Abstract: A system may include a trap and a consumable. The trap may include a data capture mechanism configured to capture data and send the data to a system operator. The consumable may include a device having an associated electronic identification code. A status-determining mechanism may be configured to determine a status of the consumable, which status may be readable via the data capture mechanism. The consumable may include a sensor configured to detect flying insects via mutual capacitance sensing. The sensor may be configured to provide a directional fringe field responsive to a flying insect. The sensor may include a plurality of sensor triplets arranged in a grid array. Each sensor triplet may include a sensor conductor and two electrically conductive un-grounded conductors. The two un-grounded conductors may be disposed one on either side of the sensor conductor to form the sensor triplet.

Abstract: A pest monitoring system may include a sensor and a sensor unit. The sensor may be configured to measure a change in fringe capacitance. The sensor unit may include a housing, at least one microprocessor, a non-volatile memory, a transceiver, a clock, and a connector operatively connected to the sensor. The housing may include a power source. The sensor unit may be programmed to manage power usage.

Abstract: A detection apparatus for identifying the presence of a target warm blooded animal in a detection zone and a method of detecting a warm-blooded animal are disclosed. The detection apparatus utilizes a thermal imaging camera, a sensor, and a microcontroller to capture data on an array and interpret data, and a signaller for sending data indicating the presence of a target animal.

Abstract: A pest monitoring system may include a sensor and a sensor unit. The sensor may be configured to measure a change in fringe capacitance. The sensor unit may include a housing, at least one microprocessor, a non-volatile memory, a transceiver, a clock, and a connector operatively connected to the sensor. The housing may include a power source. The sensor unit may be programmed to manage power usage.

Abstract: A sensor unit may include a sensor, a housing, at least one microprocessor, a non-volatile memory, a transceiver, a clock, and a connector. The sensor may be configured to measure a change in fringe capacitance and may be tuned to at least one of detect and identify a given animal. The housing may include a power source. The connector may operatively connect the sensor to the housing. The at least one microprocessor may be programmed to continuously recalibrate a baseline capacitance.

Abstract: An insect catching device may include at least two insect capture surfaces, a first surface including a first color, and a second surface including a second, lighter color relative to the first color of the first surface. The second color of the second surface may highlight the presence of insects captured thereon facilitating at least one of ease of counting and ease of identification of captured insects. The insect catching device may also include a line of weakening disposed between the first surface and the second surface. The line of weakening may include at least one perforation. The second surface may be detachable from the first surface along the line of weakening. The first color may be configured to decrease visibility of captured insects on the first surface observable by a viewer through an insect trap cover.

Abstract: A trap for catching or killing insects includes a back housing, an insect capture or killing mechanism, an insect attracting light source comprising light emitting diodes (LEDs) which emit ultra violet (UV) radiation through a lens, and a cover comprising one or more openings allowing insects to enter the trap, through which insect attracting light is dispersed, or a fascia and one or more independent openings allowing insects to enter the trap, through which insect attracting light is dispersed.

Abstract: The present invention relates to an ovitrap (10) and novel method of controlling mosquito populations comprising the use of light (20) to create a photo stimulus, causing mosquito larvae (102) to move from a location (Va), where gravid mosquitoes have deposited their eggs, in a direction away from the light, to a location (Vb). where they are trapped and killed. The ovitrap utilises this behaviour to more effectively capture and kill larvae. The ovitrap comprises a container (12), a cover (14), and a means (16) for dividing the container (12) into two regions (101; 102), which in use are filled with water, and which communicate via an opening (26) such that a volume (Vb) below the means (16) defines a larvae (102) trapping region, and a volume (Va) above the means (16) defines an egg (101) receiving region.

Abstract: A system may include a trap and a consumable. The trap may include a data capture mechanism configured to capture data and send the data to a system operator. The consumable may include a device having an associated electronic identification code. A status-determining mechanism may be configured to determine a status of the consumable, which status may be readable via the data capture mechanism. The consumable may include a sensor configured to detect flying insects via mutual capacitance sensing. The sensor may be configured to provide a directional fringe field responsive to a flying insect. The sensor may include a plurality of sensor triplets arranged in a grid array. Each sensor triplet may include a sensor conductor and two electrically conductive un-grounded conductors. The two un-grounded conductors may be disposed one on either side of the sensor conductor to form the sensor triplet.

