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Interface Design In an Automobile Glass Cockpit EnvironmentSpendel, Michael, Strömberg, Markus January 2007 (has links)
<p>Today’s automobile cockpit is filled with different buttons and screen-based displays giving input and relaying information in a complex human-machine system. Following in the footsteps of the early 1970s flight industry, this thesis work focused on creating a complete glass cockpit concept in the automobile.</p><p>Our automobile glass cockpit consists of three displays. A touch screen based centre console with an interface that we took part in creating during the spring of 2006. Parallel to this ongoing master thesis, a head-up display was installed by a group of students and we had the opportunity of giving input regarding the design of the graphical interface.</p><p>The third display, a LCD, replaces the main instruments displaying speed, RPM, fuel level, engine temperature etc. Together with ideas on an extended allocation of functions to the area on and around the steering wheel, creating a dynamic mode based interface replacing today’s static main instruments was the focus of this project.</p><p>After conducting a thorough theoretical study, a large number of ideas were put to the test and incorporated in concept sketches. Paper sketches ranging from detailed features to all-embracing concepts combined with interviews and brainstorming sessions converged into a number of computer sketches made in an image processing software. The computer sketches was easily displayed in the cockpit environment and instantly evaluated. Some parts were discarded and some incorporated in new, modified, ideas leading to a final concept solution.</p><p>After the design part was concluded, the new graphical interface was given functionality with the help of a programming software. As was the case with the computer sketches, the functionality of the interface could be quickly evaluated and modified. With the help of a custom-made application our interface could be integrated with the simulator software and fully implemented in the automobile cockpit at the university simulator facilities.</p><p>Using a custom made scenario, the interface underwent a minor, informal evaluation. A number of potential users were invited to the VR-laboratory and introduced to the new concept. After driving a pre-determined route and familiarizing themselves with the interface, their thoughts on screen-based solutions in general and the interface itself was gathered. In addition, we ourselves performed an evaluation of the interface based on the theoretical study.</p>
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Interface Design In an Automobile Glass Cockpit EnvironmentSpendel, Michael, Strömberg, Markus January 2007 (has links)
Today’s automobile cockpit is filled with different buttons and screen-based displays giving input and relaying information in a complex human-machine system. Following in the footsteps of the early 1970s flight industry, this thesis work focused on creating a complete glass cockpit concept in the automobile. Our automobile glass cockpit consists of three displays. A touch screen based centre console with an interface that we took part in creating during the spring of 2006. Parallel to this ongoing master thesis, a head-up display was installed by a group of students and we had the opportunity of giving input regarding the design of the graphical interface. The third display, a LCD, replaces the main instruments displaying speed, RPM, fuel level, engine temperature etc. Together with ideas on an extended allocation of functions to the area on and around the steering wheel, creating a dynamic mode based interface replacing today’s static main instruments was the focus of this project. After conducting a thorough theoretical study, a large number of ideas were put to the test and incorporated in concept sketches. Paper sketches ranging from detailed features to all-embracing concepts combined with interviews and brainstorming sessions converged into a number of computer sketches made in an image processing software. The computer sketches was easily displayed in the cockpit environment and instantly evaluated. Some parts were discarded and some incorporated in new, modified, ideas leading to a final concept solution. After the design part was concluded, the new graphical interface was given functionality with the help of a programming software. As was the case with the computer sketches, the functionality of the interface could be quickly evaluated and modified. With the help of a custom-made application our interface could be integrated with the simulator software and fully implemented in the automobile cockpit at the university simulator facilities. Using a custom made scenario, the interface underwent a minor, informal evaluation. A number of potential users were invited to the VR-laboratory and introduced to the new concept. After driving a pre-determined route and familiarizing themselves with the interface, their thoughts on screen-based solutions in general and the interface itself was gathered. In addition, we ourselves performed an evaluation of the interface based on the theoretical study.
