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Welcome to
Rike Hall
CONSECTETUR ADIPISCING ELIT. MORBI BIBENDUM PHARETRA LOREM, ACCUMSAN SAN NULLA.
Mauris aliquet neque quis libero consequat vestibulum. Donec lacinia consequat dolor viverra sagittis. Praesent consequat porttitor risus, eu condimentum nunc. Proin et velit ac sapien luctus efficitur egestas ac augue. Nunc dictum, augue eget eleifend interdum, quam libero imperdiet lectus, vel scelerisque turpis lectus vel ligula. Duis a porta sem. Maecenas sollicitudin nunc id risus fringilla, a pharetra orci iaculis. Aliquam turpis ligula, tincidunt sit amet consequat ac, imperdiet non dolor.
Integer gravida dui quis euismod placerat. Maecenas quis accumsan ipsum. Aliquam gravida velit at dolor mollis, quis luctus mauris vulputate. Proin condimentum id nunc sed sollicitudin.
DONEC FEUGIAT:
• Nisl nec mi sollicitudin facilisis
• Nam sed faucibus est.
• Ut eget lorem sed leo.
• Sollicitudin tempor sit amet non urna.
• Aliquam feugiat mauris sit amet.
LOREM IPSUM:
$150,000
___
Welcome to
Rike Hall
CONSECTETUR ADIPISCING ELIT. MORBI BIBENDUM PHARETRA LOREM, ACCUMSAN SAN NULLA.
Mauris aliquet neque quis libero consequat vestibulum. Donec lacinia consequat dolor viverra sagittis. Praesent consequat porttitor risus, eu condimentum nunc. Proin et velit ac sapien luctus efficitur egestas ac augue. Nunc dictum, augue eget eleifend interdum, quam libero imperdiet lectus, vel scelerisque turpis lectus vel ligula. Duis a porta sem. Maecenas sollicitudin nunc id risus fringilla, a pharetra orci iaculis. Aliquam turpis ligula, tincidunt sit amet consequat ac, imperdiet non dolor.
Integer gravida dui quis euismod placerat. Maecenas quis accumsan ipsum. Aliquam gravida velit at dolor mollis, quis luctus mauris vulputate. Proin condimentum id nunc sed sollicitudin.
DONEC FEUGIAT:
• Nisl nec mi sollicitudin facilisis
• Nam sed faucibus est.
• Ut eget lorem sed leo.
• Sollicitudin tempor sit amet non urna.
• Aliquam feugiat mauris sit amet.
LOREM IPSUM:
$150,000
___
LOREM IPSUM
DOLOR SIT AMET
___
LOREM IPSUM
DOLOR SIT AMET
JOHN DOE
Licensed Real Estate Salesperson
Tlf.: +11 111 111 111
jhondoe@realestate.com
www.loremipsum.com
Mauris aliquet neque quis libero consequat vestibulum. Donec lacinia consequat dolor viverra sagittis. Praesent consequat porttitor risus, eu condimentum nunc. Proin et velit ac sapien luctus efficitur egestas ac augue. Nunc dictum, augue eget eleifend interdum, quam libero imperdiet lectus, vel scelerisque turpis lectus vel ligula. Duis a porta sem. Maecenas sollicitudin nunc id risus fringilla, a pharetra orci iaculis. Aliquam turpis ligula, tincidunt sit amet consequat ac, imperdiet non dolor.
JOHN DOE
Licensed Real Estate Salesperson
Tlf.: +11 111 111 111
jhondoe@realestate.com
www.loremipsum.com
Mauris aliquet neque quis libero consequat vestibulum. Donec lacinia consequat dolor viverra sagittis. Praesent consequat porttitor risus, eu condimentum nunc. Proin et velit ac sapien luctus efficitur egestas ac augue. Nunc dictum, augue eget eleifend interdum, quam libero imperdiet lectus, vel scelerisque turpis lectus vel ligula. Duis a porta sem. Maecenas sollicitudin nunc id risus fringilla, a pharetra orci iaculis. Aliquam turpis ligula, tincidunt sit amet consequat ac, imperdiet non dolor.
