Microsoft Research Podcast - 072r - AI for Earth with Dr. Lucas Joppa
Episode Date: April 22, 2020This episode originally aired in April, 2019. We hear a lot these days about “AI for good” and the efforts of many companies to harness the power of artificial intelligence to solve some of our bi...ggest environmental challenges. It’s rare, however, that you find a company willing to bring its environmental bona fides all the way to the C Suite. Well, meet Dr. Lucas Joppa. A former environmental and computer science researcher at MSR who was tapped in 2017 to become the company’s first Chief Environmental Scientist, Dr. Joppa is now the Chief Environmental Officer at Microsoft, another first, and is responsible for managing the company’s overall environmental sustainability efforts from operations to policy to technology. Today, Dr. Joppa shares how his love for nature and the joy of discovery actually helped shape his career path, and tells us all about AI for Earth, a multi-year, multi-million dollar initiative to deploy the full scale of Microsoft’s products, policies and partnerships across four key areas of agriculture, water, biodiversity and climate, and transform the way society monitors, models, and ultimately manages Earth’s natural resources.
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When Dr. Lucas Joppa was on the podcast a year ago,
he talked about Microsoft's commitment to the environment,
including AI for Earth,
one of the company's efforts to put AI to work for good.
Since then, Microsoft has taken its efforts even further,
with an announcement in January 2020
to be carbon negative by 2030.
Whether you heard Lucas last Earth Day,
or you're just learning what AI can do for the planet today,
I know you'll enjoy Episode 72 of the Microsoft Research Podcast, AI for Earth.
We've been investing in the AI for Earth space from a peer research perspective for almost a
decade. And it was really when Microsoft started to go all in in AI that there was a conversation
saying, look, we've been investing in this for 10 years.
Isn't now the time?
If not now, then when?
And so I put together a memo called AI for Earth, which is how we could take this out
of research, take this out of incubation, deploy it across the entire company, and then
allow the full kind of scope and scale of a Microsoft to put that in the hands of partner organizations all around the world.
You're listening to the Microsoft Research Podcast,
a show that brings you closer to the cutting edge of technology research
and the scientists behind it.
I'm your host, Gretchen Huizenga.
We hear a lot these days about AI for good and the efforts of many companies to harness the power of artificial intelligence to solve some of our biggest environmental challenges.
It's rare, however, that you find a company willing to bring its environmental bona fides
all the way to this eSuite. We'll meet Dr. Lucas Joppa, a former environmental and computer science researcher at
MSR who was tapped in 2017 to become the company's first chief environmental scientist. Dr. Joppa is
now the chief environmental officer at Microsoft, another first, and is responsible for managing the
company's overall environmental sustainability efforts from operations to policy to technology. Today, Dr. Joppa shares how his
love for nature and the joy of discovery actually helped shape his career path, and tells us all
about AI for Earth, a multi-year, multi-million dollar initiative to deploy the full scale of
Microsoft's products, policies, and partnerships across four key areas of agriculture, water, biodiversity,
and climate, and transform the way society monitors, models, and ultimately manages Earth's
natural resources.
That and much more on this episode of the Microsoft Research Podcast. Lucas Joppa, welcome to the podcast.
Thanks for having me here.
You're the chief environmental officer at Microsoft. First off, does anyone else have that? Or is that unique to this company?
I think to the best of my knowledge, it's unique to this company. I actually came from a role that was unique to this company as well.
So before I was the chief environmental officer, I was the chief environmental scientist.
And as a former Microsoft researcher, I always told myself I didn't want a job that didn't
have the word scientist in it.
But as long as I kept environment in the chief environmental officer, then I'm good.
There are companies that have, you know, chief sustainability officers and things like that, but those generally have a much more narrow purview to them than the role that I currently have.
Perhaps within the company and the sustainability practices of the company or?
I think, you know, a traditional chief sustainability officer really thinks about sustainability within the four walls of an organization.
How do you reduce the negative environmental impact of an
organization's business practices? And I think that that is a very important aspect of the role.
I call it a wholly necessary but entirely insufficient criterion for success in the
environmental space. Microsoft's 130,000 employees or so, and that's pretty small if you look at the
seven plus billion people in the world. So
we've got to think about how we take our products, our policies, our partnerships, and use those to
really expand our impact all around the world. We're a tech company. We're obsessed with scale,
right? That's what we need to be seeking with sustainability as well.
