Effect of Population Based Augmentation applied to images, which differs at different percentages into training.
In this blog post we introduce Population Based Augmentation (PBA), an
algorithm that quickly and efficiently learns a state-of-the-art approach to
augmenting data for neural network training. PBA matches the previous best
result on CIFAR and SVHN but uses one thousand times less
compute, enabling researchers and practitioners to effectively learn
new augmentation policies using a single workstation GPU. You can use PBA
broadly to improve deep learning performance on image recognition tasks.
We are in the midst of an unprecedented convergence of two rapidly growing
trends on our roadways: sharply increasing congestion and the deployment of
autonomous vehicles. Year after year, highways get slower and slower: famously,
China’s roadways were paralyzed by a two-week long traffic jam in 2010. At the
same time as congestion worsens, hundreds of thousands of semi-autonomous
vehicles (AVs), which are vehicles with automated distance and lane-keeping
capabilities, are being deployed on highways worldwide. The second trend offers
a perfect opportunity to alleviate the first. The current generation of AVs,
while very far from full autonomy, already hold a multitude of advantages over
human drivers that make them perfectly poised to tackle this congestion. Humans
are imperfect drivers: accelerating when we shouldn’t, braking aggressively,
and make short-sighted decisions, all of which creates and amplifies patterns
Communicating the goal of a task to another person is easy: we can use language, show them an image of the desired outcome, point them to a how-to video, or use some combination of all of these. On the other hand, specifying a task to a robot for reinforcement learning requires substantial effort. Most prior work that has applied deep reinforcement learning to real robots makes uses of specialized sensors to obtain rewards or studies tasks where the robot’s internal sensors can be used to measure reward. For example, using thermal cameras for tracking fluids, or purpose-built computer vision systems for tracking objects. Since such instrumentation needs to be done for any new task that we may wish to learn, it poses a significant bottleneck to widespread adoption of reinforcement learning for robotics, and precludes the use of these methods directly in open-world environments that lack this instrumentation.
We have developed an end-to-end method that allows robots to learn from a modest number of images that depict successful completion of a task, without any manual reward engineering. The robot initiates learning from this information alone (around 80 images), and occasionally queries a user for additional labels. In these queries, the robot shows the user an image and asks for a label to determine whether that image represents successful completion of the task or not. We require a small number of such queries (around 25-75), and using these queries, the robot is able to learn directly in the real world in 1-4 hours of interaction time, resulting in one of the most efficient real-world image-based robotic RL methods. We have open-sourced our implementation.
Our method allows us to solve a host of real world robotics problems from pixels in an end-to-end fashion without any hand-engineered reward functions.
Imagine a robot trying to learn how to stack blocks and push objects using
visual inputs from a camera feed. In order to minimize cost and safety
concerns, we want our robot to learn these skills with minimal interaction
time, but efficient learning from complex sensory inputs such as images is
difficult. This work introduces SOLAR, a
new model-based reinforcement learning (RL) method that can learn skills –
including manipulation tasks on a real Sawyer robot arm – directly from
visual inputs with under an hour of interaction. To our knowledge, SOLAR is the
most efficient RL method for solving real world image-based robotics tasks.
Our robot learns to stack a Lego block and push a mug onto a coaster with only
inputs from a camera pointed at the robot. Each task takes an hour or less of
interaction to learn.
One day, an ecologist came to us. He wanted to use modern computer vision
techniques to perform automatic animal identification in his wildlife camera
trap image datasets. We were so confident because it sounded just like a basic
image classification problem. However, we failed. The dataset he provided was
extremely long-tailed and open-ended. As usual, when we did not have enough
training data, we asked if it was possible to provide more data for the tail
classes and just ignore the open classes that might appear in the testing
dataset. Unfortunately, collecting more data was not the option. It could take
an extremely long time for these ecologists to take photos of rare and secluded
animals in the wild. For some endangered animals, they even had to wait for
years for one single shot. At the same time, new animal species kept coming in,
and old animal species kept leaving. The total class number was never fixed in
such a dynamic system. Moreover, the identification of rare and new animals has
more conservational values than abundant animals. If we could only do well on
the abundant classes, the method would never be practically usable. We tried
all possible methods we could think of (data augmentation, sampling techniques,
few-shot learning, imbalanced classification, etc.); but none of the existing
methods could handle abundant classes, scarce classes and open classes at the
same time (Fig. 1).