Company Name
www.loremipsum.com
info@loremipsum.com
Tlf.: +11 111 111 111
Company Name
www.loremipsum.com
info@loremipsum.com
Tlf.: +11 111 111 111
This classroom and its sibling room 145 have plenty of space for students, a full surface writing area.
This lobby connects two open computer labs and the SCALE Up classroom to the rest of the Russ Engineering Center. Printing services are also available here to College of Engineering and Computer Science students.
This computer lab and its twin across the hall come equipped with a wide range of the software you’ll use in your classes, saving you from having to download special software to your personal computer. These two labs are open 24 hours, every single day, so you’ll always be able get your work done on time.
This computer lab and its twin across the hall come equipped with a wide range of the software you’ll use in your classes, saving you from having to download special software to your personal computer. These two labs are open 24 hours, every single day, so you’ll always be able get your work done on time.
This classroom features a full surface for writing and plenty of seating. The elevated seats help to improve the visibility of the lecturer and their material. Wright State's average class size is 25 students.
This SCALE-Up classroom houses an active learning environment designed to foster teamwork and collaborative work. Several different class styles from the standard lecture to an active learning style with a focus on hands-on learning can be housed here. Thanks to the 360° views of the lecture, no seat in this room is a bad seat.
The Cacioppo Teaching Lab features plenty of space for students to work on assignments that may require specialized software. Classes are also occasionally held here when they have a heavy focus on computer work.
Featuring multiple projectors for enhanced visibility, this classroom also has multiple large group desks to foster teamwork. Staggered heights also allow for students to more easily view the lecuturer and their material.
This atrium is the center of the Fritz and Delores Russ Engineering Center. Classrooms and computer labs can be found on the first floor, with faculty offices and specialty labs located on the higher floors of Russ.
Affectionately nicknamed “The Fishbowl”, this 24-hour 7-day-a-week study lounge features plenty of seating for course work and relaxing on campus. Conveniently located in the hallway between the Joshi Research Center and Russ Engineering Center, The Fishbowl is also right across the hall from a Rey-Rey café. When the university is fully in person, this study lounge is very popular with students.
This lab contains spinning wheels that are used to polish material and prepare the samples to be looked at through microscopes. The polishing is completed using slurries mixed with very fine particles of diamond. Smaller and smaller diamond particles are used until the surface is polished to a mirror finish.
This room contains many different microscopes allowing students to get a close look at the structures within materials.
In this lab, Wright State seniors design and build an offroad vehicle from scratch to race in a collegiate design competition sponsored by the Society of Automotive Engineers (SAE). Additionally, students present their design and business plan to mass produce their car in a shark tank like environment. Students drive their car in dynamic events such as acceleration, braking, manueverability, sled pull, suspension, and top speed events. The entire event culminates in a 4 hour endurance race to fully test all systems on the car.
This lab is overseen by Dr. Caroline Cao. Research areas include: human factors of medical systems, design and evaluation of enabling technology (e.g., robotics, image guidance, haptics) for minimally invasive surgery, training of surgical skills in real and virtual simulators, and decision-making and team communication in the operating room.
The scanning electron microscope (SEM) is used to look at microstructures within different materials. An focused electron beam is scanned across the surface of the material and the signal responds to give information about the topography and composition of the surface.
In this lab, we break things. There are several different machines that pull or compress material to see how strong it is. There are also some ovens that can be used to change the structure of a material. Once the structure is changed, the material can be tested and the change in properties observed.
This lab is overseen by Dr. Sherif Elbasiouny. Research areas: neuroengineering and computational neuroscience for analysis of disease mechanisms and identification of drugs targets, neurorehabilitation and sensorimotor control of neural prostheses after peripheral or spinal cord injury, investigation of neurodegenerative diseases (e.g., ALS). Methods employed in the research program include: computational modeling, electrophysiology, immunohistochemistry, behavioral and motor performance analysis, electrical stimulation.