Your title is kind of a spoiler alert to what kind of big problems you're looking to solve. And I usually ask that kind of off the bat.
But give us a virtual Earth 3D view of the work you do.
What gets you up in the morning?
Ultimately, at the highest level, what gets me up in the morning is the same thing that always has as far back as I can remember,
which is just this like kind of incredible sense of wonder about the world.
I think, you know, I've just always seen
my place in the cosmos and on the planet is this tiny infinitesimal speck and just, you know,
I've been fascinated by what else is out there. And as I started to think about that more, you
know, some people are super interested in what's up there up in the sky, right? In outer space.
I was always interested in what's here at home on planet Earth. And then, of course,
what's the human species role in that? What impact are we having? How much of that life have we
discovered? That's what intrinsically gets me up. I think the thing that then gets me out of bed and
gets me to work every day is what can we do to extend our knowledge base? How can we go out and
actually accelerate human discovery of the rest of life on Earth? And then how can we do to extend our knowledge base? How can we go out and actually accelerate human discovery
of the rest of life on Earth? And then how can we use some of our tools and our science to
mitigate the impact of our own human activities on Earth's natural systems? Because that last bit,
that worry about human impact, that's actually kind of what keeps me up at night.
Part of what drives the work of researchers and the people who work with them to bring their efforts to life is what we don't know, that quest for discovery, the quest for knowledge. So what are the big knowledge gaps in environmental science and how is computer science helping to narrow those gaps just general right now? Sure. I think, you know, if you want to couch it in the framing of the big
problem that we have right now is that human society is ultimately facing probably the greatest
challenge human society has ever faced. What I mean by that is we somehow have to figure out how to
adapt to and mitigate changing climates, ensure resilient water supplies, sustainably feed a human
population currently at seven, growing to 10 billion people, all while stemming a catastrophic changing climates, ensure resilient water supplies, sustainably feed a human population
currently at seven, growing to 10 billion people, all while stemming a catastrophic
loss of biodiversity that's going on.
And so what you have to do is you have to know about all of our systems, how we use
those systems to sustain our human activities, and then of course, how we can mitigate and
manage those systems to accelerate human activities. And then, of course, how we can mitigate and manage those systems to accelerate
human progress. I think just one little example that I spent a lot of time on earlier in my
research career is just looking at, for instance, the number of species on Earth. Actually, we've
only scientifically discovered something like 2 million species, scientists estimate it's probably something like 10, 15 million. We've only even discovered something like 20% at best of life on Earth. And of that,
you know, if you look at what we actually know, a lot of that discovery is just kind of a specimen
in a drawer with, you know, a Latin name written on it. If you look at like how many of those
species have we actually kind of studied and we
understand their populations, how their populations are faring, done kind of a full conservation
assessment for any particular species. We've done that for about 100,000 species of the potentially
10 million or more that are out there. And so, you know, we live in this world where
you can just ask your phone
how to get to the nearest Starbucks and it's got to run a least cost path algorithm to find out,
is it shorter to go 20 steps to the right or 30 steps to the left to get to the nearest one?
That's kind of our day-to-day problems. But when you take a step back and you ask
the human position within the rest of life on earth, I mean, we talk about an information age and, you know, information overload.
Well, it comes to our understanding of environmental systems.
It's a complete and total information drought. Well, let's plunge in right away and talk about AI for Earth, which is a pivotal program
and one that you're spearheading here at Microsoft.
The program was launched in 2017, and at the time they said it's a five-year, $50 million
cross-company effort to deploy the
full scale of Microsoft's AI technologies, capabilities, research in four key areas.
So let's start macro, and then we'll get micro in a bit. First, give us an overview of AI for
Earth, why it exists, and what its core areas of focus are. Fundamentally, AI for Earth exists
to change the way that human
society monitors models and ultimately manages Earth's natural systems. That's what we're trying
to do. We're trying to take a technology focus on doing that. Now, when you think about the scope
and the scale of the problem, how big Earth is, how few people there are for such a huge sphere, and how many species there are,
and how many complex relationships. You realize that we need to find scalable mechanisms to
monitoring and modeling earth's natural systems. And when you're embedded inside the tech sector,
as I've been inside the research arm of a company like Microsoft, you realize just how
rapid and incredible the progress we're making in collecting data, analyzing data, delivering
insights to users. And so it just, for me, became clear that Microsoft should be focusing its
attention in that space on environmental systems and that we should really focus on
agriculture, water, biodiversity, and climate change.
