Researchers from Intel Labs, in collaboration with academic and industry experts, have introduced a groundbreaking technique for generating realistic and directable human motion from sparse, multi-modal inputs. Their work, highlighted at the European Conference on Computer Vision (ECCV 2024), focuses on overcoming the challenges of generating…
What is ChatGPT Canvas? The Alternative to Claude Artifacts
OpenAI has recently introduced an impressive feature called ChatGPT Canvas. Unlike the normal chat window we’ve grown accustomed to, ChatGPT Canvas offers a more robust and collaborative environment for tackling sophisticated projects. While other AI platforms like Claude have introduced similar concepts such as Claude Artifacts,…
Laura Lewis and Jing Kong receive postdoctoral mentoring award
MIT professors Laura Lewis and Jing Kong have been recognized with the MIT Postdoctoral Association’s Award for Excellence in Postdoctoral Mentoring. The award is given annually to faculty or other principal investigators (PIs) whose current and former postdoctoral scholars say they stand out in their efforts to create a supportive work environment for postdocs and support postdocs’ professional development.
This year, the award identified exceptional mentors in two categories. Lewis, the Athinoula A. Martinos Associate Professor in the Institute for Mechanical Engineering and Science and the Department of Electrical Engineering and Computer Science (EECS), was recognized as an early-career mentor. Kong, the Jerry McAfee (1940) Professor In Engineering in the Research Laboratory of Electronics and EECS, was recognized as an established mentor.
“It’s a very diverse kind of mentoring that you need for a postdoc,” said Vipindev Adat Vasudevan, who chaired the Postdoctoral Association committee organizing the award. “Every postdoc has different requirements. Some of the people will be going to industry, some of the people are going for academia… so everyone comes with a different objective.”
Vasudevan presented the award at a luncheon hosted by the Office of the Vice President for Research on Sept. 25 in recognition of National Postdoc Appreciation Week. The annual luncheon, celebrating the postdoctoral community’s contributions to MIT, is attended by hundreds of postdocs and faculty.
“The award recognizes faculty members who go above and beyond to create a professional, supportive, and inclusive environment to foster postdocs’ growth and success,” said Ian Waitz, vice president for research, who spoke at the luncheon. He noted the vital role postdocs play in advancing MIT research, mentoring undergraduate and graduate students, and connecting with colleagues from around the globe, while working toward launching independent research careers of their own.
“The best part of my job”
Nomination letters for Lewis spoke to her ability to create an inclusive and welcoming lab. In the words of one nominator, “She invests considerable time and effort in cultivating personalized mentoring relationships, ensuring each postdoc in her lab receives guidance and support tailored to their individual goals and circumstances.”
Other nominators commented on Lewis’ ability to facilitate collaborations that furthered postdocs’ research goals. Lewis encouraged them to work with other PIs to build their independence and professional development, and to develop their own research questions, they said. “I was never pushed to work on her projects — rather, she guided me towards finding and developing my own,” wrote one.
Lewis’ lab explores new ways to image the human brain, integrating engineering with neuroscience. Improving neuroimaging techniques can improve our understanding of the brain’s activity when asleep and awake, allowing researchers to understand sleep’s impact on brain health.
“I love working with my postdocs and trainees; it’s honestly the best part of my job,” Lewis says. “It’s important for any individual to be in an environment to help them grow toward what they want to do.”
Recognized as an early-career mentor, Lewis looks forward to seeing her postdocs’ career trajectories over time. Group members returning as collaborators come back with fresh ideas and creative approaches, she says, adding, “I view this mentoring relationship as lifelong.”
“No ego, no bias, just solid facts”
Kong’s nomination also speaks to the lifelong nature of the mentoring relationship. The 13 letters supporting Kong’s nomination came from past and current postdocs. Nearly all touched on Kong’s kindness and the culture of respect she maintains in the lab, alongside high expectations of scientific rigor.
“No ego, no bias, just solid facts and direct evidence,” wrote one nominator: “In discussions, she would ask you many questions that make you think ‘I should have asked that to myself’ or ‘why didn’t I think of this.’”
Kong was also praised for her ability to take the long view on projects and mentor postdocs through temporary challenges. One nominator wrote of a period when the results of a project were less promising than anticipated, saying, “Jing didn’t push me to switch my direction; instead, she was always glad to listen and discuss the new results. Because of her encouragement and long-term support, I eventually got very good results on this project.”
