Abstract: A simulation method and system based on a distributive processing model is used for training and educating healthcare teams. The system allows team members to be at the training facility or located remotely and connected via data communication links. The system allows multiple participants for individual team member roles at various connected simulation workstations. If simulation participants cannot man all the team roles, the system can provide virtual team members in their stead. The simulation server computer delivers to each workstation the particular programs and outputs required for any given simulation exercise.

Abstract: A simulation method and system based on a distributive processing model is used for training and educating healthcare teams. The system allows team members to be at the training facility or located remotely and connected via data communication links. The system allows multiple participants for individual team member roles at various connected simulation workstations. If simulation participants cannot man all the team roles, the system can provide virtual team members in their stead. The simulation server computer delivers to each workstation the particular programs and outputs required for any given simulation exercise.

Abstract: A simulation method and system based on a distributive processing model is used for training and educating healthcare teams. The system allows team members to be at the training facility or located remotely and connected via data communication links. The system allows multiple participants for individual team member roles at various connected simulation workstations. If simulation participants cannot man all the team roles, the system can provide virtual team members in their stead. The simulation server computer delivers to each workstation the particular programs and outputs required for any given simulation exercise.

Abstract: A simulation method and system based on a distributive processing model is used for training and educating healthcare teams. The system allows team members to be at the training facility or located remotely and connected via data communication links. The system allows multiple participants for individual team member roles at various connected simulation workstations. If simulation participants cannot man all the team roles, the system can provide virtual team members in their stead. The simulation server computer delivers to each workstation the particular programs and outputs required for any given simulation exercise.

Abstract: A system for producing highly realistic, real-time simulated operating conditions for interactive training of persons to perform minimally invasive surgical procedures involving implements that are inserted and manipulated through small incisions in the patient. The virtual environment for this training system includes a housing with a small opening. An implement simulating a surgical implement is inserted into the opening and manipulated relative to the housing. A movement guide and sensor assembly monitors the location of the implement relative to the housing and provides data about the implement's location and orientation within the housing. The reported data is interpolated by a computer processor, which utilizes a database of information representing a patient's internal landscape to create a computer model of the internal landscape of the patient. With reference to this computer model, the processor controls the occurrence of force feedback opposing the motion of the implement.

Abstract: A system for producing highly realistic, real-time simulated operating condition for interactive training of persons to perform minimally invasive surgical procedures involving implements that are inserted and manipulated through small incisions in the patient. The virtual environment for this training system includes a housing with small opening. An implement simulating a surgical implement is inserted into the opening and manipulated relative to the housing. A movement guide and sensor assembly monitors the location of the implement relative to the housing and provides data about the implement's location and orientation within the housing. The reported data is interpolated by a computer processor, which utilizes a database of information representing a patient's internal landscape to create a computer model of the internal landscape of the patient. With reference to this computer model, the processor controls the occurrence of force feedback opposing the motion of the implement.

Abstract: A system for producing highly realistic, real-time simulated operating conditions for interactive training of persons to perform minimally invasive surgical procedures involving implements that are inserted and manipulated through small incisions in the patient. The virtual environment for this training system includes a housing with a small opening. An implement simulating a surgical implement is inserted into the opening and manipulated relative to the housing. A movement guide and sensor assembly monitors the location of the implement relative to the housing and provides data about the implement's location and orientation within the housing. The reported data is interpolated by a computer processor, which utilizes a database of information representing a patient's internal landscape to create a computer model of the internal landscape of the patient. With reference to this computer model, the processor controls the occurrence of force feedback opposing the motion of the implement.

Abstract: A system for producing highly realistic, real-time simulated operating conditions for interactive training of persons to perform minimally invasive surgical procedures involving implements that are inserted and manipulated through small incisions in the patient. The virtual environment for this training system includes a housing with a small opening. An implement simulating a surgical implement is inserted into the opening and manipulated relative to the housing. A movement guide and sensor assembly monitors the location of the implement relative to the housing and provides data about the implement's location and orientation within the housing. The reported data is interpolated by a computer processor, which utilizes a database of information representing a patient's internal landscape to create a computer model of the internal landscape of the patient. With reference to this computer model, the processor controls the occurrence of force feedback opposing the motion of the implement.