Those four issues are inseparable from each other, by the way.
I mean, obviously, you need water to grow crops and you need species to pollinate crops
and you need predictable climates to be able to plant crops predictably.
And so those all kind of bundle together under that higher rubric of
AI for Earth and this five-year, $50 million commitment to deploying Microsoft's 35 years now
of research investments in the key areas of artificial intelligence.
Talk a little bit more about this idea of five years, because it's not five years.
Explain what you mean by that.
Sure. I mean, you know, anybody that works in the tech sector understands that five years? Because it's not five years. Explain what you mean by that. Sure. I mean, you know, anybody that works in the tech sector understands that five years is
actually a geological age, right? Five years is about as far into the future as we can possibly
imagine. If you look at the research to product to deployment cycle that's going on right now,
you quickly understand that a five-year commitment in the tech sector means that you're committing to deploying technologies out into a particular space, in our case, environmental sustainability, technologies
that haven't even been invented yet. I mean, in some cases, maybe technologies that haven't even
been dreamed of yet. And so for me, five years just is really something so far off in the horizon
that it's kind of a statement of saying,
as long as we can imagine doing tech, we imagine doing tech for nature, right? The $50 million part is important, of course, but it's way more than that because of all the other resources that come
across Microsoft. And what was really interesting is everyone talks about the $50 million five-year
commitment, but nobody talks about how we kind of launched it
with a much smaller commitment.
We launched it with a $2 million commitment
about five months prior to the main announcement.
And this is what I love about the tech sector in general,
Microsoft in particular.
We launched it with a $2 million investment
just to kind of see what the demand was.
The demand was overwhelming.
Right.
And we were able to scale to meet it as quickly as we saw it. I think that for me just kind of
blew my mind about the power of a large organization. You can put something out in
the market, you can see market response, market demand, and you can just immediately rise up and
meet it. I'd been in Microsoft Research leading research programs at the
intersection of environmental and computer science. That's another thing. We've been
investing in this space, in the AI for Earth space, from a peer research perspective for almost a
decade. And it was really when Microsoft, from a corporate level, really started to go all in in
AI that there was a conversation about, just like every technology that we incubate inside Microsoft Research,
there's a question about the human tech transfer for me of saying,
look, we've been investing in this for 10 years. Isn't now the time? If not now, then when?
And so I put together a memo called AI for Earth, which is how we could take this out of research,
take this out of incubation, deploy it across the entire company, and then allow the full kind of scope and scale of a Microsoft to put that in the hands of partner organizations countries around the world, 38 or so states in the United States.
For me, it's kind of the program equivalent of seeing some feature that you develop deployed
in software that's used by a billion people, right? You know, just to see that incredible
growth. And that's because of the 35 years of investment that we've been putting in this
space.
Well, we talked about four areas of focus, and I'd like to switch over and talk about the
three what you call pillars of support for the program. Tell us about the pillars of this program.
How did you decide on them? Why are they important? So AI for Earth from its very beginnings had
three pillars, and those pillars are super purposeful. And they were put in place as the result of years of work in this area of
recognition of what the difficulties are. And the pillars are simply access, education,
and co-innovation. And what I mean by that is, from an access perspective, is that most
organizations that work on environmental topics aren't the large enterprise customers of the world.
They're the small, scrappy nonprofits, the chronically underfunded government agencies,
the academics, the small kind of social good startups. And these are organizations where
resources are incredibly tight. And they often just don't have the ability to get out ahead
on kind of the digital transformation journey that they would like to because they just don't
have that little bit of excess capital that they would need to crystallize the process.
And so for me, the number one thing going into AI for Earth was just this recognition that budget
simply cannot be a barrier to people using our
tech for environmental sustainability. And so the significant aspect of our budget of that $50
million is just to ensure that budget isn't a barrier, that anybody who's taking kind of a
machine learning or AI-first approach to solving environmental sustainability challenges in the
four areas of ag, water, biodiversity, or climate climate we want to get our tech in their hands that's great but it ignores the fact that also while resources are short most
of those places doing the best work their employees didn't graduate from the world's leading computer
science departments their employees graduated from the world's leading environmental science
departments often some of our best tech still requires a minor
in computer science to use fully effectively, you know. And so we immediately recognized that just
putting tech in people's hands that don't know how to use it is kind of a fool's errand. You've
got to ensure that you follow that up with educational curricula and community building.