Figure 1: There exists a considerable gap between the existing computer vision
setting and the real-world scenario.
Figure 1: Our model-based meta reinforcement learning algorithm enables a
legged robot to adapt online in the face of an unexpected system
malfunction (note the broken front right leg).
Humans have the ability to seamlessly adapt to changes in their environments:
adults can learn to walk on crutches in just a few seconds, people can adapt
almost instantaneously to picking up an object that is unexpectedly heavy, and
children who can walk on flat ground can quickly adapt their gait to walk
uphill without having to relearn how to walk. This adaptation is critical for
functioning in the real world.
In many animals, tool-use skills emerge from a combination of observational
learning and experimentation. For example, by watching one another, chimpanzees
can learn how to use twigs to “fish” for insects. Similarly, capuchin
monkeys demonstrate the ability to wield sticks as sweeping tools to pull
food closer to themselves. While one might wonder whether these are just
illustrations of “monkey see, monkey do,” we believe these tool-use abilities
indicate a greater level of intelligence.
Left: A chimpanzee fishing for termites. Right: A gorilla using a stick to
gather herbs. (source)
The question our new work explores is: can we enable robots to use tools in the
same way — through observation and experimentation?
A requisite for performing complex multi-object manipulation tasks, such as
those involved in tool use, is an understanding of physical cause-and-effect
relationships. Therefore, the ability to predict how one object might
interact with another is crucial. Our prior work has investigated how
visual predictive models of cause-and-effect can be learned from unsupervised
robot interaction with the world. After learning such a model, the robot can
plan to accomplish a diverse set of simple tasks, including cloth folding and
object arrangement. However, if we consider the more complex interactions that
occur in tool-use tasks, such as how a broom can sweep dirt into a dustpan,
undirected experimentation isn’t enough.
Hence, taking inspiration from how animals learn, we designed an algorithm that
allows robots to learn tool-use skills through a similar paradigm of imitation
and interaction. In particular, we show that, with a mix of demonstration data
and unsupervised experience, a robot can use novel objects as tools and even
improvise tools in the absence of traditional ones. Further, depending on the
demands of the task, our method demonstrates the ability to decide whether to
use the provided tools. In this post, we will describe how this works.
We all dream of a future in which autonomous cars can drive us to every corner
of the world. Numerous researchers and companies are working day and night to
chase this dream by overcoming scientific and technological barriers. One of the
greatest challenges we still face is developing machine learning models that can
be trained in a local environment and also perform well in new, unseen
situations. For example, self-driving cars may utilize perception models to
recognize drivable areas from images. Companies in Silicon Valley can build and
perfect such a model using large local datasets from the Bay Area for training.
However, if the same model were deployed in a snowy area such as Boston, it
would likely perform miserably, because it has never seen snow before. Boston,
during winter, and Silicon Valley, during any time of the year, can be labeled
as separate domains for perception models, since they present clear differences
in climate and challenges in perception. In other cases, domains may be much
closer in nature, such as a city street and a nearby highway. The process of
transferring knowledge and models between different domains in machine learning
is called domain adaptation.
