Provided is a simulation device for a simulation of a cooperative task carried out cooperatively by a cooperative robot and a person, and the simulation device includes a head mounting-type display device to be mounted on an operator to simulatively carry out the cooperative task, a detecting section configured to detect a position of the operator in a real space, a three-dimensional model display section configured to cause an image in which a robot system model including a cooperative robot model is arranged in a three-dimensional virtual space to be displayed on the head mounting-type display device, and a simulation execution section configured to simulatively operate the cooperative robot model in the three-dimensional virtual space based on an operation program of the cooperative robot to carry out the cooperative task and the detected position of the operator.

In this patent, an advanced head display unit designed primarily for fire fighters is disclosed. The advanced augmented reality/virtual reality (AR/VR) head display unit improves coordination between teammates through eye tracking coupled with augmented reality features. This allows one fire fighter to know where another fire fighter is looking and helps coordinate tasks by dividing the scene into sectors and visibly marking each sector. Further, this system helps determine where to hose with a smart target system. Further, multiple sensors are utilized together to triangulate the location of a victim's voice. Additional advantages are also disclosed above.

An automatic fog identification method using a front camera image and a emergency fog red LED high beam system using the same are proposed. The emergency fog red LED high beam system is configured such that a red LED module is applied to a high beam light source, thus providing a clear and wide view for a driver without diffused reflection even in a foggy situation.

Provided are a boundary display control device, a boundary display control method, and a program which can reduce an oppressive feeling of a user when a virtual object representing a boundary surface dividing a region in a real space in which the user is permitted to exist from a region in the real space in which the user is not permitted to exist is displayed. A program executing section (84) locates a position of the user wearing a head-mounted display. An approach portion identifying section (86) identifies, as an approach portion, a part of a boundary surface dividing a permitted region that is the region in the real space in which the user is permitted to exist from an unpermitted region that is the region in the real space in which the user is not permitted to exist, on the basis of the located position of the user. A display control section (92) causes the head-mounted display to display a virtual object representing the identified approach portion.

Sensory feedback (“chaperoning”) systems and methods for guiding users in virtual/augmented reality environments such as walk-around virtual reality environments are described. Exemplary implementations assist with preventing collisions with objects in the physical operating space in which the user acts, among other potential functions and/or uses.

An example device includes a monitoring engine. The monitoring engine is to measure a characteristic of a wireless signal related to a path of the wireless signal. The wireless signal includes data from a remote source. The device includes an analysis engine to determine that an object is within a proximity threshold of a user based on the characteristic of the wireless signal. The device includes an indication engine to indicate to the user that the object is within the proximity threshold of the user.

A virtual image display device includes a virtual image position selector, a vision measurement interface, a display information acquirer, a display image generator, and a projection processor. The virtual image position selector selects either a first virtual image position or a second virtual image position as a display position of the virtual image. The vision measurement interface measures a vision of a user based on a user's response to a vision measurement image projected as a virtual image at the display position. The display information acquirer acquires information to be shown. The display image generator generates a display image showing an image corresponding to the information acquired by the display information acquirer in a size determined by the vision acquired by the vision measurement interface. The projection processor performs a projection process of projecting the display image generated by the display image generator as a virtual image.

A projection display device includes an image display control unit configured to perform a first display control for generating image data in accordance with information received from a control unit that controls the vehicle, and a second display control for generating image data in accordance with the measurement information acquired from the information measuring device without passing through the control unit, and a warning determination unit, wherein the image display control unit performs the second display control when the warning determination unit determines that the warning is necessary, and performs the first display control when the warning determination unit determines that the warning is not necessary, in a first mode in which driving of the vehicle is performed in accordance with an internally generated instruction or an instruction externally and wirelessly received, the image display control unit performs at least the second display control without passing through the control unit.

A head-mounted display, a display control method, and a program that facilitate a user to understand proximity between the user and an object around the user are provided. A display block (36) is arranged in front of the eyes of the user wearing a HMD (12). In accordance with proximity between the user and an object around the user, the HMD (12) controls the display block (36) so as to have the user visually recognize a forward direction of the display block (36).

An augmented reality system for providing depth perspective includes a sensor system that provides spatial data of objects in a surrounding environment of a user. A computer processor system calculates spatial information of the objects from the spatial data received the sensor system. The computer processor system determines a depth-to-color mapping in which distance of objects from the user is mapped to a predetermined viewable representation. The system also includes a head mountable display that displays the depth-to-color mapping to the user. Characteristically, distances of the objects from the user are rendered to allow at least partial viewability of the object by the user. A method utilizing the augmented reality system is also provided.