This lab is overseen by Dr. Caroline Cao. Research areas include: human factors of medical systems, design and evaluation of enabling technology (e.g., robotics, image guidance, haptics) for minimally invasive surgery, training of surgical skills in real and virtual simulators, and decision-making and team communication in the operating room.
This lab is overseen by Dr. Subashini Ganapathy. Research areas include: integrating technology for improving human performance, health and wellness, design thinking, user-experience assessment, and human factors engineering. She directs the Interaction Design & Modeling Lab that explores fundamental and applied research in the area of Human Computer Interaction. This lab conducts work that seeks to understand how technology can help enable more healthy, socially connected, reflective living.
This lab is overseen by Dr. Tarun Goswami. Research areas include studying the applicability of engineering materials in biomedical fields such as total joint replacements and characterizing their mechanics and durability. New bio/nano-material development and assessing their biocompatibility. Design and development of orthopedic related devices, injury (traumatic brain injury and cervical spinal injury) and device biomechanics assessments. Probabilistic and deterministic design and failure analyses of medical and engineering components. Laboratories supporting these efforts maintain imaging data base, computational modeling and analysis software and mechanical testing of hard bones to research bone mechanics.
Additive manufacturing, or 3D printing is the process of creating a part from a computer drawing using a layer by layer additive process. This lab contains several different types of 3D printers that can print plastic, metal and electronics! This Creator Machine uses a laser to selectively melt small layers of metal powders. The result is a solid metal geometry with complex designs that are being used in fields such as aerospace and medical. Material extrusion is a 3D printing process that pushes a plastic filament through a nozzle to create a plastic part. Our material extrusion printers are often used to prototype parts for capstone design projects. Vat Photopolymerization Printers: Photopolymerization is a process where a liquid resin is converted to a solid plastic part when exposed to UV light. This process can be used to print fine features, and a wide variety of material characteristics such as translucent and flexible material using our Vat Photopolymerization Printers.
This lab contains saws and mounting presses that prepare small samples to be polished.
Such a cool room needs a description of somekind. :-)
Wright State seniors design and build a solar powered boat to race in a collegiate design competition sponsored by UPS Battery Center Solar Splash here. Students explore solar panels, batteries, electric motors, drag, etc while optimizing their boat to race in sprints and endurance events. This lab also features a wind tunnel!
This lab is overseen by Dr. Jaime Ramirez-Vick. Research areas include: adult stem cell research for tissue engineering applications in bone and heart, development of nanotechnologies for the treatment and detection of cancer, and development of various types of electrochemical biosensors. Tissue engineering research has focused on the development of 3D biomimetic scaffolds and the use biophysical stimulation to direct mesenchymal stem cell commitment and differentiation. Specifically, using electromagnetic, microgravity, ultrasound and mechanical stimuli while monitoring genetic and epigenetic changes to understand the underlying mechanisms. Also, we are developing multifunctional nanomedical formulations for cancer siRNA therapeutics capable of simultaneous targeting, imaging and drug delivery. In addition, current investigations related to biosensors focus on applying nanostructured electrodes for DNA based detection to identify transcription factor biomarkers for recognition of breast and colorectal cancers at an early stage.
The scanning electron microscope (SEM) is used to look at microstructures within different materials. An focused electron beam is scanned across the surface of the material and the signal responds to give information about the topography and composition of the surface.
This is the classroom where most of the Cyber Classes are taught. Courses taught in this room can be taken either online or in-person.
The purpose of this laboratory project is to provide hands-on experience with basic digital devices. Essentially, this is the laboratory where students learn how we can control electrons and use them to perform useful work on our behalf. Large digital devices are difficult to conceptualize, design, and debug. Therefore, when faced with a complex problem, digital designers often look for opportunities to solve it by integrating collections of smaller problems. In this room students practice breaking problems down into collections of smaller problems until the sub-problems can be solved with existing or easily constructed digital devices. Students first practice how to analyze existing systems and discover the difference between theoretical models and practical implementation. Students then design, build, and test systems of their own devising. The final course project includes the construction of a simple, but fully functional, microprocessor CPU. Depending on subjects, different computer languages are used. They include C, assembly, C++, and Verilog.
