Tag Archives: Rochester Institute of Technology

ArtSci Salon visits the Society for Literature, Science & the Arts 2018 Meeting in Toronto (Canada) while Vancouver’s Curiosity Collider provides a November 2018 update

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I have two art/sci (or sciart) announcements, one concerns an event and the other is a news update.

Toronto’s ArtSci Salon and the Society of Literature, Science & the Arts (SLSA) 2018 Meeting

How could I not have stumbled across SLSA until now? Better late than never but the 2018 meeting/conference in Toronto, Canada is the 32nd of this annual event. (sigh)

Getting on to the important points, the ArtSci Salon is hosting a special roundtable as part of the conference (from a November 14, 2018 announcement received via email),

ArtSci Salon has organized a special roundtable at the annual SLSA
(Society for Science Literature and the Arts) which will take place in
Toronto this week.

The roundtable is public and will be held at OCADU [Ontario College of Art and Design University] in the gallery on 49 McCaul Street.

Re-locating the rational: on the re-making of categories through art and science (or: the artist is out of mind!)

A roundtable and a mobile/pop-up exhibition organized by ArtSci Salon

The world always exceeds our conception of it (Shotwell, 2016)

Coinciding with this year’s SLSA “Out of Mind” conference in Toronto, ArtSci Salon is proposing a panel/roundtable on “out-of-mindedness” as a way to re-think categories, and to disrupt the disciplinary and methodological status quo through which we normally see science and the humanities unfolding in academic contexts. We plan to do it through a pop-up exhibition featuring the works of local artists and members of SLSA.

What to do when the sciences and the humanities loose [sic] their ability to fully grasp, and sometimes even speak of, phenomena that have inevitably become too complex, too diffuse to be simplified through a model or a formula, or to be seized and summarized by one discipline?

This initiative is not designed to propose a set of new categories, but to pose a series of open questions, highlighting the necessity to conduct collaborative research between artistic practices and scientific research. We interpret the idea of “out of mind” as a strategy. In fact, using the arts as our preferred mode of expression, we believe that we ought to step out of the traditional mind configurations and fixed wiring in order to seize new ways to come to term with the multiplicities characterizing current environmental transformations. These occurrences have proved to be connected with nature, culture, and society in too many intricate ways, to the extent that neither science, nor technological methods are able to fully comprehend them.

Roundtable Participants:

Roberta Buiani (Chair)

Erika Biddles

Jenifer Wightman

Stephanie Rothenberg

Adam Zaretsky

Kathy High

Dolores Steinman

Here’s the poster:

One more logistical detail,

[T]he roundtable will be at 10:30-12:00 noon [Friday, November 16, 2018] followed by a small tour of the mobile pop-up exhibition[.]

For the curious, here’s the SLSA website and the SLSA 2018 [Meeting]—Out of Your Mind website. Unexpectedly, the University of Toronto is not one of the conference hosts, instead we have the University of Waterloo [Waterloo, Ontario] and York University [Toronto, Ontario] as joint hosts with OCAD University—Canada’s oldest art and design institution—partnering with the Rochester Institute of Technology (New York state, US).

Vancouver’s Curiosity Collider

Coincidentally on the same day I received the ArtSci Salon event information, I received a November 14, 2018 update for Vancouver’s art/sci (or sciart) organization, Curiosity Collider. From the update received via email,

Collider Update

Next events (save-the-date), call for submissions, and other art+science in town

Collisions Festival:
Meet Up & Hang Out

Are you an artist working in the sci/art genre? A scientist interested in collaborating with artists? Or one who wears both hats?

In the fall of 2019, the Curiosity Collider will be hosting our inaugural Sci-Art festival The Collisions Festival; the first theme will be Invasive Systems. The call for submission will be open in spring, 2019. The theme is meant to be broad in scope and not limited to any specific scientific subject/discipline; participants are encouraged to suggest various interpretation of the theme.

We would like to invite all artists and scientists who are interested in participating or potentially submitting a proposal to join us at this meet up event, chat about possible collaborations, and learn more about projects and details on “collaborative work” proposals we are looking for.

RSVP now so we know how many to expect.. This is a casual drop in event; feel free to stay, or just stop by and say hi!

Notice that RSVP? Taken with the next announcement, something becomes evident,

Join the Collider Team!

Are you passionate about art and science? Want to be part of the awesome Curiosity Collider team to help create new ways to experience science? 

We are now inviting applications for the following positions:

Read more on our volunteer page. Feel free to contact us if you have any questions!