And so we started putting together things like AI for Earth education summits, bringing grantees from all over the world together, both in person and digitally.
We've got some fantastic top technical talent on the team that also leads that education effort.
And so engineering is an absent from education. And then the last bit is just simply a recognition of reality, which is that the tech sector has a lot of the tech talent
and that human skill and capacity. We need to be able to put that into play as well.
The thing is, we know a lot about tech and a little bit about the environment.
Our partners know a whole lot about the environment and a little bit about tech. And that intersection there is where innovation actually happens,
right? It's not just collaboration. Collaboration is just like, hey, me helping you get something
done or vice versa, right? But this idea that there's something that comes out of it that's
greater than the sum of its parts, that's what innovation for me means. And so we looked across
and those were the three pillars. Obviously, there's always more to do, but...
AI for Earth writ large has several specific projects within that really flesh out how this
impacts the real world. Tell us about these. It's a lot to cover, but maybe a brief overview of each
would just give our listeners sort of the basis for where you're heading with this.
Sylvia Terra is a big one.
Yeah, Sylvia Terra is a fantastic organization. Sylvia Terra is actually the name of the basis for where you're heading with this. Sylvia Terra is a big one. Yeah, Sylvia Terra is a fantastic organization. Sylvia Terra is actually the name of the
company, not just the project. And what they're really looking to do is to provide a species
level tree count product across the entire United States. And this is super important because
when you think about climate change mitigation or land conservation, you have to know what is where, how much is there, and how fast is it changing.
And we fundamentally don't know that information about Earth's natural resources or the natural
resources of the United States.
Sylvia Terra is using high-resolution satellite and aerial imagery and convolutional deep
neural networks to be able to build up that data product from
looking down, train up models that are able to assess not just is there a tree there or not,
but what species of tree that is, how big that tree is, what its carbon potential,
et cetera, et cetera, that really is allowing people to have kind of an unprecedented view
into the state of their local forests. And Sylvia Terra's work on single
tree species counting and identification is just kind of a subset of a larger problem that
some of my research colleagues and I here in MSR have been tackling over the past couple of years,
which is trying to build a land cover product. So not just where are the trees, but where are
the forests, the fields,
the built in urban environments, the creeks and the streams and the lakes, all of that so that
you can look down and not just say, oh, that pixel is red or green or blue or looks like a tree,
but we can bring all that together for the United States at a one meter resolution.
That's something like 10 trillion pixels that you need to count up. And it's a really hard computer science problem as well. And so building up things like a forest map of species, a national land cover map, all of these sorts of things start to get you lot of questions, it's kind of from looking down at the world and satellite imagery and the size of these data sets.
You know, we're talking about just petabytes and petabytes and petabytes of data flowing down.
And so you've got to store those data.
You've got to be able to get them into memory really quick.
You know, you've got to be able to train up algorithms really efficiently.
And then you've got to be able to do evaluation or deploy those algorithms over even larger amounts of data.
It's a super non-trivial task.
Getting those data labeled, I mean, is just a problem in and of itself.
And so, you know, when people ask why environment, I mean, even if you didn't care about an environment, from a computer science perspective, these are some of the hardest problems out there. Talk a little bit, give a nod to FarmBeats and Project Premonition,
because those are two really cool things that are going on. I've watched those projects,
FarmBeats and Project Premonition, grow from ideas to what they are right now. I mean,
FarmBeats, an incredible sensor and data fusion project that's really looking to revolutionize the way that farmers collect data about their field and make harvesting and growing decisions based on extremely new advances in artificial intelligence, bringing that all together.
I mean, it's kind of crazy to see the result of some of these projects because ultimately it kind of distills down to some graphs on a browser dashboard.
Right.
And what that hides is just the incredible amount of engineering of actual physical electronic sensors in the field, communicating over really novel communication pathways like TV white space, which Ron Veer is such an incredible kind of advocate and proponent for,
bringing that into centralized on-prem compute centers, figuring out what matters, what needs bigger compute, doing all of that kind of local intelligence processing, sending up information
and data sets to our larger compute clusters in the cloud, and ultimately just allowing somebody
to come click and see what's going on out in their field just
from, you know, balloons floating in the air, drones flying around and sensors out there.