This lab is overseen by Dr. Caroline Cao. Research areas include: human factors of medical systems, design and evaluation of enabling technology (e.g., robotics, image guidance, haptics) for minimally invasive surgery, training of surgical skills in real and virtual simulators, and decision-making and team communication in the operating room.
The importance of the surface chemistry increases as the need for high-performance materials increases, which leads to understanding the surface interactions of the materials with the environment. In such a case, the material characterization technique, XPS, plays a crucial role in exploring the factors such as adhesive properties, Corrosion rate, catalytic activity, wettability, and failure mechanism. It can also measure elemental Composition empirical formula, chemical state, and electronic state by irradiating the test sample with a beam of X-ray while measuring the Kinetic energy and binding energy of electrons emitted from the surface within the 100nm region. A Spectra is recorded by the detector when the electrons are emitted, which helps us understand the Surface chemistry and can further be analyzed using Data Deconvolution Software CASA-XPS. XPS can analyze various types of materials like Semi-conductors, bio-materials, metal alloys, woods, bones, ceramics, inorganic materials, coatings such as paints, and makeup products. In general terms, XPS can analyze various materials and act as an efficient tool to understand the interactions between atoms and molecules.
This is an informal learning lab that doubles as a Team Projects II/Senior Design build space. Its main purpose is to provide access to lots of cool stuff. Students and student clubs can meet here, and the Computer Science and Engineering (CSE) department hosts how-to sessions here. It’s accessible to any student in the CSE program. Boffin Nights are held once a week for students to get together, hack, code, and tear thing apart, and unwind!
All graphics focused classes are taught here, and research related to data visualization and virtual and augmented reality. Each display is 3-D capable with glasses, and each system in this room features a powerful graphics card, running programs on the GPU, not the CPU. The televisions also feature a Tracking System that tracks gray balls placed on glasses or on controllers. This software is the same as that found in the Visualization Research Lab on the 2nd floor of Russ.
The System-on-a-Chip (SoC) is perhaps the most important component present in a smartphone. SoC not only comprises up of the smartphone’s CPU, LTE modem, display processor, video processor, but GPU. We are in the age of continuing digital revolution.
The course emphasis is placed on top-down design methodology beginning with structural HDL and then behavioral HDL description. We begin by developing HDL skills and techniques for designing digital combinational, synchronous sequential, and pipeline circuits. We study digital signal processor and controller. We discuss HDL/FPGA design methodology for FPGA implementation and verification.
In the EE4620 course, emphasis is placed on top-down design methodology beginning with structural HDL and then behavioral HDL description. We begin by developing HDL skills and techniques for designing digital combinational, synchronous sequential, and pipeline circuits. We study digital signal processor and controller. We discuss HDL/FPGA design methodology for FPGA implementation and verification.
This lab is overseen by Dr. Jaime Ramirez-Vick. Research areas include: adult stem cell research for tissue engineering applications in bone and heart, development of nanotechnologies for the treatment and detection of cancer, and development of various types of electrochemical biosensors. Tissue engineering research has focused on the development of 3D biomimetic scaffolds and the use biophysical stimulation to direct mesenchymal stem cell commitment and differentiation. Specifically, using electromagnetic, microgravity, ultrasound and mechanical stimuli while monitoring genetic and epigenetic changes to understand the underlying mechanisms. Also, we are developing multifunctional nanomedical formulations for cancer siRNA therapeutics capable of simultaneous targeting, imaging and drug delivery. In addition, current investigations related to biosensors focus on applying nanostructured electrodes for DNA based detection to identify transcription factor biomarkers for recognition of breast and colorectal cancers at an early stage.