Abstract: An optical probe includes a first region and a second region connected to have a continuous optical waveguide in which a transmission mode is a single mode. The first region connected to a tip-end surface opposed to an optical device includes a region in which a mode field diameter that is maximum at the tip-end surface is gradually decreased toward a boundary between the first region and the second region. The tip-end surface is a curved surface and has a radius of curvature set so that an advancing direction of an optical signal entering through the tip-end surface approximates in parallel to a central-axis direction of the optical waveguide.

Abstract: A measurement method of receiving an emission light output from an optical semiconductor element on an incident end surface of an optical probe, shifts a relative position between the optical semiconductor element and the optical probe on a plane surface intersecting with an optical axis of the emission light, measures an incident intensity of the emission light at several positions, and obtains an incident intensity pattern showing a relationship between a change in the relative position and the respective incident intensities.

Abstract: It is possible to make the free length of a contactor uniform even when the contactor is joined to a position that deviates from a joint position in a high-frequency conducting path and make contact with an electrode with stability, which improves measurement quality. A probe unit according to the present disclosure includes: a coaxial connector that is attached to a main body and gives and receives an electrical signal to and from a tester via a coaxial cable; a high-frequency conducting path that is connected to the coaxial connector and transmits an electrical signal; a plurality of contactors, each having a tip portion that makes electrical contact with an electrode of an object to be inspected and giving and receiving an electrical signal to and from the high-frequency conducting path; and a pedestal that is interposed between the contactor and the high-frequency conducting path, and the pedestal is provided in each contactor such that a free length of the contactor is a predetermined length.

Abstract: An optical probe receives an optical signal output from a test subject. The optical probe includes an optical waveguide composed of a core portion and a cladding portion disposed on an outer periphery of the core portion, wherein an incident surface of the optical waveguide, which receives the optical signal, is a convex spherical surface with a constant curvature radius.

Abstract: An optical probe includes a core part and a clad part arranged along an outer circumference of the core part, and has an incident surface having a radius of curvature R through which an optical signal enters. The radius of curvature R and a central half angle ? at an incident point of the optical signal on the incident surface fulfil the following formulae using a radiation angle ? of the optical signal, an effective incident radius Se of the optical signal transmitted in the core part without penetrating into the clad part on the incident surface, a refractive index n(r) of the core part at the incident point, and a refracting angle ? at the incident point: R=Se/sin(?) ?=±sin?1{[K22/(K12+K22)]1/2} where K1=n(r)×cos(?)?cos(?/2) and K2=n(r)×sin(?)?sin(?/2).

Abstract: It is possible to make the free length of a contactor uniform even when the contactor is joined to a position that deviates from a joint position in a high-frequency conducting path and make contact with an electrode with stability, which improves measurement quality. A probe unit according to the present disclosure includes: a coaxial connector that is attached to a main body and gives and receives an electrical signal to and from a tester via a coaxial cable; a high-frequency conducting path that is connected to the coaxial connector and transmits an electrical signal; a plurality of contactors, each having a tip portion that makes electrical contact with an electrode of an object to be inspected and giving and receiving an electrical signal to and from the high-frequency conducting path; and a pedestal that is interposed between the contactor and the high-frequency conducting path, and the pedestal is provided in each contactor such that a free length of the contactor is a predetermined length.

Abstract: A measurement method of receiving an emission light output from an optical semiconductor element on an incident end surface of an optical probe, shifts a relative position between the optical semiconductor element and the optical probe on a plane surface intersecting with an optical axis of the emission light, measures an incident intensity of the emission light at several positions, and obtains an incident intensity pattern showing a relationship between a change in the relative position and the respective incident intensities.

Abstract: An optical probe includes a first region and a second region connected to have a continuous optical waveguide in which a transmission mode is a single mode. The first region connected to a tip-end surface opposed to an optical device includes a region in which a mode field diameter that is maximum at the tip-end surface is gradually decreased toward a boundary between the first region and the second region. The tip-end surface is a curved surface and has a radius of curvature set so that an advancing direction of an optical signal entering through the tip-end surface approximates in parallel to a central-axis direction of the optical waveguide.

Abstract: A measurement system includes an optical probe array including the m-number of optical probe groups arranged, each including the n-number of optical probes, the m-number of optical signal selectors each corresponding one of the optical probe groups, and a control circuit configured to control the optical signal selectors. The respective optical signal selectors select and output one of optical signals output from the n-number of the optical probes of the corresponding optical probe groups. The measurement system causes the control circuit to control the optical signal selectors to repeat the selection of the optical signals until the optical signals output from all of the optical probes included in the respective optical probe groups are selected.

Abstract: An optical probe receives an optical signal output from a test subject. The optical probe includes an optical waveguide composed of a core portion and a cladding portion disposed on an outer periphery of the core portion, wherein an incident surface of the optical waveguide, which receives the optical signal, is a convex spherical surface with a constant curvature radius.