Abstract: Systems and methods are described that generate a first virtual space corresponding to a first multi-dimensional image set, where the first multi-dimensional image set includes one or more images generated based on receiving first imaging signals. The systems and method store pose information of one or more markers in association with a second virtual space, where the second virtual space corresponds to a second multi-dimensional image set including one or more ultrasound images generated based on receiving second imaging signals. The systems and method generate an image-based surgical plan in association with the first virtual space based on the pose information of the one or more markers. In some cases, the systems and method translate the pose information of the one or more markers to the first virtual space, and generating the image-based surgical plan is based on the translation of the pose information to the first virtual space.

Abstract: The personalisation machine for smart cards (5) comprises an administration computer system (1) connected via at least one data personalisation transmission element (2, 200) to a turning device (3) equipped with routing means of personalisation data to locations (32) of a plurality of card locations (5). Said transmission element (2, 200) is of wired type and has a maximal data transmission capacity greater than 100 MBps (megabytes per second). To ensure a substantial processing rate with a compact machine, it is provided with:—means (4) for driving in rotation of bi-directional type for turning the device (3) around an axis (23) of rotation, said system (1) remaining fixed;—a control module (40) regularly inverting the direction of rotation of the turning device. Stops are provided for preventing rotation of the device (3) beyond one turn.

Abstract: The personalisation machine for smart cards (5) comprises an administration computer system (1) connected via at least one data personalisation transmission element (2, 200) to a turning device (3) equipped with routing means of personalisation data to locations (32) of a plurality of card locations (5). Said transmission element (2, 200) is of wired type and has a maximal data transmission capacity greater than 100 MBps (megabytes per second). To ensure a substantial processing rate with a compact machine, it is provided with:—means (4) for driving in rotation of bi-directional type for turning the device (3) around an axis (23) of rotation, said system (1) remaining fixed;—a control module (40) regularly inverting the direction of rotation of the turning device. Stops are provided for preventing rotation of the device (3) beyond one turn.

Abstract: A machine for the personalising of chip cards (5) that includes a computer control system (1) fitted with first communication means (21) to send personalising data, at least one rotating device (3) with portable object (5) slots (32), and means for routing the personalising data to the slots (32). Each of the slots is equipped with means to communicate with an electronic chip on one of the portable objects. A rotating connection element (6) is used exclusively for the electrical powering of the rotating device (3), while second communication means (22) fitted in the device (3) remotely receive the personalising data transmitted by the system (1) via the first means (21) The transmission of data is therefore accomplished wirelessly with a. bit-rate that can exceed 1 Gbit/s, which renders the processing rate very high in a machine with a rotating device.

Abstract: The present invention relates to a digital device for printing on “open” or “closed” surface substrates by demand bubble-jet comprising at least one built-in ink reservoir (13) with a system of anti-splash partitions, at least one printhead and one buffer reservoir, the whole located in a print module (1) which moves in relation to the substrate (5). The device comprises a means for creating, during operation of the module, on the one hand, a vacuum in the built-in reservoir, with a method of active regulation of this vacuum by adjustment of the ink level detected by a sensor attached to the built-in reservoir and, on the other hand, the air pressure in the built-in reservoir required for printhead cleaning phases.

Abstract: The present invention relates to a digital device for printing on “open” or “closed” surface substrates by demand bubble-jet comprising at least one built-in ink reservoir (13) with a system of anti-splash partitions, at least one printhead and one buffer reservoir, the whole located in a print module (1) which moves in relation to the substrate (5), characterized in that it The device comprises a means for creating, during operation of the module, on the one hands a vacuum in the built-in reservoir, with a method of active regulation of this vacuum by adjustment of the ink level detected by a sensor attached to the built-in reservoir and on the other hand, the air pressure in the built-in reservoir.