Abstract: A sensor unit may include a sensor, a housing, at least one microprocessor, a non-volatile memory, a transceiver, a clock, and a connector. The sensor may be configured to measure a change in fringe capacitance and may be tuned to at least one of detect and identify a given animal. The housing may include a power source. The connector may operatively connect the sensor to the housing. The at least one microprocessor may be programmed to continuously recalibrate a baseline capacitance.

Abstract: The present disclosure relates to an ovitrap and a method of controlling mosquito populations. The ovitrap includes a container, a cover, and a dividing mechanism for dividing the container into two regions, which in use are filled with water, and which communicate via an opening such that a first volume below the dividing mechanism defines a larvae trapping region, and a second volume above the dividing mechanism defines an egg receiving region A light source having a cool, white spectra with two peaks is mounted above the container and positioned to direct light downwards at a water surface, such that the larvae move in a direction away from the light source, from the second volume into the first volume below the dividing mechanism via the opening. A gating mechanism is operatively linked to the light source for opening and closing the opening.

Abstract: An insect catching device may include at least two insect capture surfaces, a first surface including a first color, and a second surface including a second, lighter color relative to the first color of the first surface. The second color of the second surface may highlight the presence of insects captured thereon facilitating at least one of ease of counting and ease of identification of captured insects. The insect catching device may also include a line of weakening disposed between the first surface and the second surface. The line of weakening may include at least one perforation. The second surface may be detachable from the first surface along the line of weakening. The first color may be configured to decrease visibility of captured insects on the first surface observable by a viewer through an insect trap cover.

Abstract: The invention relates to an insect trap (10) and more particularly to an insect trap which has been designed to facilitate simple and efficient servicing, maintenance and cleaning. In a first aspect the trap comprises a. a back housing (12); b. a frame (14) swing mounted to said housing; and c. a cover (16) comprising openings (18) allowing insects to enter the trap and the frame supports one or a plurality of lights (22) such that said frame and lights can be moved from a first position where they overlie the back housing, to a second position where they lie clear of the back housing such that an insect catching means (100) which may be fitted over the back housing is readily accessible for replacement during servicing. In another aspect the trap comprises a. a back housing (12); b. a plurality of lights (22); and c.

Abstract: The invention relates to an insect trap (10) and more particularly to an insect trap which has been designed to facilitate simple and efficient servicing, maintenance and cleaning. In a first aspect the trap comprises a. a back housing (12); b. a frame (14) swing mounted to said housing; and c. a cover (16) comprising openings (18) allowing insects to enter the trap and the frame supports one or a plurality of lights (22) such that said frame and lights can be moved from a first position where they overlie the back housing, to a second position where they lie clear of the back housing such that an insect catching means (100) which may be fitted over the back housing is readily accessible for replacement during servicing. In another aspect the trap comprises a. a back housing (12); b. a plurality of lights (22); and c.

Abstract: A trap for catching insects may include a back housing, a plurality of lights and a cover. The trap may be adapted for ease of servicing and jet cleaning via a plurality of shields. Each of the plurality of shields may sealably protect, from water ingress, the plurality of lights at a position where the plurality of lights connect to a plurality of electrical fittings.

Abstract: A trap for catching insects may include a back housing, a plurality of lights and a cover. The trap may be adapted for ease of servicing and jet cleaning via a plurality of shields. Each of the plurality of shields may sealably protect, from water ingress, the plurality of lights at a position where the plurality of lights connect to a plurality of electrical fittings.

Abstract: The invention relates to an insect trap (10) and more particularly to an insect trap which has been designed to facilitate the destruction of micro-organisms thereby countering odours and mitigating against the spread of germs. The trap (10) comprises a. a housing (12); b. a cover (14); c. one or a plurality of insect attracting lights (16); and d. an insect catching means (18) and further comprises a UVC lamp which emits radiation (or other means) which is capable of destroying air-borne pathogens. The insect attractant lamps (16) heat the air which is convected as a consequence of louvered openings (26) in the cover and an opening (30) in the top (28) of the trap and circulate across the UVC lamp where the micro-organisms are killed.