant composition from about 5 g per day to about 500 g per day.

A discrete and safe automated insect monitoring system includes a housing, an interior chamber within the housing, and a light source arranged within the housing to illuminate at least a portion of a floor surface of the interior chamber. A multi-pixel optical sensor is arranged within the housing so that a field of view of the sensor comprehends a substantial portion of the floor surface. A processing circuit arranged within the housing receives optical data from the multi-pixel optical sensor, analyzes the optical data to detect the intrusion of an insect or other object into the interior chamber by comparing most recently received optical data to previously received optical data, and generates an indication in response to detecting the intrusion of an insect or other object. Detection and/or classification results can be wirelessly forwarded to another device, to alert appropriate personnel.

A digitally controlled, wearable or stationary chemical dispersal device using a pump and activity-based or environmental-based feedback monitoring is described. The system contains a liquid chemical reservoir which can be replaced or refilled for multi-use operation. Electronic controls are used to drive the pump's liquid or air flow rate periodically with user control features and/or monitored, embedded digital sensors. Feedback from the sensors monitoring either the activity of a wearer of the device or the local environment can be used to adjust the pump's flow rate automatically. In addition, user selectable operation mode via Bluetooth is also described.

A bedbug trap that has a series of stacked containers. The top container holds a quantity of water, sugar and yeast, which generates carbon dioxide. The central container holds a small heating pad to attract the bedbugs and to heat the water and yeast mixture to aid in the fermentation. A hose with a water trap system brings the generated carbon dioxide from the upper chamber to the bottom chamber. This chamber sits in a bowl that has a rough exterior and a smooth interior. Holes, formed around the base of the bottom chamber allow the carbon dioxide to escape into the room, which attracts the bedbugs. The assembled unit is large, to trap as many bedbugs as possible in the shortest amount of time. Finally, the water, sugar and yeast are common household items that are easily and cheaply replenished as needed.