It's kind of incredible. And Ethan, another fantastic researcher in Microsoft Research,
he's really interested in how we monitor the biosphere, as he would say. And his kind of path into it is through understanding that we have a scale problem.
He originally started out wanting to understand diseases and how we can prevent epidemics with
this perspective that epidemics are so catastrophic because we don't see them coming. And they often
come from our unbuilt natural environments. And they're housed by the rest of life on Earth.
And so if you want to go out and sample that, well, you need to take a technology approach.
But still, tech isn't going to allow you to sample every animal on the planet everywhere.
But he had the same simple idea that many have had before him,
which is that evolution has already provided these data samplers in the form of biting insects,
mosquitoes, and their kind of devilish ilk, right?
And so the question is, well, how do you insert yourself in that data sampling process?
If you're a metagenomicist, you see mosquitoes and the blood samples they collect is simply roaming data collectors.
So now you need to figure out how to collect those data. And the engineering that Ethan and his team have put together in building these
entirely new next generation mosquito traps that are running machine learning algorithms on board
that can do species level recognition from wing beat frequency patterns, decide which species they
want to collect, and then pipe those into a full metagenomics compute engine that again spits out
some graphs and information about what diseases
and other species might be out in that environment. You know, the scope and the scale, it's, you know,
somebody who speaks about these a lot. One of the things that I really struggle to get across,
it seems just this horrible disservice to this entire legacy of research and innovation that goes into providing
something so simple and so powerful that people just don't see everything that goes behind it.
Right. And I think that's kind of one of the cool things about the digital transformation
that the world's undergoing is all of the incredibly useful applications that we have in our lives that make our lives lighter,
but are powered by things that most people will never be capable of truly kind of grokking,
you know, the scope and the scale of work that goes into this stuff.
I love that you said the word grok. It's one of my favorite words. Such a sci-fi word.
That's right.
I think we get why the earth part of this program is important, but let's talk a bit
more about the AI part.
What does AI do for the earth that we can't?
I think we've framed this in a previous conversation as an efficiency story, but agreed that that
doesn't quite do it justice.
Yeah, I mean, I think the way I look at it is like,
ultimately, we've got this massive scale problem on the size of the earth, the amount of living
organisms on earth, the complexity of the relationships. So there's this massive scale
problem. How do we scale? And then we have a resource problem, which is that the organizations
that focus on this, for better or worse, aren't necessarily the most well-resourced organizations in the world. And so where has tech always had a transformative impact? It's in the efficiency story. And what is efficiency? Well, efficiency allows you to either do the same for less or do more for the same. And maybe in the enterprise space when you're worrying about margins and quarterly profits,
you're really interested in doing at the very least the same for less and maybe even more
for less.
But when you're interested in understanding the rest of life on earth, when you're interested
in collecting data about natural systems and building models about them, and you're wildly
resource constrained, the question you're wildly resource-constrained,
the question you're asking yourself every day is,
how do I do orders of magnitude more for the same?
And technology allows you to do that.
One nice story from a partner organization
between the AI for Earth program, Microsoft Research,
and a small nonprofit called the Chesapeake Bay Conservancy.
This is that land cover mapping project.
And, you know, we had this ambition to build a one meter resolution land cover map for
the entire United States.
That's plowing through something like 10 trillion pixels, 25, 30 terabytes of data.
And that was an aspiration shared with this small 19 person nonprofit called Chesapeake
Bay Conservancy.
And they were way out ahead of us, mind you, because they actually had done stuff and we just thought about it. And what they had
done was they had built a one-meter resolution land cover map for the Chesapeake Bay watershed,
which is just a small fraction of the United States. But it had taken them well over a million
dollars and over a year and a half just to produce that one data product.