Kong’s lab focuses on the chemical synthesis of nanomaterials, such as carbon nanotubes, with the goal of characterizing their structures and identifying applications. Kong says postdocs are instrumental in bringing new ideas into the lab.
“I learn a lot from each one of them. They always have a different perspective, and also, they each have their unique talents. So we learn from each other,” she says. As a mentor, she sees her role as developing postdocs’ individual talents, while encouraging them to collaborate with group members who have different strengths.
The collaborations that Kong facilitates extend beyond the postdocs’ time at MIT. She views the postdoctoral period as a key stage in developing a professional network: “Their networking starts from the first day they join the group. They already in this process establish connections with other group members, and also our collaborators, that will continue on for many years.”
About the award
The Award for Excellence in Postdoctoral Mentoring has been awarded since 2022. With support from Ann Skoczenski, director of Postdoctoral Services in the Office of the VPR, and the Faculty Postdoctoral Advisory Committee, nominations are reviewed on four criteria:
- excellence in fostering and encouraging professional skills development and growth toward independence;
- ability to foster an inclusive work environment where postdoctoral mentees across a diversity of backgrounds and perspectives are empowered to engage in the mentee-mentor relationship;
- ability to support postdoctoral mentees in their pursuit of a chosen career path; and
- a commitment to a continued professional mentoring relationship with mentees, beyond the limit of the postdoctoral term.
The Award for Excellence in Postdoctoral Mentoring provides a celebratory lunch for the recipient’s research group, as well as the opportunity to participate in a mentoring seminar or panel discussion for the postdoctoral community. Last year’s award was given to Jesse Kroll, the Peter de Florez Professor of Civil and Environmental Engineering, professor of chemical engineering, and director of the Ralph M. Parsons Laboratory.
The Proliferation and Problem of the ✨ Sparkles ✨ Icon
Kate Kaplan hits on something over at Nielsen Norman Group’s blog that’s been bugging me:
The challenge with this icon is sparkle ambiguity: Participants in our recent research study generally agreed that it represented something a little special
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The Proliferation and Problem of the ✨ Sparkles ✨ Icon originally published…
The Human-AI Partnership in EDR: Augmenting Cybersecurity Teams with Artificial Intelligence
As cyberattacks grow more frequent and complex, companies struggle to keep up. Highly skilled security teams work night and day to spot and stop digital intruders, but it often feels like a losing battle. Hackers always seem to have the advantage. However, there is a light…
Iccha Sethi, Vice President of Engineering at Vanta – Interview Series
Iccha Sethi is Vice President of Engineering at Vanta, the leading Trust Management Platform, where she leads initiatives focused on enhancing security and compliance automation. Previously, she was an engineering leader at GitHub where she oversaw a multi-product portfolio including Actions, Hosted Runners, Codespaces, Packages, Pages,…
TransAgents: A New Approach to Machine Translation for Literary Works
Translating literary classics like War and Peace into other languages often results in losing the author’s unique style and cultural nuances. Addressing this longstanding challenge in literary translation is essential to preserving the essence of works while making them accessible globally. TransAgents introduces a pioneering approach…
PTZOptics Empowering Courtrooms with Live Streaming & Video Capture – Videoguys
In an era where digital integration has become paramount, PTZOptics stands at the forefront of providing innovative solutions for various sectors, notably within the courtroom. PTZOptics PTZ cameras, known for their expansive coverage, remote control features, and excellent optical zoom capabilities, have consistently proved to be ideal tools for modernizing traditionally large and challenging environments. Through an assortment of case studies, they aim to showcase how our technology has made a positive impact in various judiciary applications across the United States.
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Transforming Courtrooms with PTZ Technology In an age of technological advancement, courtrooms across the nation are embracing PTZ (pan, tilt, zoom) technology to revolutionize the legal experience. By integrating PTZ cameras, courtrooms are able to ensure comprehensive coverage of proceedings with minimal manpower. This not only enhances efficiency but also fosters greater accessibility and transparency. Whether live-streaming for remote viewing or archiving for future reference, PTZ technology is setting a new standard for justice in the digital era, aligning the judicial system with modern needs and expectations. |
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Fixed Cameras PTZOptics offers a range of fixed cameras called “ZCams” that provide a cost-effective solution for capturing high-quality video of specific areas within the courtroom. These cameras are designed to remain stationary while delivering excellent video coverage, making them ideal for recording proceedings, ensuring transparency, and maintaining a reliable video record without the need for frequent adjustments. |
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Manage Your Spaces Seamlessly with Hive
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With our courtroom management system, ensure that your IT and AV teams have the tools they need to keep the judicial process running smoothly and efficiently. Experience the peace of mind that comes with knowing you have complete control over your courtroom technology, all from a single, powerful interface.