A large number of papers on domain adaptation of perception models have appeared
in top publishing venues for machine learning and computer vision. However, most
of these works focus on image classification and semantic segmentation. Hardly
any attention has been paid to instance-level tasks, such as object detection
and tracking, even though localization of nearby objects is arguably more
important for autonomous driving. To foster the study of domain adaptation of
perception models, Berkeley
DeepDrive and Didi Chuxing are
co-hosting two competitions in CVPR 2019 Workshop on
Autonomous Driving. The challenges will focus on domain adaptation of object
detection and tracking based on the BDD100K, from Berkeley DeepDrive, and
D2-City, from Didi Chuxing, datasets. The domain of BDD100K covers US
scenes, while D2-City was collected on China’s streets. The
competitions ask participants to transfer object detectors from BDD100K to
D2-City and object trackers from D2-city to BDD100K. More
information about the challenges can be found on our website and D2-City.
Following our introduction of the BDD100K dataset, we have been busy working to
provide more temporal annotations. Above is an example of object tracking
annotation, created by our open-source annotation platform Scalabel. Some of the tracking labels are
used in the domain adaptation challenge for object tracking. More data will be
released this summer. Of course, we also have object tracking at night.
The University of California Berkeley Artificial Intelligence Research (BAIR)
Lab is pleased to announce the BAIR Open Research Commons, a new industrial
affiliate program launched to accelerate cutting-edge AI research. AI research
is advancing rapidly in both university and corporate research settings, with
existing collaborations already underway driven by individual
researcher-to-researcher collaborations. The BAIR Commons is designed to enhance
and streamline such collaborative cutting-edge research by students, faculty,
and corporate research scholars.
The Commons agreement has been framed with the goal of promoting open research
in AI: all on-campus effort, data, and results in the Commons program will be
non-exclusive with open publication and open-source code release expected.
Fostering an environment for excellence for graduate student research is the
primary motivation of the new program: Berkeley students will lead the design of
projects in the Commons, and the program of research must be approved by their
home departments before a project commences. Students are expected to benefit
from collaboration with leading researchers in industrial research labs, as well
as the availability of partner resources useful to investigate certain open
questions in state-of-the-art AI research. The University will benefit from
membership fees paid by partners to participate in the program. The Commons
agreement provides for collaborative joint projects between the partners and
Berkeley, with intellectual property shared jointly and equally by the parties.
The agreement also provides for joint research “lablets”, which will be embedded
collaborative open research spaces inside BAIR’s 27,000 sq. ft. research
facility opening this summer in the Berkeley Way West facility on the Berkeley
campus. More than a dozen faculty and 120 students will be assigned space in
the new lab, with an equal number of visiting positions allocated for
researchers from other BAIR labs and for visiting industrial partners.
Initial alliance participants include Amazon, Facebook, Google, Samsung, and
Wave Computing. Funding for over twenty joint projects has been committed in the
initial launch of the program, which will support both BAIR facilities and
research efforts. Over 30 faculty and 200 graduate students and postdocs at
Berkeley are affiliated with BAIR. For more information about BAIR or the
Commons program please contact email@example.com.
BAIR will occupy the top floor of Berkeley Way West.
Guiding our fingers while typing, enabling us to nimbly strike a matchstick, and
inserting a key in a keyhole all rely on our sense of touch. It has been
shown that the sense of touch is
very important for dexterous manipulation in humans. Similarly, for many robotic
manipulation tasks, vision alone may not be
often, it may be difficult to resolve subtle details such as the exact position
of an edge, shear forces or surface textures at points of contact, and robotic
arms and fingers can block the line of sight between a camera and its quarry.
Augmenting robots with this crucial sense, however, remains a challenging task.
Our goal is to provide a framework for learning how to perform tactile servoing,
which means precisely relocating an object based on tactile information. To
provide our robot with tactile feedback, we utilize a custom-built tactile
sensor, based on similar principles as the GelSight
sensor developed at MIT. The sensor is
composed of a deformable, elastomer-based gel, backlit by three colored LEDs,
and provides high-resolution RGB images of contact at the gel surface. Compared
to other sensors, this tactile sensor sensor naturally provides geometric
information in the form of rich visual information from which attributes such as
force can be inferred. Previous work using similar sensors has leveraged the
this kind of tactile sensor on tasks such as learning how to
success rates when grasping a variety of objects.