In the old days a ‘development director’ was a ‘fundraiser’. That RSVP? Likely, they’re trying to establish the size of their potential audience so they can get government grants. Audience size is important to corporate or ‘other’ funders but if you want a government grant you need numbers.

Getting back to the update, this is a grouping of Curiosity Collider’s latest hits,

#ColliderCafe: Art. Science. Cadence.

Did you miss our most recent Collider Cafe event? You can now chek out the talks by Singer-songwriter Devon More, Biologists Wayne Maddison and David Maddison, as well as Integrated Media Artist Victoria Gibson on our YouTube Channel.

Check out the talks now.

Et al 3: Collaboration Process for Quantum Futures

Nerd Nite, Science Slam, and Curiosity Collider joined forces for the 3rd edition of Et al: the ultimate bar science night event. During the event, Quantum Physicist James Day and our Creative Managing Director Char Hoyt gave attendees an overview of the collaboration process that made Night shift: Quantum Futures, an event curated by CC and hosted at the Museum of Anthropology, possible.

Missed the show? Watch the presentation on our YouTube channel now.

While they don’t seem to have any details, there is a date for the next Collider Cafe,

Save the Date:
Next Collider Cafe

Our next Collider Cafe will be on Wednesday, January 23 at Cafe Deux Soleils. #ColliderCafe is a space for artists, scientists, makers, and anyone interested in art+science. Meet. Discover. Connect. Create.

Are you curious? Join us to explore how art and science intersect in the exploration of curiosity.

Finally, a miscellaneous listing of related events being held in Vancouver, mostly, this November,

Looking for more art+science in town?

  • November 17 (Victoria) Science Writers and Communicators of Canada is hosting a workshop on science writing in an age of reconciliation: What science writers can learn from indigenous community members about better representation and relationships. Only a few spots left! Register now.
  • November 15-18 CC friend Dzee Louise will open her studio during the East Side Cultural Crawl! Drop by at studio #5 just at the top of the stairs of the William Clark Building at 1310 William Street (on the corner of Clark).
  • November 21 Natural History (Paleoart) Illustrator Julius Csotonyi will present a public lecture at the Vancouver Public Library (Kits branch) on the mutually beneficial affair between science and art.
  • November 21 Our friends at Nerd Nite Vancouver is hosting another awesome event next week, including a presentation by artist Michael Markowsky who will talk about how he ends up “Painting on the Moon”. Get your tickets now!
  • Until December 15 Vancouver Biennale’s CURIOUS IMAGININGS continues…check out the exhibition that will “challenge us to explore the social impacts of emerging biotechnology and our ethical limits in an age where genetic engineering and digital technologies are already pushing the boundaries of humanity.”

For more Vancouver art+science events, visit the Curiosity Collider events calendar. Let us know about your art+science events by emailing info@curiositycollider.org.

I did write a preview (June 18, 2018) for the last event on the list, Curious Imaginings, which included some of the latest science on xenotransplantation and chimeras (i.e., examples of  emerging biotechnology). That’s all folks!

I sing the body cyber: two projects funded by the US National Science Foundation

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Points to anyone who recognized the reference to Walt Whitman’s poem, “I sing the body electric,” from his classic collection, Leaves of Grass (1867 edition; h/t Wikipedia entry). I wonder if the cyber physical systems (CPS) work being funded by the US National Science Foundation (NSF) in the US will occasion poetry too.

More practically, a May 15, 2015 news item on Nanowerk, describes two cyber physical systems (CPS) research projects newly funded by the NSF,

Today [May 12, 2015] the National Science Foundation (NSF) announced two, five-year, center-scale awards totaling $8.75 million to advance the state-of-the-art in medical and cyber-physical systems (CPS).

One project will develop “Cyberheart”–a platform for virtual, patient-specific human heart models and associated device therapies that can be used to improve and accelerate medical-device development and testing. The other project will combine teams of microrobots with synthetic cells to perform functions that may one day lead to tissue and organ re-generation.

CPS are engineered systems that are built from, and depend upon, the seamless integration of computation and physical components. Often called the “Internet of Things,” CPS enable capabilities that go beyond the embedded systems of today.

“NSF has been a leader in supporting research in cyber-physical systems, which has provided a foundation for putting the ‘smart’ in health, transportation, energy and infrastructure systems,” said Jim Kurose, head of Computer & Information Science & Engineering at NSF. “We look forward to the results of these two new awards, which paint a new and compelling vision for what’s possible for smart health.”

