this... this is PEAK‼️‼️‼️‼️

The gremlins in my mind want to own a lil mini computer like this as if I we're some strange sci-fi novel character. To you beautiful humans who make stuff like this and know how to use raspberry pies, I love you. My fantasy to be a cyberpunk/lainecore/space girl is fuled by your mastery of this lil goobers

i just think it’s funny that raspberry pi seems to plan their releases around that of apple’s

Testing Dark Castle with audio on the RP2350 Fruit Jam 🕹️🏰

Jepler spent a bunch of time this week working on getting audio working on the pico-umac port https://github.com/jepler/pico-mac/tree/rp2350-fruitjam to Fruit Jam

. Audio on the hardware we're emulating is pretty straightforward: every scanline of the video generator also pops out one byte of PWM data. We have 370 horizontal lines—352 visible and 18 during the vsync—and a 60.15 Hz refresh rate for 22.255 KHz audio approximately. That data is written to $1FD00 http://www.mac.linux-m68k.org/devel/plushw.php . That data is being piped over I2S to the MAX98357

and to a speaker for now.

So, of course, the first thing we have to try out is Dark Castle

: famous for great audio and being a surprisingly hard game to play! The audio sounds really good though :)

Y'ever just think... wow... that's too many computers?

I have seven, not including my tablets.

Five of them are laptops.

Two of those laptops are Macs -- my current Mac laptop (an M2 Macbook Air) which I use every day, and my old laptop (a late-2011 13" MacBook Pro) which after some upgrades (and the removal of its spicy pillow battery years ago) currently runs as a backup server, print server, and network drive.

Then there are the three HP laptops.

One of them I technically don't own, as it's my work machine. It's just running Windows 10 -- nothing special -- and it works. Then I have my two fuckaround machines -- a 15 year old 17" 'desktop replacement' that originally ran Vista but currently runs Linux Mint (and we used for years as the registration computer at No Brand Con). Then I have a 14" laptop that's "current" (in the sense that you can buy it right now for less than $200 at Walmart) that I got for free -- which dual boots into Linux Mint and Windows 11.

And then there are the non-laptops -- my M1 Mac Mini (my primary production workstation for art and podcasts) and my non-laptop fuckaround machine -- a Raspberry Pi 400 running Raspberry Pi OS.

And I was realizing today... is that too many? That might be too many.

The gremlins in my mind want to own a lil mini computer like a cyberdeck as if I we're some strange sci-fi novel character. To you beautiful humans who make stuff like this and know how to use raspberry pies, I love you. Marry me especially if you use Linux.

I’m starting a new project soon (yes I know I have a ton of other WIP projects that need to be done but shush)

It’s basically a mini computer, it’ll consist of a Raspberry Pi 4 for the brains, a 50k mAh rechargeable battery for the power, a touchscreen for viewing(idk about dimensions of it, I’m still designing), a small keyboard and numpad for input, either a 32gb or 64gb micro SD card for storage

It’ll most likely be running some version of Linux (most likely Ubuntu MATE)

It’ll be all housed in a small box, with the screen folding down (on hinges) on top of the keyboard, the numpad will slide in an out of the side of the box, there will be connectors mounted to the side of the box to connect The USB ports (probably only the two USB 3.0s)

Once I set up the server I’ll make it so I manage the server from it, and get it to run more taxing tasks on it that the mini computer wouldn’t have enough processing power to do in a reasonable amount of time

I don’t have a name for it yet but I’d like for it to be an acronym and also sound like an actual name (some of the ideas I’ve gotten so far are NOVA and ALAN, so like those but not quite, also the words that the letters represent didn’t really work)

So if anyone has any suggestions for a name or for more features or revisions and such please tell me (my brain is a bit square and I’m dumb)

All I want is a raspberry pi based portable mini computer that I can read The Unofficial Homestuck Collection on. Just a portable Homestuck machine. Is that too much to ask.

Raspberry Pi Board: Revolutionizing Computing and Education

The Raspberry Pi board is a series of small, affordable single-board computers developed by the Raspberry Pi Foundation, a UK-based charity focused on promoting computer science education and digital literacy. Since its launch in 2012, the Raspberry Pi has transformed from a niche educational tool into a versatile platform used in a wide range of applications, from DIY electronics projects to industrial automation.

