Physical Electronics Seminar : Building blocks for nanoscale magnetic resonance imaging

סמינר שמיעה לתלמידי תואר שני ושלישי

14 בנובמבר 2024, 11:00 
Room 011 Kitot Building  
Physical Electronics Seminar : Building blocks for nanoscale magnetic resonance imaging

 

  -סמינר זה יחשב כסמינר שמיעה לתלמידי תואר שני ושלישי-  This Seminar Is Considered A Hearing Seminar For Msc/Phd Students-

 

 

ברכת דקאן הפקולטה להנדסה וסגן הדקאן להוראה ולתלמידים לסטודנטיות ולסטודנטים לקראת פתיחת שנה"ל תשפ"ה:  עברית

 

ברכת דקאן הפקולטה להנדסה וסגן הדקאן להוראה ולתלמידים לסטודנטיות ולסטודנטים לקראת פתיחת שנה"ל תשפ"ה:   אנגלית

 

ברכת דקאן הפקולטה להנדסה וסגן הדקאן להוראה ולתלמידים לסטודנטיות ולסטודנטים לקראת פתיחת שנה"ל תשפ"ה:  ערבית

 

פרופ' אריה ירדאור. סגן דקאן

EE Seminar: HydroNeRF: NeRF for Scenes with Air and Water

13 בנובמבר 2024, 15:30 
אולם 011  
EE Seminar: HydroNeRF: NeRF for Scenes with Air and Water

Electrical Engineering Systems Seminar

 

Speaker: Osher Stamker

M.Sc. student under the supervision of Prof. Shai Avidan & Prof. Alex Liberzon

 

Wednesday, 13th November 2024, at 15:30

Room 011, Kitot Building, Faculty of Engineering

HydroNeRF: NeRF for Scenes with Air and Water

 

Abstract

Neural Radiance Fields (NeRF) revolutionized the field of view synthesis by providing high-quality, photorealistic novel views from unstructured image collections. As a side benefit, it is possible to measure geometric properties in the scene (such as distances between 3D points) based on a depth map that is extracted from NeRF.

However, NeRF models struggle with complex light interactions, such as reflections and refractions, often resulting in inaccurate renderings. Going beyond view synthesis, accurate 3D measurements of objects submerged in liquid is also important for fluid mechanics.

In this work, we introduce HydroNeRF, an enhanced NeRF framework designed to accurately model light refraction and handle reflective scenes. Our approach leverages Snell's law to model the bending of light rays as they transition between different media (air, glass, water), and integrates a Deformation Network to render the scene.

We collected a dataset of challenging scenes that contain objects submerged in water tanks and show that HydroNeRF can be used to measure distances between 3D points more accurately than NeRF.

 

השתתפות בסמינר תיתן קרדיט שמיעה = עפ"י רישום שם מלא + מספר ת.ז. בדף הנוכחות שיועבר באולם במהלך הסמינר

 

 

 

 

EE Seminar: Is There a Needle in the Haystack

13 בנובמבר 2024, 15:00 
אולם 011  
EE Seminar: Is There a Needle in the Haystack

Electrical Engineering Systems Seminar

 

Speaker: Shoval Mishal

M.Sc. student under the supervision of Prof. Shai Avidan

 

Wednesday, 13th November 2024, at 15:00

Room 011, Kitot Building, Faculty of Engineering

Is There a Needle in the Haystack?

Abstract

We are interested in detecting the existence of novel object classes in aerial images, without specifying these novel classes ahead of time.

In our setting, we are equipped with a detector capable of detecting a closed set of objects (e.g., vehicles, planes) but wish to determine if other, unspecified, object classes, that are of interest (say, ships), appear in the images as well. This open vocabulary problem poses two challenges. The first is scale, as there are tens of millions of patches to evaluate. The second is vagueness. How do you determine whether a given patch contains a semantically meaningful object of interest or just an interesting background pattern?