And so that meant that by the time they got done, they were almost already out of date,
right? And so we came in, we said, hey, look, you know, the way you're doing that, we think that there's a better way. It turned out to be really hard. It's led to some top papers and,
you know, leading conferences like CVPR and ICLR. And, you know, we've made some significant
machine learning progress as well. But ultimately, we still have a long way to go on our algorithmic kind of accuracy
side of things. But from just a pure infrastructure perspective, we're able to
train up an algorithm and deploy it on a cluster of 800 FPGAs, so field programmable gate arrays,
which is some really cool architecture that we've been shipping all across Azure, and plow through all 10 trillion pixels. So go from the Chesapeake Bay to the entire United
States, 25 terabytes of data, 10 trillion pixels, 10 minutes, $42. So that gets to how do I do more
for the same, or in this case, way more for way less.
And so that's just the efficiency story.
How do you give an individual or a small organization superpowers? You either give them a huge check or you give them technology. Several researchers on the pod have talked about this idea of humans in the loop.
And it kind of speaks to the fact that technology isn't taking us over.
It still needs us if we personify it.
But you've turned that on its head a little bit. Talk to me
about your take on who's in the loop and how and why. Yeah, I mean, I think what's kind of funny
is, you know, researchers are always so far out ahead that they started talking about humans in
the loop probably two decades before it was relevant. They were talking about humans in the
loop when we were still trying to figure out how to put algorithms in the loop, right? Where we were doing most of it, but algorithms
were just kind of helping. I think where a lot of the worry is coming from an AI and ethics
perspective or anything else is around what the future might hold when we need to purposefully
build humans into the loop so that we have these spot checks and balances and things like that. So
I still think we completely
live in a world where it's algorithms in the loop of human activity, algorithms in the loop of human
life. That's the world I want to live in. I don't want to live in a world where it's humans in the
loop as if I'm some sort of secondary citizen to addendum to this digital substrate that I'm just,
you know, allowed to exist in. You know, it's kind of a corollary to something else that just frustrates me all the time,
which is that so many of the things that we don't know about are things that we ourselves have built.
So ask me where all the world's dams are.
I don't know.
Ask me where all the world's roads are.
We built these things and we don't even know where they are with
the state of them. And so when you get back to this whole human in the loop concept, I fundamentally
have a problem with imagining a future where I'm an addendum to something that we built.
And just to prove how far off I think we are from that is that the things we built, as I said,
like are kind of addendums in our lives still. And I think we'd from that is that the things we built, as I said, like are kind of
addendums in our lives still. And I think we'd be much better focused in figuring out how to put
algorithms in the loop to help us understand what we've built, the impact that it's having on
environmental and social systems and to build our societies around that. And that's going to be
really important as we start to ask algorithms what we
should do about managing Earth's natural systems. Where should we put renewable versus non-renewable
energy? Where should we put high-density urban growth centers versus protected areas and national
parks? Where should we do, you know, any number of things? Well, we don't know enough about our own biology to tell an algorithm how we'd make that decision. And to me, then I'm going to continue to interrogate it with human systems. And I'm going to take it one step at a time. But that's just my opinion. But we've hit the worry part of the podcast. This is where I ask the guests, what keeps you up at night? And aside from all the concerns about conservation and stewardship of our planet, you're developing and deploying some incredibly powerful technologies in which we're putting a lot of trust both what could possibly go wrong and that we won't do it fast enough.
My former manager and longtime mentor, Eric Horvitz, who leads Microsoft Research,
you know, he has a long history in the health space at the intersection of health and medicine
and machine learning. And one of the things that he consistently says is people worry about
the issues of algorithms in these loops,
and that's completely valid and understandable, but what's the human cost of not doing it?
I think that same thing is true in the environmental space, which is just the opportunities are
so incredible to help better understand and manage Earth's natural systems that we have
got to be throwing basically everything that we have at it. So my first worry is that we won't. My first worry is that all the other tech companies won't follow Microsoft's lead and build up an AI for Earth program, that all of the environmental scientists and organizations won't see tech as one of the significant breakthrough solutions in their
space and that will stagnate. We won't make the progress that we all know we need to make.
So that's the first thing that keeps me up at night. There's that secondary worry, which is
what could go wrong? Well, I mean, if history shows you anything about human activities,
it's that a whole lot could go wrong. You know, I worry more about our lack of understanding
of how nature works and doing something
that inadvertently has a bit of a Schrodinger's cat
kind of effect in the sense of like,
are you observing what would have been observed
in the absence of observation, right?
I don't actually know if that's what Schrodinger said or not,
but it sounded good.