A Brief History

The first Raspberry Pi, the Model B, was released in February 2012. Designed to promote basic computer science in schools and developing countries, it featured a 700 MHz ARM11 processor, 256 MB of RAM, and basic connectivity options. The success of the Model B led to a rapid expansion of the Raspberry Pi lineup, with various models offering improved performance, more memory, and enhanced connectivity.

Key Features and Models

Raspberry Pi 1 Model B (2012):

Processor: 700 MHz ARM11

Memory: 256 MB RAM

Ports: 2 USB 2.0 ports, HDMI, Composite video, 3.5mm audio jack, Ethernet

Storage: SD card slot

Raspberry Pi 2 Model B (2015):

Processor: 900 MHz quad-core ARM Cortex-A7

Memory: 1 GB RAM

Ports: 4 USB 2.0 ports, HDMI, Composite video, 3.5mm audio jack, Ethernet

Storage: MicroSD card slot

Raspberry Pi 3 Model B (2016):

Processor: 1.2 GHz quad-core ARM Cortex-A53

Memory: 1 GB RAM

Ports: 4 USB 2.0 ports, HDMI, Composite video, 3.5mm audio jack, Ethernet

Wireless: Wi-Fi and Bluetooth

Raspberry Pi 4 Model B (2019):

Processor: 1.5 GHz quad-core ARM Cortex-A72

Memory: Options of 2 GB, 4 GB, and 8 GB RAM

Ports: 2 USB 3.0 ports, 2 USB 2.0 ports, 2 Micro HDMI ports, Ethernet, USB-C for power

Wireless: Wi-Fi and Bluetooth

Raspberry Pi Zero (2015) and Zero W (2017):

Processor: 1 GHz single-core ARM11

Memory: 512 MB RAM

Ports: Mini HDMI, Micro USB OTG, Micro USB for power, GPIO pins

Wireless (Zero W): Wi-Fi and Bluetooth

Applications and Uses

The versatility of the Raspberry Pi has led to its adoption in numerous fields:

Education:

Coding and Programming: Used in schools and educational programs to teach students programming languages such as Python, Scratch, and Java.

Computer Science Concepts: Introduces concepts like hardware, software, and networking.

DIY Projects and Maker Community:

Home Automation: Controls smart home devices, including lights, thermostats, and security systems.

Media Centers: Powers home media centers using software like Kodi.

Retro Gaming: Emulates classic gaming consoles using software like RetroPie.

Industrial and Commercial Applications:

IoT Devices: Serves as a hub for Internet of Things (IoT) devices, enabling data collection and remote control.

Automation and Control Systems: Used in factories and labs for monitoring and controlling equipment.

Research and Development:

Prototyping: Facilitates rapid prototyping of electronic devices and systems.

Data Collection: Gathers data from various sensors in environmental and scientific research.

Community and Ecosystem

The Raspberry Pi has cultivated a vibrant global community of developers, hobbyists, educators, and students. Online forums, tutorials, and community projects provide extensive support and resources for users at all skill levels. The Raspberry Pi Foundation also offers official accessories, including cases, cameras, and expansion boards, further enhancing the functionality of the Raspberry Pi.

Conclusion

The Raspberry Pi board has revolutionized the way people learn about and interact with technology. Its affordability, versatility, and extensive support network have made it an indispensable tool in education, DIY projects, and professional applications. As technology continues to evolve, the Raspberry Pi Foundation remains committed to expanding the capabilities and accessibility of this remarkable platform, ensuring that computing remains within reach for everyone.

I'm trying to build a tiny baby mini computer for an art project and it's going just absolutely terribly.

How terrible?

Not sure if related but 24 hrs after starting my google account was hacked and I had to cancel a bunch of credit cards.

Now my root password isn't working and I have to start the whole process over.

Hopefully I can still salvage a youtube video about How NOT to setup a Raspberry Pi CM4.

I'm trying to build a mini computer and it's going just absolutely terribly.

How terrible?

Not sure if related but 24 hrs after starting my google account was hacked and I had to cancel a bunch of credit cards.

Now my root password isn't working and I have to start the whole process over.

Hopefully I can still salvage a youtube video about How NOT to setup a Raspberry Pi CM4.