To address these challenges, we propose a funnel approach that gradually reduces the number of patches of interest from tens of millions to a short list of few tens of thousands. The patches in the short list are ranked automatically and shown to a human operator. We therefore measure performance by ``Time-To-1st(TT-1), i.e. the time it takes a human to find the first instance of interesting new classes in aerial images, and show we are capable of producing such a sample within the first few patches. Our code will be made publicly available.

 

השתתפות בסמינר תיתן קרדיט שמיעה = עפ"י רישום שם מלא + מספר ת.ז. בדף הנוכחות שיועבר באולם במהלך הסמינר

 

 

 

טפסים רלוונטים: 

 

 

Physical Electronics Seminar Recording and analyzing high resolution electrophysiological data from freely behaving humans

סמינר שמיעה לתלמידי תואר שני ושלישי

07 בנובמבר 2024, 11:00 
Room 011 Kitot Building  
Physical Electronics Seminar Recording and analyzing high resolution electrophysiological data from freely behaving humans

 

  -סמינר זה יחשב כסמינר שמיעה לתלמידי תואר שני ושלישי-  This Seminar Is Considered A Hearing Seminar For Msc/Phd Students-

 

 

LMI Seminar: Atomic arrays as programmable quantum processors and sensors

06 בנובמבר 2024, 13:00 
הפקולטה להנדסה אוניברסיטת תל אביב, בנין כיתות ,אולם 011  
LMI Seminar: Atomic arrays as programmable quantum processors and sensors

 

חלוקת פרסי מכון וינשטין לשנת תשפ"ד

30 באוקטובר 2024, 16:45 
אולם 001 בנין ברודקום  
חלוקת פרסי מכון וינשטין לשנת תשפ"ד

 

 

 

 

 
 

 

 

 

 

 

 

 

 

 

EE Seminar: Camera Spoofing via the in-Vehicle IP Network

27 בנובמבר 2024, 15:00 
אולם 011  
EE Seminar: Camera Spoofing via the in-Vehicle IP Network

Electrical Engineering Systems Seminar

 

Speaker: Dror Peri

M.Sc. student under the supervision of Prof. Avishai Wool

 

Wednesday, 27th November 2024, at 15:00

Room 011, Kitot Building, Faculty of Engineering

Camera Spoofing via the in-Vehicle IP Network

 

Abstract

Autonomous driving and advanced driver assistance systems (ADAS) rely on cameras to control driving. In many prior approaches an attacker aiming to stop the vehicle had to send messages on the specialized and better-defended CAN bus. We suggest an easier alternative: manipulate the IP-based network communication between the camera and the ADAS logic, inject fake images of stop signs or red lights into the video stream, and let the ADAS stop the car safely. We created such an attack tool that successfully exploits the GigE Vision protocol.

Then we analyze two classes of passive anomaly detectors to identify such attacks: protocol-based detectors and video-based detectors. We implemented multiple detectors of both classes and evaluated them on data collected from our test vehicle and on data from the public BDD corpus. Our results show that such detectors are effective against naive adversaries, but sophisticated adversaries can evade detection.

Finally, we propose a novel class of active defense mechanisms that randomly adjust camera parameters during the video transmission and verify that the received images obey the requested adjustments. Within this class we focus on a specific implementation, the width-varying defense, which randomly modifies the width of every frame. Beyond its function as an anomaly detector, this defense is also a protective measure against certain attacks: by distorting injected image patches it prevents their recognition by the ADAS logic. We demonstrate the effectiveness of the width-varying defense through theoretical analysis and by an extensive evaluation of several types of attack in a wide range of realistic road driving conditions. The best the attack was able to achieve against this defense was injecting a stop sign for a duration of 0.2 seconds, with a success probability of 0.2%, whereas stopping a vehicle requires about 2.5 seconds.

 

דןעהשתתפות בסמינר תיתן קרדיט שמיעה = עפ"י רישום שם מלא + מספר ת.ז. בדף הנוכחות שיועבר באולם במהלך הסמינר

 

 

 

 

 
 

 

 

 

 

 

 

 

 

 

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