Cyber-physical systems have the potential to benefit many sectors of our society, including healthcare. While advances in sensors and wearable devices have the capacity to improve aspects of medical care, from disease prevention to emergency response, and synthetic biology and robotics hold the promise of regenerating and maintaining the body in radical new ways, little is known about how advances in CPS can integrate these technologies to improve health outcomes.

These new NSF-funded projects will investigate two very different ways that CPS can be used in the biological and medical realms.

A May 12, 2015 NSF news release (also on EurekAlert), which originated the news item, describes the two CPS projects,

Bio-CPS for engineering living cells

A team of leading computer scientists, roboticists and biologists from Boston University, the University of Pennsylvania and MIT have come together to develop a system that combines the capabilities of nano-scale robots with specially designed synthetic organisms. Together, they believe this hybrid “bio-CPS” will be capable of performing heretofore impossible functions, from microscopic assembly to cell sensing within the body.

“We bring together synthetic biology and micron-scale robotics to engineer the emergence of desired behaviors in populations of bacterial and mammalian cells,” said Calin Belta, a professor of mechanical engineering, systems engineering and bioinformatics at Boston University and principal investigator on the project. “This project will impact several application areas ranging from tissue engineering to drug development.”

The project builds on previous research by each team member in diverse disciplines and early proof-of-concept designs of bio-CPS. According to the team, the research is also driven by recent advances in the emerging field of synthetic biology, in particular the ability to rapidly incorporate new capabilities into simple cells. Researchers so far have not been able to control and coordinate the behavior of synthetic cells in isolation, but the introduction of microrobots that can be externally controlled may be transformative.

In this new project, the team will focus on bio-CPS with the ability to sense, transport and work together. As a demonstration of their idea, they will develop teams of synthetic cell/microrobot hybrids capable of constructing a complex, fabric-like surface.

Vijay Kumar (University of Pennsylvania), Ron Weiss (MIT), and Douglas Densmore (BU) are co-investigators of the project.

Medical-CPS and the ‘Cyberheart’

CPS such as wearable sensors and implantable devices are already being used to assess health, improve quality of life, provide cost-effective care and potentially speed up disease diagnosis and prevention. [emphasis mine]

Extending these efforts, researchers from seven leading universities and centers are working together to develop far more realistic cardiac and device models than currently exist. This so-called “Cyberheart” platform can be used to test and validate medical devices faster and at a far lower cost than existing methods. CyberHeart also can be used to design safe, patient-specific device therapies, thereby lowering the risk to the patient.

“Innovative ‘virtual’ design methodologies for implantable cardiac medical devices will speed device development and yield safer, more effective devices and device-based therapies, than is currently possible,” said Scott Smolka, a professor of computer science at Stony Brook University and one of the principal investigators on the award.

The group’s approach combines patient-specific computational models of heart dynamics with advanced mathematical techniques for analyzing how these models interact with medical devices. The analytical techniques can be used to detect potential flaws in device behavior early on during the device-design phase, before animal and human trials begin. They also can be used in a clinical setting to optimize device settings on a patient-by-patient basis before devices are implanted.

“We believe that our coordinated, multi-disciplinary approach, which balances theoretical, experimental and practical concerns, will yield transformational results in medical-device design and foundations of cyber-physical system verification,” Smolka said.

The team will develop virtual device models which can be coupled together with virtual heart models to realize a full virtual development platform that can be subjected to computational analysis and simulation techniques. Moreover, they are working with experimentalists who will study the behavior of virtual and actual devices on animals’ hearts.

Co-investigators on the project include Edmund Clarke (Carnegie Mellon University), Elizabeth Cherry (Rochester Institute of Technology), W. Rance Cleaveland (University of Maryland), Flavio Fenton (Georgia Tech), Rahul Mangharam (University of Pennsylvania), Arnab Ray (Fraunhofer Center for Experimental Software Engineering [Germany]) and James Glimm and Radu Grosu (Stony Brook University). Richard A. Gray of the U.S. Food and Drug Administration is another key contributor.

It is fascinating to observe how terminology is shifting from pacemakers and deep brain stimulators as implants to “CPS such as wearable sensors and implantable devices … .” A new category has been created, CPS, which conjoins medical devices with other sensing devices such as wearable fitness monitors found in the consumer market. I imagine it’s an attempt to quell fears about injecting strange things into or adding strange things to your body—microrobots and nanorobots partially derived from synthetic biology research which are “… capable of performing heretofore impossible functions, from microscopic assembly to cell sensing within the body.” They’ve also sneaked in a reference to synthetic biology, an area of research where some concerns have been expressed, from my March 19, 2013 post about a poll and synthetic biology concerns,

In our latest survey, conducted in January 2013, three-fourths of respondents say they have heard little or nothing about synthetic biology, a level consistent with that measured in 2010. While initial impressions about the science are largely undefined, these feelings do not necessarily become more positive as respondents learn more. The public has mixed reactions to specific synthetic biology applications, and almost one-third of respondents favor a ban “on synthetic biology research until we better understand its implications and risks,” while 61 percent think the science should move forward.

