Abstract: A reader device for detecting a test result from a testing element carrying a sample includes a radiation source for emitting electromagnetic radiation, an optical system for directing the electromagnetic radiation to the testing element, and a detector for receiving electromagnetic radiation from the testing element and for producing a detection signal responsive to the received electromagnetic radiation. The optical system includes a guide rod for conducting electromagnetic radiation and a lens system for focusing the electromagnetic radiation coming out via an egress-end surface of the guide rod to the testing element. The egress end-surface of the guide rod has an elongated shape so that a radiation pattern having an elongated shape is produced on the testing element. The elongated shape of the radiation pattern facilitates scanning the testing element with the electromagnetic radiation.

Abstract: A reader device for detecting a test result from a testing element carrying a sample includes a radiation source for emitting electromagnetic radiation, an optical system for directing the electromagnetic radiation to the testing element, and a detector for receiving electromagnetic radiation from the testing element and for producing a detection signal responsive to the received electromagnetic radiation. The optical system includes a guide rod for conducting electromagnetic radiation and a lens system for focusing the electromagnetic radiation coming out via an egress-end surface of the guide rod to the testing element. The egress end-surface of the guide rod has an elongated shape so that a radiation pattern having an elongated shape is produced on the testing element. The elongated shape of the radiation pattern facilitates scanning the testing element with the electromagnetic radiation.

Abstract: An apparatus for measuring an optical component (160, 170, 190) of the apparatus, the apparatus comprising a radiation source (130) configured to form a measuring beam in a measuring channel (140), wherein the measured optical component configured to be in a first position outside the measuring channel and in a second position in the measuring channel; a first detector (110) configured to receive beams in the measuring channel; a second detector (150) configured to receive beams in the measuring channel; at least one processor; and at least one memory including computer program code.

Abstract: An apparatus for optically measuring samples, including a radiation source configured to form an excitation beam in an excitation channel, a detector configured to detect an emission beam in an emission channel and a filter configured to be located, in an excitation position, in the excitation channel, and in an emission position, in the emission channel. The apparatus further includes a first filter storage comprising a first set of filter storage positions, a second filter storage comprising a second set of filter storage positions, and a filter transfer mechanism configured to move the filter between the excitation position, the emission position, the first set of filter storage positions and the second set of filter storage positions.

Abstract: An apparatus for measuring an optical component (160, 170, 190) of the apparatus, the apparatus comprising a radiation source (130) configured to form a measuring beam in a measuring channel (140), wherein the measured optical component configured to be in a first position outside the measuring channel and in a second position in the measuring channel; a first detector (110) configured to receive beams in the measuring channel; a second detector (150) configured to receive beams in the measuring channel; at least one processor; and at least one memory including computer program code.

Abstract: A lens and reflector unit for optical measurements includes first and second convex surface sections of the lens and reflector unit. Both have their respective central normal lines. A first flat surface section has a normal direction that divides the angle between the central normal lines into equal halves. A third convex surface section has a third central normal line, and the fourth convex surface section has a fourth central normal line. A second flat surface section has a normal direction that divides the angle between the third and fourth central normal lines into to equal halves.

Abstract: An apparatus for optically measuring samples, including a radiation source configured to form an excitation beam in an excitation channel, a detector configured to detect an emission beam in an emission channel and a filter configured to be located, in an excitation position, in the excitation channel, and in an emission position, in the emission channel. The apparatus further includes a first filter storage comprising a first set of filter storage positions, a second filter storage comprising a second set of filter storage positions, and a filter transfer mechanism configured to move the filter between the excitation position, the emission position, the first set of filter storage positions and the second set of filter storage positions.

Abstract: A lens and reflector unit for optical measurements includes first and second convex surface sections of the lens and reflector unit. Both have their respective central normal lines. A first flat surface section has a normal direction that divides the angle between the central normal lines into equal halves. A third convex surface section has a third central normal line, and the fourth convex surface section has a fourth central normal line. A second flat surface section has a normal direction that divides the angle between the third and fourth central normal lines into to equal halves.

Abstract: The invention concerns a measurement system and method for optical spectroscopic measurement of samples. The system comprises an illumination source for forming a primary light beam, a first tunable monochromator for spectrally filtering the primary light beam, a sample-receiving zone to which the spectrally filtered primary beam is directed for producing a secondary light beam affected by a sample in the sample receiving zone, and a second tunable monochromator for spectrally filtering the secondary light beam, and a detector for measuring the intensity of the spectrally filtered secondary beam. In particular, the system is adapted to scan a predefined wavelength range using one of the monochromators and to tune the other monochromator sequentially to one of at least two predefined separate wavelengths in order to eliminate the effect of undesired diffraction orders of the second monochromator on the measurement.

Abstract: The present technology relates generally to fibre optic cables their manufacture and uses in the field of optical measurements including biochemical laboratory instrumentation for measuring properties of samples on microtitration plates and corresponding sample supports. The technology has also applications in various laser technologies. A fibre optic cable has an active surface with a determined form provided at a first optical interface at the first end of the cable. The first end of the cable is fused into an exemplary circular form, the fused cable end including fibre ends both within the active surface and outside the active surface. At the opposite, second end of the cable, those fibres which have their first ends at the determined active surface area, are used for forming a second optical interface. It is possible to have high transmission efficiency in optical interfaces where other than circular cross section of the light beam exists.

Abstract: The present technology relates generally to fibre optic cables their manufacture and uses. The technology has useful applications e.g. in the field of optical measurements such as biochemical laboratory instrumentation for measuring properties of samples on microtitration plates and corresponding sample supports. The technology has also applications in various laser technologies. The object of the technology is achieved by providing a fibre optic cable wherein an active surface with a determined form is provided at a first optical interface at the first end (451a, 451b) of the cable. The first end of the cable is fused into an exemplary circular form, the fused cable end including fibre ends both within the active surface and outside the active surface. At the opposite, second end of the cable, those fibres which have their first ends at the determined active surface area, are used for forming a second optical interface (452a, 452b).

Abstract: An optical method for measuring a liquid sample (24) placed in a sample well (21), in which method the liquid sample (24) is exposed to excitation light (32) obtained from an excitation light source (30) from below the sample well through a transparent bottom (23). The excitation light is directed towards the sample well preferably as a conical light beam, which in the area of the sample well has a width mainly corresponding to the width of the sample well. The distance of the excitation light source from the bottom of the sample well is adjusted so that the excitation light beam is the size of the transparent bottom of the sample well. In an optical measuring device (10), an emission light shutter (50) is provided between the sample well and an emission light detector (12), and the shutter plate (51) has a glossy surface on the side facing towards the sample well. The measuring device may comprise a plurality of detectors placed side by side for simultaneous measurement of a plurality of sample wells.