Abstract: A multi-spot ophthalmic laser device that produces spatially distributed laser spots with the spatial distribution of the laser spots defined by a spot diameter to space ratio in the range 1:2 to 1:20. The multi-spot ophthalmic laser device comprises: a laser module producing a laser pulse or sequence of laser pulses each having: a pulse duration in the range of 10 ps to 20 ?s; a wavelength in the range 500 nm to 900 nm; and a pulse energy in the range 10 ?J to 10 mJ per pulse; and an optical beam profiling module that modifies an output beam profile of each pulse of the laser module to deliver multiple spatially distributed laser spots of defined size and energy. The multi-spot ophthalmic laser device is used in a method of improving the function of the retina of a human eye by irradiation through the cornea of the eye to the retinal pigmented epithelium by a treatment laser having a beam profile with spatially distributed energy peaks.

Abstract: A multi-spot ophthalmic laser device that produces spatially distributed laser spots with the spatial distribution of the laser spots defined by a spot diameter to space ratio in the range 1:2 to 1:20. The multi-spot ophthalmic laser device comprises: a laser module producing a laser pulse or sequence of laser pulses each having: a pulse duration in the range of 10 ps to 20 ?s; a wavelength in the range 500 nm to 900 nm; and a pulse energy in the range 10 ?J to 10 mJ per pulse; and an optical beam profiling module that modifies an output beam profile of each pulse of the laser module to deliver multiple spatially distributed laser spots of defined size and energy. The multi-spot ophthalmic laser device is used in a method of improving the function of the retina of a human eye by irradiation through the cornea of the eye to the retinal pigmented epithelium by a treatment laser having a beam profile with spatially distributed energy peaks.

Abstract: A head-up display unit 10 comprises a microprocessor 30 which controls four light-emitting diodes (LEDs) which constitute the head-up display 20. The microprocessor 30 and LEDs 20 are powered by a battery 40 and a switch 50 is in series with the battery. A temporary store 60 in the form of a capacitor is in parallel with the battery 40 after the switch 50. A data receiver 32 is connected to the microprocessor 30 and communicates received data 34 to the microprocessor 30. The head-up display unit 10 is located in the face-mask 100 of a self contained breathing apparatus unit. The LEDs 20 are located in the periphery of the viewable region of the face-mask 100 so that they can be seen by the user when the face-mask is worn. The switch 50 comprises two conductive rubber strips which conduct current between them when sufficient pressure is applied. The switch 50 is located on a portion of the face-mask seal 102 such that when the face-mask 100 is worn i.e.

Abstract: A compact combination sensor is provided for physiological parameters, which can be worn behind the ear. The combination sensor has a heat flux sensor (1) for detecting two temperatures (Th1, Th2) for determining the body core temperature (Tc), an acoustic sensor (2) for measuring the heart rate (HR) and for detecting speech signals, as well as a measured signal evaluating unit (4, 5, 7). A communications interface (8) is provided for transmitting the processed data from the measured signal evaluating unit (4, 5, 7) to a communications unit (9) are located in the sensor carrier (11).

Abstract: A head-up display unit 10 comprises a microprocessor 30 which controls four light-emitting diodes (LEDs) which constitute the head-up display 20. The microprocessor 30 and LEDs 20 are powered by a battery 40 and a switch 50 is in series with the battery. A temporary store 60 in the form of a capacitor is in parallel with the battery 40 after the switch 50. A data receiver 32 is connected to the microprocessor 30 and communicates received data 34 to the microprocessor 30. The head-up display unit 10 is located in the face-mask 100 of a self contained breathing apparatus unit. The LEDs 20 are located in the periphery of the viewable region of the face-mask 100 so that they can be seen by the user when the face-mask is worn. The switch 50 comprises two conductive rubber strips which conduct current between them when sufficient pressure is applied. The switch 50 is located on a portion of the face-mask seal 102 such that when the face-mask 100 is worn i.e.

Abstract: A compact combination sensor is provided for physiological parameters, which can be worn behind the ear. The combination sensor has a heat flux sensor (1) for detecting two temperatures (Th1, Th2) for determining the body core temperature (Tc), an acoustic sensor (2) for measuring the heart rate (HR) and for detecting speech signals, as well as a measured signal evaluating unit (4, 5, 7). A communications interface (8) is provided for transmitting the processed data from the measured signal evaluating unit (4, 5, 7) to a communications unit (9) are located in the sensor carrier (11).