I imagine that for scientists, 61% in favour of more research is not particularly comforting given how easily and quickly public opinion can shift.

Outer space telescopes made of micro- and nanoparticles (smart dust)

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Scientists at Rochester Institute of Technology (RIT is located in New York state) are working on a project that would see ‘smart dust’ used as a telescope in outer space. From a Dec. 1, 2014 news item on phys.org,

Telescope lenses someday might come in aerosol cans. Scientists at Rochester Institute of Technology and the NASA [ National Aeronautics and Space Administration] Jet Propulsion Laboratory are exploring a new type of space telescope with an aperture made of swarms of particles released from a canister and controlled by a laser.

These floating lenses would be larger, cheaper and lighter than apertures on conventional space-based imaging systems like NASA’s Hubble and James Webb space telescopes, said Grover Swartzlander, associate professor at RIT’s Chester F. Carlson Center for Imaging Science and Fellow of the Optical Society of America. Swartzlander is a co-investigator on the Jet Propulsion team led by Marco Quadrelli.

A Dec. 1, 2014 RIT news release by Susan Gawlowicz, which originated the news item, describes the NASA project and provides more details about the technology,

NASA’s Innovative Advanced Concepts Program is funding the second phase of the “orbiting rainbows” project that attempts to combine space optics and “smart dust,” or autonomous robotic system technology. The smart dust is made of a photo-polymer, or a light-sensitive plastic, covered with a metallic coating.

“Our motivation is to make a very large aperture telescope in space and that’s typically very expensive and difficult to do,” Swartzlander said. “You don’t have to have one continuous mass telescope in order to do astronomy—it can be distributed over a wide distance. Our proposed concept could be a very cheap, easy way to achieve large coverage, something you couldn’t do with the James Webb-type of approach.”

An adaptive optical imaging sensor comprised of tiny floating mirrors could support large-scale NASA missions and lead to new technology in astrophysical imaging and remote sensing.

Swarms of smart dust forming single or multiple lenses could grow to reach tens of meters to thousands of kilometers in diameter. According to Swartzlander, the unprecedented resolution and detail might be great enough to spot clouds on exoplanets, or planets beyond our solar system.

“This is really next generation,” Swartzlander said. “It’s 20, 30 years out. We’re at the very first step.”

Previous scientists have envisioned orbiting apertures but not the control mechanism. This new concept relies upon Swartzlander’s expertise in the use of light, or photons, to manipulate micro- or nano-particles like smart dust. He developed and patented the techniques known as “optical lift,” in which light from a laser produces radiation pressure that controls the position and orientation of small objects.

In this application, radiation pressure positions the smart dust in a coherent pattern oriented toward an astronomical object. The reflective particles form a lens and channel light to a sensor, or a large array of detectors, on a satellite. Controlling the smart dust to reflect enough light to the sensor to make it work will be a technological hurdle, Swartzlander said.

Two RIT graduate students on Swartzlander’s team are working on different aspects of the project. Alexandra Artusio-Glimpse, a doctoral student in imaging science, is designing experiments in low-gravity environments to explore techniques for controlling swarms of particle and to determine the merits of using a single or multiple beams of light.

Swartzlander expects the telescope will produce speckled and grainy images. Xiaopeng Peng, a doctoral student in imaging science, is developing software algorithms for extracting information from the blurred image the sensor captures. The laser that will shape the smart dust into a lens also will measure the optical distortion caused by the imaging system. Peng will use this information to develop advanced image processing techniques to reverse the distortion and recover detailed images.

“Our goal at this point is to marry advanced computational photography with radiation-pressure control techniques to achieve a rough image,” Swartzlander said. “Then we can establish a roadmap for improving both the algorithms and the control system to achieve ‘out of this world’ images.”

You can find out more about NASA’s Orbiting Rainbows project here.

I just mentioned rainbows and optics with regard to Robert Grosseteste, a 13th century cleric who ‘unwove’ rainbows, in a Dec. 1, 2014 posting (scroll down about 60% of the way).