Abstract: A method for producing a waveguide device, including producing a core of a non-conductive material. The core has side walls with outer surfaces and inner surfaces, the inner surfaces defining a waveguide channel. A layer of conductive metal is deposited on the inner surfaces by immersion in a fluid of reactants. The core includes at least one hole between the outer and inner surfaces, specifically used to encourage the removal of bubbles from the channel and/or the circulation of the fluid during the immersion.

Abstract: A passive radiofrequency device includes a core formed by the gluing of multiple parts in direct contact against one another. At least one of the parts includes a housing for glue. At least some of the parts are manufactured individually by additive manufacturing. A conductive metal jacket surrounds the core without separating the parts from one another.

Abstract: A waveguide device for guiding a radio frequency signal at a determined frequency f, the device including a body having side walls with outer surfaces and inner surfaces, the inner surfaces defining a waveguide channel. A conductive layer covers the inner surface of the body, the conductive layer being formed of a metal having a skin depth ? at frequency f. The conductive layer has a thickness at least twenty times as large as the skin depth ?.

Abstract: A method for producing a waveguide device, including producing a core of a non-conductive material. The core has side walls with outer surfaces and inner surfaces, the inner surfaces defining a waveguide channel. A layer of conductive metal is deposited on the inner surfaces by immersion in a fluid of reactants. The core includes at least one hole between the outer and inner surfaces, specifically used to encourage the removal of bubbles from the channel and/or the circulation of the fluid during the immersion.

Abstract: A waveguide device for guiding a radio frequency signal at a determined frequency f, the device including a body having side walls with outer surfaces and inner surfaces, the inner surfaces defining a waveguide channel. A conductive layer covers the inner surface of the body, the conductive layer being formed of a metal having a skin depth ? at frequency f. The conductive layer has a thickness at least twenty times as large as the skin depth ?.

Abstract: A passive radiofrequency device includes a core formed by the gluing of multiple parts in direct contact against one another. At least one of the parts includes a housing for glue. At least some of the parts are manufactured individually by additive manufacturing. A conductive metal jacket surrounds the core without separating the parts from one another.

Abstract: A simulation device is disclosed for practicing manipulations of at least one elongated medical instrument, comprising a housing presenting at least one instrument input and enclosing a first motion sensor for tracking the motions of a first elongated medical instrument inserted therein. The housing encloses a bifurcating device having one input connected to the instrument input as well as at least a first and a second outputs. The bifurcating device further comprises a deflecting mechanism for guiding the first and a second elongated medical instruments from its input, respectively, through the first and second outputs, the first output being connected to the first motion sensor while the second output is connected to a second motion sensor for tracking the motions of the second elongated medical instrument. Thus, the operator's feelings are very close from those of a real medical intervention, the respective behaviour of the instruments being substantially identical.

Abstract: The present invention relates to a simulation device (2), for practicing manipulations of at least one elongated medical instrument (101, 102), comprising a housing (11) presenting at least one instrument input (10) and enclosing a first motion sensor (18) for tracking the motions of a first elongated medical instrument (101) inserted therein. The housing encloses a bifurcating device (14, 140) having one input (13, 142) connected to the instrument input as well as at least a first and a second outputs (23, 24), the bifurcating device further comprising a deflecting mechanism (15, 141) for guiding the first and a second elongated medical instruments (101, 102) from its input, respectively, through the first and second outputs, the first output being connected to the first motion sensor while the second output is connected to a second motion sensor for tracking the motions of the second elongated medical instrument.