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NDAA Compliance Select PTZOptics cameras comply with NDAA 2019, Section 889, ensuring they do not contain components from restricted companies. This compliance is crucial for organizations that prioritize security and adhere to federal regulations. For more information, please refer to the camera documentation. |
Courtroom Video Systems
PTZ cameras enable seamless communication within governmental agencies, from local meetings to global summits, fostering collaboration and decision-making. Learn how top local, state and federal court systems are upgrading their video systems.
Ensuring Transparency
With live streaming and video recording capabilities, PTZOptics empowers judiciaries to maintain transparency with their constituents. Our technology ensures that proceedings are accessible to the public, promoting trust, integrity, and responsiveness in public administration.
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Pioneering Courtroom Modernization In the pursuit of justice, adaptability, and accessibility, PTZOptics has been instrumental in modernizing courtroom video systems across the United States. Below is a remarkable case study that stands as a testament to our impact. |
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PTZOptics Cameras The city of Whitefish embraced PTZOptics cameras to redefine its courtroom experience. These state-of-the-art cameras, known for their expansive coverage and discreet in-room mounting locations, have provided a seamless and efficient solution to handle large spaces. This integration not only enhances functionality but also promotes greater accessibility to judicial proceedings. |
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PTZOptics cameras are often chosen for government applications such as courtrooms due to their large size. These spaces can benefit from the remote control and optical zoom features available on PTZOptics cameras. In this case study, the city of Whitefish, Montana approved the installation for four PTZOptics cameras to be used with a vMix video switching system. The cameras are installed in remote locations to the video production studio allowing a single camera operator to control the pan, tilt and zoom of each camera. Each camera is set up with camera presets that are assigned to various areas of interest inside the courtroom. |
PTZ Cameras For Legal Proceedings
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New York State Unified Court System’s Digital Transformation The New York State Unified Court System (NYS UCS), serving as the judicial branch of the state government, has embarked on an ambitious modernization journey to make its 1,540 courtrooms more functional, accessible, and equipped for the digital era. The Courtroom Modernization Initiative (CMI) Team was established in 2019 to actualize this vision; PTZOptics played a pivotal role in the transition along with other key vendors, such as Magewell and Biamp. |
Learn more about PTZOptics here:
Clever Polypane Debugging Features I’m Loving
I’m working on a refresh of my personal website, what I’m calling the HD remaster. Well, I wouldn’t call it a “full” redesign. I’m just cleaning things up, and Polypane is coming in clutch. I wrote about how much …
Clever Polypane Debugging Features I’m Loving originally…
MIT engineers create a chip-based tractor beam for biological particles
MIT researchers have developed a miniature, chip-based “tractor beam,” like the one that captures the Millennium Falcon in the film “Star Wars,” that could someday help biologists and clinicians study DNA, classify cells, and investigate the mechanisms of disease.
Small enough to fit in the palm of your hand, the device uses a beam of light emitted by a silicon-photonics chip to manipulate particles millimeters away from the chip surface. The light can penetrate the glass cover slips that protect samples used in biological experiments, enabling cells to remain in a sterile environment.
Traditional optical tweezers, which trap and manipulate particles using light, usually require bulky microscope setups, but chip-based optical tweezers could offer a more compact, mass manufacturable, broadly accessible, and high-throughput solution for optical manipulation in biological experiments.
However, other similar integrated optical tweezers can only capture and manipulate cells that are very close to or directly on the chip surface. This contaminates the chip and can stress the cells, limiting compatibility with standard biological experiments.
Using a system called an integrated optical phased array, the MIT researchers have developed a new modality for integrated optical tweezers that enables trapping and tweezing of cells more than a hundred times further away from the chip surface.
