Compared to the development of single-user virtual reality applications, collaborative multi-user simulation brings about new challenges and technical hurdles:

• Hardware architecture (the set of hardware devices that need to be put in place for the application to work): it involves establishing communication between VR headsets through a server while maintaining a smooth experience. Quality and bandwidth of the internet connection must be ensured if users are connected remotely. For online simulations involving a large number of users simultaneously, the server architecture needs to be adapted (number of simultaneous connections, optimized for parallelization, machine fleet, etc.).
• Software architecture and server load optimization: The networked application requires constant communication between users and the server that processes the data. To achieve this, it is necessary to minimize data transfers to prevent the server from being overloaded with processing tasks and ensure satisfactory response times for users. The increase in the number of participants should not compromise the quality of the experience.
• Maintenance: The multiplication of usage sites and devices (multiple headsets, network connection, one or more servers) inevitably leads to an increased need for hardware maintenance. As a result, it can be useful to implement additional tools to facilitate this maintenance (fleet management tools for headsets and servers, for example).

• Communication for collaboration in VR: Since users can collaborate remotely, it is important to ensure good verbal communication (using integrated voice microphones) as well as non-verbal communication. Other users are represented by an avatar in the simulation, which can be animated using motion capture technology. This allows for more natural and fluid movements from the users. In addition to the head and hand position (captured through the headset and controllers), some devices also enable the capture of the user’s facial expressions.
• Performance is crucial to ensure the simultaneity of operations, as maintaining low latency is essential to avoid desynchronization and maintain the consistency of actions. For instance, when a user interacts with an object, it should move/react in the same way in the environments of other users. Given that each user can interact with objects, if two users perform the same action simultaneously, the server must assign priorities to determine which interaction to allow.

Low latency is also important for user comfort. In case of desynchronization between the server and a user, the user may experience a “rubber-banding” effect when resynchronizing, which can be uncomfortable. In virtual reality, this “rubber-banding” effect can cause a loss of spatial awareness and contribute to cyber sickness, a discomfort similar to motion sickness experienced in virtual environments.

• Access to relevant information streams by the instructor: a large amount of information is transmitted through the server. The instructor should be able to access real-time filtered, useful, and relevant information for their pedagogical activities. To ensure effective training monitoring, it is necessary to track the learners’ position in the 3D space as well as their progress in the training scenario.
• Accessibility for users: Since virtual reality is not yet widely used by the general public, this type of application is sometimes the first VR experience for a learner. Therefore, a user may require assistance from the instructor. For example, users may need assistance with hardware setup (properly fitting the headset, configuring the environment, etc.) or with simulation controls (how to move, interact with objects, etc.).

Finally, everyone will recognize that a pleasant learning environment or learning material helps reduce stress and anxiety when faced with a “mountain” of information. Learners naturally feel more comfortable in a calming and aesthetically pleasing environment.

Beauty is, of course, a subjective notion, and what is considered beautiful can vary from person to person. However, in general, the integration of aesthetic and appealing elements in learning promotes engagement, motivation, and the success of learners.

At Audace, we believe that beauty is the minimum we owe to the learner. To achieve this, Audace puts its talents at the service of your talents. Each project receives dedicated attention: an Art Director is assigned to the design of your solution’s interface. According to your preferences, the interface design is aligned with your brand’s graphic charter, your academy’s style, or tailored to fit the storytelling of the learning experience. Our 2D or 3D digital artists then enhance your content, bringing it to life and adding visual richness to support your message. Trained in the top schools such as Rubika and Pôle 3D, our digital artists bring that extra touch of soul to your training programs, making a difference in the overall experience.

Deambulation – Virtuix omni one

The ORANO Group has been collaborating with the AUDACE teams for 12 years, resulting in the production of more than fifty projects in the nuclear field. Recently, AUDACE has developed a simulator called “JUMPER.” This device offers an intervention experience in the heart of a highly radioactive confined space.

The learner practices “jumping,” intervening, and exiting a steam generator to replace a “vital” component, the tape. They must perform their work according to the expected standard while minimizing their exposure to radiation as much as possible. Very anxiety-inducing, the virtual reality simulation recreates both the feeling of claustrophobia, the manipulation with limited light, and the imperative of speed of execution that the collaborator must demonstrate.

Risky work situations can be divided into two distinct categories:

• The first category consists of production situations during which employees may be exposed to hazards related to the environment (equipment, energy flows, machinery, etc.). These are fortuitous cases that are typically protected against by work organization and personal protective equipment.
• The second category consists of operators performing interventions that clearly pose a identified danger to their health. It involves individually and voluntarily exposing oneself in a measured manner to a danger for the sake of collective safety gain. For example, by exposing oneself to the dangers of fire in order to save installations or individuals.

For both categories, simulation will allow the recreation of conditions exposing individuals to risks. The learner will then be able to confront situations that require their vigilance, reasoning, compliance, as well as common sense.

For simulations of interventions in hostile environments (virology, chemistry, radioactivity, etc.), the benefits of simulation are evident. It should be noted that training in hazardous environments is the only true tool for evaluating the operational skills of an operator.

AUDACE has developed numerous simulators for confronting known or unknown risks. Fire extinguishing simulator in virtual reality, industrial risk discovery school in augmented reality, simulation of intervention in a radioactive environment…

ORANO GROUP CASE

The ORANO Group has been collaborating with the AUDACE teams for 12 years, resulting in the production of over fifty projects in the nuclear field. Recently, AUDACE has developed a simulator called “JUMPER.” This device offers an intervention experience in the heart of a highly radioactive confined space.

The learner practices “jumping,” intervening, and exiting a steam generator to replace a “vital” component called the “tape.” The learner must perform their work according to the expected standard while minimizing their exposure to radiation. Very anxiety-inducing, the virtual reality simulation recreates both the feeling of claustrophobia, the manipulation with limited light, and the imperative of execution speed that the collaborator must demonstrate.