How BTech Mechanical Can Lead to Careers in Robotics

When most students think of Mechanical Engineering, they picture machines, engines, or automobiles. But here’s something exciting—Mechanical Engineering is one of the strongest foundations for a career in Robotics. Yes, you read that right. If you’re someone who dreams of working on intelligent machines, drones, or automation systems, a BTech in Mechanical can be your perfect Launchpad.

Let’s break it down so you see the big picture.

What’s the Link Between Mechanical Engineering and Robotics?

Robotics is not a single-subject field. It combines mechanical engineering, electronics, computer science, and control systems. A robot, after all, is a physical system—made up of gears, motors, joints, and frames. And who better than a mechanical engineer to design and build those parts?

In fact, many leading robotics engineers started with a mechanical background. That’s because mechanical engineering gives you:

A strong understanding of kinematics and dynamics (how things move)

Skills in mechanical design and CAD

Knowledge of materials and manufacturing

Basics of control systems and automation

In simpler words, mechanical engineers are the architects of the robot’s body. They ensure that what’s imagined can be built, function, and perform in the real world.

What You Learn in BTech Mechanical That Helps in Robotics

Here are a few key subjects and skills taught in BTech Mechanical that directly contribute to robotics:

Engineering Mechanics & Dynamics: These help you understand how forces act in machines.

Machine Design & CAD: You’ll learn to design robotic arms, gear systems, and mobile robots.

Thermodynamics & Fluid Mechanics: Useful if you're designing robots for extreme environments.

Automation and Control Engineering: Many colleges include mechatronics and automation, laying the base for robotic control systems.

In institutes that focus on real-world learning, you’ll also work on mini projects and hands-on labs—and that’s where true robotics interest gets sparked.

Where Do Robotics Engineers Work?

You might be surprised at how widespread robotics is. Industries hiring robotics professionals include:

Automotive & Aerospace: Building robots for manufacturing and assembly lines.

Healthcare: Designing robotic surgical tools and prosthetics.

Agriculture: Drones and autonomous farming equipment.

Logistics & Warehousing: Robotics in Amazon-like fulfillment centers.

Defense & Space: Autonomous vehicles, drones, and exploration bots.

So yes, it’s no longer just “rocket science”—robotics is now applied science, and mechanical engineers are at the heart of it.

Top Skills You Need to Add Alongside Your Degree

While your BTech in Mechanical gives you the base, to truly excel in robotics, you should explore:

Programming Skills (Python, C++, MATLAB)

Microcontrollers & Sensors (Arduino, Raspberry Pi)

Robotics Simulation Tools (ROS, Gazebo)

Machine Learning Basics (for intelligent robot behavior)

These can be learned via online courses, robotics clubs, or elective subjects in college.

Choosing the Right College Makes a Difference

Now here’s something important—not all mechanical programs are the same. The best engineering colleges in Odisha are those that go beyond textbooks. Look for places that encourage interdisciplinary projects, have modern labs, and foster industry connections.

For example, NM Institute of Engineering and Technology (NMIET) in Bhubaneswar, though known primarily for its strong mechanical and technical base, also supports hands-on learning, industry collaboration, and practical workshops—exactly the environment where robotics thrives. Institutes like NMIET, affiliated with BPUT and accredited by AICTE, offer a strong academic foundation paired with exposure to real-world applications.

Interestingly, NMIET also maintains industry tie-ups with companies like IBM, Cognizant, and Capgemini—which often explore robotics and automation in their operations. A setup like this can open doors to internships or projects that align with robotics, even if your core branch is mechanical.

Final Thoughts

If you’ve been wondering whether a BTech in Mechanical can lead you into the world of robotics, the answer is: Absolutely, yes. Mechanical engineers are not just part of the robotics field—they are essential to it.

So, if your interest lies in building things that move, think, and react, consider mechanical engineering as your foundation. And when choosing where to study, keep in mind that the best engineering colleges in Odisha are those that integrate practical learning, tech-savvy faculty, and an open environment for innovation.

Remember, the robots of tomorrow need bright minds today—and your journey can begin with a single decision.

Exploring EEE in Engineering: Subjects, Syllabus & Career Opportunities

Introduction

Electrical and Electronics Engineering (EEE) is one of the most dynamic and versatile branches in the field of engineering. It integrates the principles of electricity, electronics, electromagnetism, and computer systems to design, develop, and maintain electrical equipment and electronic devices. Whether it’s power grids, automation systems, or embedded circuits, EEE professionals play a pivotal role in shaping the technology-driven world we live in.