“This work opens up new possibilities for chip-based optical tweezers by enabling trapping and tweezing of cells at much larger distances than previously demonstrated. It’s exciting to think about the different applications that could be enabled by this technology,” says Jelena Notaros, the Robert J. Shillman Career Development Professor in Electrical Engineering and Computer Science (EECS), and a member of the Research Laboratory of Electronics.
Joining Notaros on the paper are lead author and EECS graduate student Tal Sneh; Sabrina Corsetti, an EECS graduate student; Milica Notaros PhD ’23; Kruthika Kikkeri PhD ’24; and Joel Voldman, the William R. Brody Professor of EECS. The research appears today in Nature Communications.
A new trapping modality
Optical traps and tweezers use a focused beam of light to capture and manipulate tiny particles. The forces exerted by the beam will pull microparticles toward the intensely focused light in the center, capturing them. By steering the beam of light, researchers can pull the microparticles along with it, enabling them to manipulate tiny objects using noncontact forces.
However, optical tweezers traditionally require a large microscope setup in a lab, as well as multiple devices to form and control light, which limits where and how they can be utilized.
“With silicon photonics, we can take this large, typically lab-scale system and integrate it onto a chip. This presents a great solution for biologists, since it provides them with optical trapping and tweezing functionality without the overhead of a complicated bulk-optical setup,” Notaros says.
But so far, chip-based optical tweezers have only been capable of emitting light very close to the chip surface, so these prior devices could only capture particles a few microns off the chip surface. Biological specimens are typically held in sterile environments using glass cover slips that are about 150 microns thick, so the only way to manipulate them with such a chip is to take the cells out and place them on its surface.
However, that leads to chip contamination. Every time a new experiment is done, the chip has to be thrown away and the cells need to be put onto a new chip.
To overcome these challenges, the MIT researchers developed a silicon photonics chip that emits a beam of light that focuses about 5 millimeters above its surface. This way, they can capture and manipulate biological particles that remain inside a sterile cover slip, protecting both the chip and particles from contamination.
Manipulating light
The researchers accomplish this using a system called an integrated optical phased array. This technology involves a series of microscale antennas fabricated on a chip using semiconductor manufacturing processes. By electronically controlling the optical signal emitted by each antenna, researchers can shape and steer the beam of light emitted by the chip.
Motivated by long-range applications like lidar, most prior integrated optical phased arrays weren’t designed to generate the tightly focused beams needed for optical tweezing. The MIT team discovered that, by creating specific phase patterns for each antenna, they could form an intensely focused beam of light, which can be used for optical trapping and tweezing millimeters from the chip’s surface.
“No one had created silicon-photonics-based optical tweezers capable of trapping microparticles over a millimeter-scale distance before. This is an improvement of several orders of magnitude higher compared to prior demonstrations,” says Notaros.
By varying the wavelength of the optical signal that powers the chip, the researchers could steer the focused beam over a range larger than a millimeter and with microscale accuracy.
To test their device, the researchers started by trying to capture and manipulate tiny polystyrene spheres. Once they succeeded, they moved on to trapping and tweezing cancer cells provided by the Voldman group.
“There were many unique challenges that came up in the process of applying silicon photonics to biophysics,” Sneh adds.
The researchers had to determine how to track the motion of sample particles in a semiautomated fashion, ascertain the proper trap strength to hold the particles in place, and effectively postprocess data, for instance.
In the end, they were able to show the first cell experiments with single-beam optical tweezers.
Building off these results, the team hopes to refine the system to enable an adjustable focal height for the beam of light. They also want to apply the device to different biological systems and use multiple trap sites at the same time to manipulate biological particles in more complex ways.
“This is a very creative and important paper in many ways,” says Ben Miller, Dean’s Professor of Dermatology and professor of biochemistry and biophysics at the University of Rochester, who was not involved with this work. “For one, given that silicon photonic chips can be made at low cost, it potentially democratizes optical tweezing experiments. That may sound like something that only would be of interest to a few scientists, but in reality having these systems widely available will allow us to study fundamental problems in single-cell biophysics in ways previously only available to a few labs given the high cost and complexity of the instrumentation. I can also imagine many applications where one of these devices (or possibly an array of them) could be used to improve the sensitivity of disease diagnostic.”
This research is funded by the National Science Foundation (NSF), an MIT Frederick and Barbara Cronin Fellowship, and the MIT Rolf G. Locher Endowed Fellowship.