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Simulator-Based Design in PracticeLopez, Alejandro, Garcia, Mario January 2008 (has links)
<p>The automotive field is becoming more and more complex and cars are no longer just pure mechanical artifacts. Today much more than 50 % of the functionality of a car is computerized, so, a modern car system is obviously based on mixed technologies which emphasize the need for new approaches to the design process compared to the processes of yesterday. A corresponding technology shift has been experienced in the aerospace industry starting in the late sixties and today aircraft could not fly without its computers and the pilots’ environment has turned to a so called glass cockpit with no iron-made instrumentation left. A very similar change is still going on in the automotive area.</p><p>Simulator-Based Design (SBD) refers to design, development and testing new products, systems and applications which include an operator in their operation. Simulator-Based Design has been used for decades in the aviation industry. It has been a common process in this field. SBD may be considered as a more specific application of simulation-based design, where the specific feature is a platform, the simulator itself. The simulator could consist of a generic computer environment in combination with dedicated hardware components, for instance a cockpit. This solution gives us the possibility of including the human operator in the simulation.</p><p>The name of the project is Simulator-Based Design in Practice. The purpose of this master thesis is to get a complete practice in how to use a human-in-the-loop simulator as a tool in design activities focusing on the automotive area. This application area may be seen as an example of systems where an operator is included in the operation and thus experience from the car application could be transferred to other areas like aviation or control rooms in the process industry.</p><p>During the performance of the project we have gone through the main parts of the SBD process. There are many steps to complete the whole cycle and many of them have iterative loops that connect these steps with the previous one. This process starts with a concept (product/system) and continues with a virtual prototyping stage followed by implementation, test design, human-in-the-loop simulation, data analysis, design synthesis and in the end a product/system decision. An iterative process approach makes the cycle flexible and goal oriented.</p><p>We have learnt how to use the simulator and how to perform the whole cycle of SBD. We first started getting familiar with the simulator and the ASim software and then we were trying to reduce the number of computers in the simulator and changing the network in order to find good optimization pf the computer power. The second step has been to implement a new application to the simulator. This new application is the rear mirror view and consists of a new LCD monitor and the rear view vision that must be seen in the new monitor. Finally we updated the cockpit to the new language program Action Script 3.0.</p><p>The information gathering consisted of the course Human-System interaction in the University, the introduction course to ASim software and the course of Action Script 3.0.</p>
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Simulator-Based Design in PracticeLopez, Alejandro, Garcia, Mario January 2008 (has links)
The automotive field is becoming more and more complex and cars are no longer just pure mechanical artifacts. Today much more than 50 % of the functionality of a car is computerized, so, a modern car system is obviously based on mixed technologies which emphasize the need for new approaches to the design process compared to the processes of yesterday. A corresponding technology shift has been experienced in the aerospace industry starting in the late sixties and today aircraft could not fly without its computers and the pilots’ environment has turned to a so called glass cockpit with no iron-made instrumentation left. A very similar change is still going on in the automotive area. Simulator-Based Design (SBD) refers to design, development and testing new products, systems and applications which include an operator in their operation. Simulator-Based Design has been used for decades in the aviation industry. It has been a common process in this field. SBD may be considered as a more specific application of simulation-based design, where the specific feature is a platform, the simulator itself. The simulator could consist of a generic computer environment in combination with dedicated hardware components, for instance a cockpit. This solution gives us the possibility of including the human operator in the simulation. The name of the project is Simulator-Based Design in Practice. The purpose of this master thesis is to get a complete practice in how to use a human-in-the-loop simulator as a tool in design activities focusing on the automotive area. This application area may be seen as an example of systems where an operator is included in the operation and thus experience from the car application could be transferred to other areas like aviation or control rooms in the process industry. During the performance of the project we have gone through the main parts of the SBD process. There are many steps to complete the whole cycle and many of them have iterative loops that connect these steps with the previous one. This process starts with a concept (product/system) and continues with a virtual prototyping stage followed by implementation, test design, human-in-the-loop simulation, data analysis, design synthesis and in the end a product/system decision. An iterative process approach makes the cycle flexible and goal oriented. We have learnt how to use the simulator and how to perform the whole cycle of SBD. We first started getting familiar with the simulator and the ASim software and then we were trying to reduce the number of computers in the simulator and changing the network in order to find good optimization pf the computer power. The second step has been to implement a new application to the simulator. This new application is the rear mirror view and consists of a new LCD monitor and the rear view vision that must be seen in the new monitor. Finally we updated the cockpit to the new language program Action Script 3.0. The information gathering consisted of the course Human-System interaction in the University, the introduction course to ASim software and the course of Action Script 3.0.
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Simulator-Based Design : Methodology and vehicle display applicationAlm, Torbjörn January 2007 (has links)
Human-in-the-loop simulators have long been used in the research community as well as in industry. The aviation field has been the pioneers in the use of simulators for design purposes. In contrast, corresponding activities in the automotive area have been less widespread. Published reports on experimental activities based on human-in-the-loop simulations have focused on methods used in the study, but nobody seems to have taken a step back and looked at the wider methodological picture of Simulator-Based Design. The purpose of this thesis is to fill this gap by drawing, in part, upon the author’s long experience in this field. In aircraft and lately also in ground vehicles there has been a technology shift from pure mechanics to computer-based systems. The physical interface has turned into screen-based solutions. This trend towards glass has just begun for ground vehicles. This development in vehicle technology has opened the door for new design approaches, not only for design itself, but also for the development process. Simulator-Based Design (SBD) is very compatible with this trend. The first part of this thesis proposes a structure for the process of SBD and links it to the corresponding methodology for software design. In the second part of the thesis the focus changes from methodology to application and specifically to the design of three-dimensional situation displays. Such displays are supposed to support the human operator with a view of a situation beyond the more or less limited visual range. In the aircraft application interest focuses on the surrounding air traffic in the light of the evolving free-flight concept, where responsibility for separation between aircraft will be (partly) transferred from ground-based flight controllers to air crews. This new responsibility must be supported by new technology and the situational view must be displayed from the perspective of the aircraft. Some basic design questions for such 3D displays were investigated resulting in an adaptive interface approach, where the current situation and task govern the details of information presentation. The thesis also discusses work on situation displays for ground vehicles. The most prominent example may be the Night Vision system, where the road situation ahead is depicted on a screen in the cab. The existing systems are based on continuous presentation, an approach that we have questioned, since there is strong evidence for negative behavioral adaptation. This means, for example, that the driver will drive faster, since vision has been enhanced, and thereby consume the safety margins that the system was supposed to deliver. Our investigation supports a situation-dependant approach and no continuous presentation. In conclusion, the results from our simulator-based studies showed advantages for adaptive interface solutions. Such design concepts are much more complicated than traditional static interfaces. This finding emphasizes the need for more dynamic design resources in order to have a complete understanding of the situation-related interface changes. The use of human-in-the-loop simulators and deployment of Simulator-Based Design will satisfy this need.
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