Something about a dead cat. Yeah, something about a dead cat. Yeah,
something about two cats and a box. So that's really kind of one of the first design principles
for everything that we do is in the absence of full understanding, do you feel like you are really
taking that like do no harm kind of approach? And that's one of the reasons that we're really interested in these kind of aspects of remote monitoring,
whether that's like taking images from above
or passively listening to ecosystems with acoustic sensors
or monitoring environmental systems through the lens
of a organism like a mosquito that many places
are trying to eradicate anyway. And really thinking
about, are we deploying technology in a way that isn't going to further disrupt the system? Because
the reason we're putting technology in the system is to figure out how to fix it and stop the
problems. And so those are my two worries. You know, I work a lot. So the time between worrying,
falling asleep and wondering and waking up and getting going again is a bit too lot. So the time between worrying, falling asleep and wondering and waking up and
getting going again is a bit too short. So sometimes I feel like those two W's go hand in hand.
So I like to hear the stories of the guests that come on this show, personal, professional,
academic, how you ended up doing what you're doing. How did you get started and how did you
end up doing what you're doing now? You know, I grew up a kid that just loved being out in the woods,
never was a technology kind of family. I've never had a TV, didn't have a computer until undergrad,
never learned how to program until my PhD when I realized that I probably should.
But I was always just interested in how it kind of all worked. And then I started paying more attention to the fact that in many cases it wasn't working, i.e. humans were negatively influencing these systems. I did my undergrad in wildlife ecology. One of the beauties of the American education system is the general education requirements. I took a general education requirement called on the extinction of species. I sat through that first class. I listened to this professor talk about the state of the world, and I was just completely and totally hooked, changed my major,
spent two years in the Peace Corps, saw some of these environmental issues, just kind of raw,
upfront, in person, came back, did my PhD in ecology and environmental science.
That's when I really leaned into tech because I realized that
there was no way I was going to answer the questions that I wanted to ask, like,
do protected areas protect? Well, there's a lot of protected areas all around the world. You want
to ask that across the entire earth, across every year, you're going to be running code to do those
sorts of things. And just through kind of serendipity and contacts, ended up at Microsoft Research
in Cambridge in the UK. I had an incredible time there. And now I have this opportunity
to oversee Microsoft's global sustainability ambitions, everything from our built environments
to our technology deployment. It's kind of a crazy thing to look back and see.
From a kid in the woods to where you sit now.
Among the trees here in Redmond.
All right, Lucas, as I said at the beginning of the podcast,
you're the chief environmental officer at Microsoft.
Here's your chance to say whatever you want to our listeners.
I often frame this in terms of parting thoughts, wisdom, advice, inspiration, but you can say anything you want. So go.
I get asked this question a lot. And the thing that I always say is,
don't take the easy path, which is, what do you need to succeed? And it's easy to say,
I need money or I need resources. But when I'm talking to an audience like this, an audience of
machine learning experts, computer science professionals, and researchers all around the world,
the message I try to consistently deliver
is all I really need is for every single person
at some point in the day to think about
how they could deploy their core competency,
to just think about,
hey, you know what, I'm a homomorphic encryption guy, or I'm a deep neural nets person, or I'm a UI UX person. That's what I'm great at. massive areas of societal challenge. How can I think about accelerating human progress in the
areas of ag, water, biodiversity, and climate change? If you just think about that, even if
you don't have an idea today or tomorrow, if you just think about that every day,
then I'm satisfied. Then we've made an incredible start on the problem. I don't need every single
person to pick up an identical brick. I need
every person to commit to doing what they're good at. I think so many people look and they
say in environmental sustainability, oh, what we need is better policy. You go over to the
public sector and they say, well, we need our technology solutions. And the truth is
we need all of that. And we need the people who are best at each of those things to do what they're best at.
The Microsofts of the world need to contribute tech.
The public sector needs to contribute policy.
And, you know, double-click all the way down in the tech sector to whatever kind of role that you have in a company like Microsoft.
That's what the world needs.
The world needs what you're best at deployed to help solve some of these environmental
challenges. Lucas Joppa, thank you for coming on the podcast. Yeah, thank you so much for having
me. It's a huge pleasure and a great opportunity. To learn more about Dr. Lucas Joppa and how
Microsoft is putting its powerful cloud and AI tools into the hands of those working to solve
environmental challenges?
Visit Microsoft.com slash research.