This blog serves as a complete guide to understanding the subjects in EEE engineering, the course structure, and the career paths it unlocks.

What is EEE (Electrical and Electronics Engineering)?

EEE is a core engineering discipline that focuses on both electrical systems (such as power generation, transmission, and motors) and electronics (like microcontrollers, signal processing, and embedded systems). It’s an ideal choice for students who are analytical, curious about how things work, and passionate about innovation.

Course Duration & Eligibility

Course Name: B.E./B.Tech in Electrical and Electronics Engineering

Duration: 4 years (8 semesters)

Eligibility: 10+2 with Physics, Chemistry, and Mathematics (PCM) + entrance exams like JEE Main, state CETs, or institute-level tests

Core EEE Subjects: Semester-Wise Breakdown

EEE curriculum is spread over 4 years and focuses on both theoretical learning and practical application. Here's a semester-wise overview of key subjects:

Year 1: Basic Engineering & Foundation

Engineering Mathematics I & II

Physics & Chemistry

Basic Electrical & Electronics Engineering

Programming in C

Engineering Graphics

Environmental Science

Workshops and Labs

Year 2: Electrical & Circuit Theory

Circuit Analysis

Network Theory

Electronic Devices & Circuits

Electromagnetic Fields

Signals and Systems

Analog and Digital Electronics

Electrical Machines – I

Simulation Lab, Devices Lab

Year 3: Core Technical Development

Electrical Machines – II

Control Systems

Power Electronics

Microprocessors & Microcontrollers

Transmission and Distribution

Measurements & Instrumentation

Renewable Energy Systems

Power Systems Lab, Embedded Systems Lab

Year 4: Advanced Topics & Applications

High Voltage Engineering

Smart Grid Technology

Electric Drives & Control

Industrial Automation (PLC, SCADA)

Elective Subjects (Robotics, IoT, Artificial Intelligence in Electrical Systems)

Final Year Project

Internship & Industrial Training

Practical Learning & Lab Work

EEE places strong emphasis on hands-on learning. Students gain real-world experience through:

Circuit design and simulation

Hardware testing and troubleshooting

Mini projects and capstone projects

Industrial visits and live projects

Coding for embedded systems using Arduino, Raspberry Pi, etc.

Skills You Gain in EEE

Strong analytical and mathematical reasoning

Hardware and circuit design proficiency

Knowledge of renewable and sustainable energy

Programming skills (C, C++, Python for microcontrollers)

Problem-solving and project management

Interdisciplinary collaboration

Career Opportunities After EEE

Graduates in Electrical and Electronics Engineering are in high demand across sectors like energy, manufacturing, automation, transportation, and IT. Common job roles include:

Electrical Engineer

Power Systems Engineer

Embedded Systems Developer

Electronics Design Engineer

Automation Engineer

Control Systems Engineer

Maintenance Engineer

Technical Consultant

Major recruiters include public sector undertakings (PSUs like BHEL, NTPC, ONGC), private MNCs (Siemens, ABB, Schneider Electric), IT firms (TCS, Wipro, Infosys), and startups in renewable energy and robotics.

Higher Studies & Certifications

Students often pursue postgraduate degrees like:

M.Tech in Power Systems / VLSI / Control Systems

MBA in Operations or Project Management

International MS in Electrical Engineering

Additionally, certifications in PLC programming, SCADA systems, MATLAB, or IoT applications can greatly enhance job prospects.

Final Thoughts

EEE is an exciting and future-proof engineering stream that opens up diverse opportunities in traditional and emerging industries. With a curriculum that balances theoretical knowledge and practical exposure, students graduate with the skills needed to power innovation and electrify the future. If you’re a student passionate about circuits, energy, and electronics, Electrical and Electronics Engineering could be your perfect career path.

Website:https://kce.ac.in/

Address:Myleripalayam Village, Othakkal Mandapam Post, Coimbatore - 641032, Tamilnadu, India

+91 82203 33750, +91 82203 33620 +91 422 2619005, +91 422 2619006

Mail id :[email protected]

Fruit Jam RP2350B credit-card mini computer with all the fixin's 🍓🍇💾

We were catching up on a recent Hackaday hackchat with Eben Upton (https://hackaday.io/event/202122-raspberry-pi-hack-chat-with-eben-upton) and learned some fun facts: such as the DVI hack for the RP2040 was inspired by a device called the IchigoJam (https://www.hackster.io/news/ichigojam-combines-strawberry-and-raspberry-to-deliver-a-raspberry-pi-pico-powered-educational-micro-66aa5d2f6eec). We remember reading about this back when it was an LPC1114, now it uses an RP2040. Well, we're wrapping up the Metro RP2350 (https://www.adafruit.com/product/6003), and lately, we've been joking around that with DVI output and USB Host support via bit-banged PIO, you could sorta build a little stand-alone computer. Well, one pear-green-tea-fueled-afternoon later we tried our hand at designing a 'credit card sized' computer - that's 3.375" x 2.125", about the same size as a business card (https://hackaday.com/2024/05/07/the-2024-business-card-challenge-starts-now/) and turns out there's even a standard named for it: ISO/IEC 7810 ID-1 (https://www.iso.org/standard/70483.html).

Anyhow, with the extra pins of the QFN-80 RP2350B, we're able to jam a ridonkulous amount of hardware into this shape: RP2350B dual 150MHz Cortex M33 w/ PicoProbe debug port, 16 MB Flash + 8 MB PSRAM, USB type C for bootloading/USB client, Micro SD card with SPI or SDIO, DVI output on the HSTX port, I2S stereo headphone + mono speaker via the TLV320DAC3100 (https://www.digikey.com/en/products/detail/texas-instruments/tlv320dac3100irhbt/2353656), 2-port USB type A hub for both keyboard and mouse or game controllers, chunky on-off switch, Stemma QT I2C + Stemma classic JST 3-pin, EYESPI for TFT displays, 5x NeoPixels, 3x tactile switches, and a 16-pin socket header with 10 A/D GPIO + 5V/3V/GND power pins. The PSRAM will help when we want to do things like run emulations that we need to store in fast RAM access, and it will also let us use the main SRAM as the DVI video buffer.

When we get the PCBs back and assembled, what should we try running on this hardware? We're pretty sure it can run DOOM. Should that be first? :) We also need a name. Right now, we're just calling it Fruit Jam since it's inspired by the IchigoJam project.

Given this familiarity, I had a few big questions for Sholly about the self-hosted scene. First up: What is the difference between "home lab" and "self-hosting"? Home labs, Sholly suggested, are much more focused on hardware and networking. Home labs are often something people do in their professional lives and bring home with them. Self-hosting is something you could technically do on a laptop you keep running in a closet, Sholly said.

What gave rise to self-hosting's relative recent popularity? That led Sholly to a few answers, many of them directly relating to the corporate cloud services people typically use instead of self-hosting:

Privacy for photos, files, and other data

Cost of cloud hosting and storage

Accessibility of services, through GitHub, Reddit, and sites like his

Installation with Docker ("a game-changer for lots of people") and Unraid

Single-board computers (SBCs) like the Raspberry Pi

NUCS, mini-PCs, workstations, and other pandemic-popular hardware

Finally, there's the elephant in any self-hosting discussion: piracy. Sholly doesn't shy away from it as a driver of self-hosting (see the "*arr Stack" in the chart below, "arr" as in goofy pirate speak). "Look at the questions asked by the newcomers to the scene on any subreddit or forum, look at what they're asking about: It's their 'media files' and how to handle them," he said.

Bring your imagination to life and hone your tech skills with Heartening Raspberry Pi projects that are more practical than theoretical. Raspberry Pi projects. No matter if you have interest in electronics, IoT, robotics, or automation-these projects prove to be suitable for Computer Science, Electronics, as well as Electrical engineering students. Construct authentic solutions for the world, improve your CV, and remain in front of the competition in technology!

Types of Raspberry Pi Projects for Engineering Students Raspberry Pi is truly the breakthrough invention that will take up engineering students building ground breaking yet real-time applications. Some of the most common types of Raspberry Pi projects are:

1. Through Internet of Things (IoT) projects, sensors and devices can be connected to the internet for making advanced homes, weather stations, or health monitoring systems.

2. Automate anything from lights and appliances to security systems with Raspberry Pi and Python.

3. Using motor drivers and Raspberry Pi, a robotic project would control robots that may be line followers or robotic arms.

4. AI and ML projects simulate basic image recognition, voice assistants, or face detection modelling in Python and TensorFlow Lite.

5. Networking is where mini-servers, VPNs, or network scanners can be made using Raspberry Pi.

6. Projects of Media and Entertainment create smart mirrors and media centers and also game emulators for some fun and learning.

7. Educational projects will create learning kits for kids, digital notice boards, or interactive classroom tools.

It is the best medium for undergraduate students who are interested in practical study in the domains of computer science, electrical, electronics, electronic systems, and telecommunications engineering.

Top Skills You’ll Learn in a Robotics and Artificial Intelligence Course

In a world that’s rapidly embracing automation, machine intelligence, and smart systems, careers in robotics and artificial intelligence (AI) are more promising than ever. From healthcare robots to self-driving cars and intelligent customer support systems, AI and robotics are becoming integral to modern life.

If you're considering robotics and artificial intelligence courses, you're not just choosing a degree — you're preparing to be part of a technological revolution. But what exactly will you learn in such a program? Let’s explore the most important skills these courses help you develop, and how they prepare you for the future of innovation.

Programming Fundamentals for AI and Robotics

Whether a robot arm on a manufacturing floor or a chatbot handling customer queries, everything begins with programming. Students learn core languages such as:

Python: Widely used in AI and machine learning applications.

C/C++: Essential for embedded systems and robotic control.

Java: Useful in software development and some machine learning frameworks.

Understanding data structures, control flow, and algorithms is foundational for writing efficient code for intelligent systems.

Machine Learning and Deep Learning Techniques

At the heart of AI lies machine learning — the ability for machines to learn from data. Students gain practical knowledge of:

Supervised and unsupervised learning

Neural networks and deep learning frameworks like TensorFlow and PyTorch

Natural Language Processing (NLP) for text and voice-based AI systems

These skills are critical for creating models that can analyze data, make predictions, and improve over time.

Robotics System Design and Control

In robotics, it’s all about building machines that sense, think, and act. You'll learn how to:

Design mechanical structures and integrate them with electronics

Work with sensors (like LIDAR, cameras, gyros) and actuators

Apply control systems theory to ensure precise movements and decisions

These concepts are essential in developing autonomous systems, from robotic arms to drones.

Embedded Systems and IoT Integration

Modern robots and smart devices often rely on embedded systems — mini-computers that perform dedicated functions. You'll learn to:

Program microcontrollers (like Arduino or Raspberry Pi)

Work with real-time operating systems

Connect devices using IoT protocols (like MQTT)

This hands-on knowledge is critical for building responsive and connected devices.

Computer Vision and Image Processing

Robots and AI systems need eyes — and that’s where computer vision comes in. This skill allows machines to:

Interpret visual data from cameras or sensors

Recognize objects, track movements, and detect patterns

Use tools like OpenCV to process and analyze images

Applications range from facial recognition to robotic navigation.

AI Ethics and Responsible Innovation

With great power comes great responsibility. As AI systems become more influential, engineers must understand:

Ethical implications of automation and decision-making

Bias in AI models

Data privacy and security concerns

Courses now include modules that prepare students to design responsible and inclusive technologies.

Soft Skills for Cross-Disciplinary Collaboration

It’s not all about tech. Robotics and AI projects often involve teamwork across domains. You’ll develop:

Communication and presentation skills

Project management techniques

Creative thinking and problem-solving abilities

These soft skills ensure that your innovative ideas are clearly conveyed and efficiently executed in real-world scenarios.

Real-World Projects and Internships

A good robotics and AI course doesn't end with classroom theory. Students gain experience through:

Capstone projects where they design, build, and deploy AI or robotic systems

Industry internships that provide exposure to real-world applications

Hackathons and competitions that encourage innovation under pressure

This kind of hands-on experience is crucial in standing out during placements and job interviews.

Choosing the Right Institution Matters

The quality of your learning experience depends heavily on where you study. The best robotics and artificial intelligence courses provide a mix of strong academic foundation, practical labs, and industry exposure.

At NITTE University, particularly through its NMAM Institute of Technology (NMAMIT), students receive a future-focused education that combines cutting-edge theory with real-world skills. With dedicated labs, advanced AI and robotics curriculum, and partnerships with industry leaders, NMAMIT prepares students not just for today’s tech world—but for the challenges of tomorrow.