4.9K
RPSome of our School of Science students share their favorite class this semester! What’s yours? 🤔 Let us know in the comments below! #RPIScience #RPI2030 #RPI
@rpiscience
#Rpi2030
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Reel di Tendenza
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1.8M
THHow to make a deer? Here’s a general step-by-step outline of how it could be approached:
1. **Design and Planning:**
- Define the purpose of the synthetic deer (e.g., for research, decoration, robotics).
- Create a detailed design including dimensions, appearance, and functionality.
2. **Materials and Components:**
- Gather materials such as synthetic fur, mechanical components (motors, sensors), and structural materials (plastic, metal).
- Choose electronic components for any interactive features (LED eyes, sound effects).
3. **Constructing the Body:**
- Build the skeleton or frame using lightweight materials like aluminum or plastic tubing.
- Attach joints and mechanisms for mobility (legs, head movement).
- Cover the frame with synthetic fur or materials that mimic deer skin.
4. **Electronic Integration:**
- Install motors and actuators for movement (e.g., walking, turning head).
- Integrate sensors for environmental awareness (e.g., proximity sensors to avoid obstacles).
- Wire components for power supply and control (Arduino or Raspberry Pi may be used for control).
5. **Detailing and Aesthetics:**
- Sculpt or mold facial features and antlers if applicable.
- Paint or apply finishing touches to enhance realism (e.g., texture painting, weathering effects).
6. **Testing and Calibration:**
- Test mobility and electronic functionalities.
- Calibrate sensors and actuators to ensure smooth operation.
7. **Final Adjustments:**
- Fine-tune movements and appearance based on testing feedback.
- Secure all components to prevent wear or malfunction.
8. **Optional Features:**
- Consider adding additional features like sound effects, infrared night vision, or remote control capabilities depending on the project’s requirements.
9. **Documentation and Maintenance:**
- Document the build process and specifications for future reference.
- Provide guidelines for maintenance and troubleshooting.
10. **Deployment or Display:**
- Deploy the synthetic deer in its intended environment or display it as desired.
- Ensure it meets safety standards and regulations if applicable.
@the_speak_inglis
317.4K
EUThe Ultimate Raspberry Pi: Portable, Modular, and Powerful 🛜
This is my 100% portable Raspberry Pi 5 build: 16GB RAM, 512GB NVMe SSD storage, battery powered, and designed for real-world wireless research, testing, and lab work.
The Pi runs completely untethered from wall power using an external battery pack, connects over VNC from my phone or laptop, and uses a dedicated Wi-Fi adapter so management, connectivity, and wireless testing stay cleanly separated. Everything is tied together through a compact UniFi 5-port switch, keeping the setup stable, modular, and expandable.
For internet access, I pair it with a Verizon Inseego 5G router, which keeps the entire rig mobile while still maintaining solid upstream connectivity. Pairs nicely when experimenting with Evil Twin Wi-Fi “fun”. 🙃
And now the real question…
👉 What would YOU add to make this even stronger?
- More radios? Better antennas?
- Displays? Redundancy?
#raspberrypi #techgadgets #cybersecurity #tech #hacking
@eurothrottle
121.0K
THEverybody loves OpenClaw.
But these 5 just raised the bar.
Day 50 of building 100X 🚀
OpenClaw went viral.
180K stars.
Mass adoption.
But innovation didn’t stop there.
NanoClaw
Same memory. Same WhatsApp. Same scheduling.
500 lines of code.
Runs inside Apple Containers.
Even lets you launch Agent Swarms inside chat.
ZeroClaw
Pure Rust.
3.4MB binary.
Runs on a $10 device.
Imports your OpenClaw memory in seconds.
TrustClaw
Your agent never sees your API keys.
1,000 integrations.
Zero setup.
Nanobot
Built by researchers at University of Hong Kong.
4,000 lines of Python.
Runs on a Raspberry Pi.
Works with WhatsApp, Telegram, Slack, Discord, Email.
Moltworker
Runs OpenClaw inside Cloudflare.
$5/month.
Your agent lives in the cloud — not your laptop.
All five are free or nearly free.
All five do what OpenClaw does.
Just differently.
This is what open source looks like.
Evolution in real time.
Comment OPENCLAW and I’ll send you all the links.
@thevibefounder
5.4K
RPCoach Eric Lang checking in from the road with an important reminder: it’s Rπ Day. Let’s finish strong and support the future of RPI Hockey. 🔴⚪️ #LetsGoRed
@rpi_mhockey
1.4M
ALI wanted an all-in-one unit for DJing but nothing available met my requirements:
- **multiple** USB ports for storage drives on the top (necessary for going back to back with other DJs)
- separate booth vs main output
- beveled screen, easily viewed while performing
- strictly pioneer layout to practice for spinning at the club.
I also wanted it to cost under $500. It is ridiculous that the XZ for example costs over $3,000.
It turns out that you can load mixxx onto a raspberry pi such that you can plug in a pioneer DJ controller, then build your own mixer using NE5532 op amps to create a separate booth output. The real magic is building the enclosure out of something strong (acrylic) then mounting RCA and USB type-c plugs to the back such that it just sort of snaps into an existing controller, in this case an FLX4, effectively creating an all-in-one unit.
I plan to continue development on this and I'm excited for the possibility of 3D printing a more elegant enclosure and also adding native USB eject/ management capabilities into mixxx so that I can replicate the USB management of a pioneer controller. Please follow along if this interests you!:) #dj #diy #pioneer #raspberrypi #electronics
@alyxxcould
2.5M
TH📹The Speak English Daily
🎯 Goal → 100K🥳
📆 DAY 144/1000🚀
🙏 Please follow the page 💙
How to make a deer? Here’s a general step-by-step outline of how it could be approached:
1. Design and Planning:
- Define the purpose of the synthetic deer (e.g., for research, decoration, robotics).
- Create a detailed design including dimensions, appearance, and functionality.
2. Materials and Components:
- Gather materials such as synthetic fur, mechanical components (motors, sensors), and structural materials (plastic, metal).
- Choose electronic components for any interactive features (LED eyes, sound effects).
3. Constructing the Body:
- Build the skeleton or frame using lightweight materials like aluminum or plastic tubing.
- Attach joints and mechanisms for mobility (legs, head movement).
- Cover the frame with synthetic fur or materials that mimic deer skin.
4. Electronic Integration:
- Install motors and actuators for movement (e.g., walking, turning head).
- Integrate sensors for environmental awareness (e.g., proximity sensors to avoid obstacles).
- Wire components for power supply and control (Arduino or Raspberry Pi may be used for control).
5. Detailing and Aesthetics:
- Sculpt or mold facial features and antlers if applicable.
- Paint or apply finishing touches to enhance realism (e.g., texture painting, weathering effects).
6. Testing and Calibration:
- Test mobility and electronic functionalities.
- Calibrate sensors and actuators to ensure smooth operation.
7. Final Adjustments:
- Fine-tune movements and appearance based on testing feedback.
- Secure all components to prevent wear or malfunction.
8. Optional Features:
- Consider adding additional features like sound effects, infrared night vision, or remote control capabilities depending on the project’s requirements.
9. Documentation and Maintenance:
- Document the build process and specifications for future reference.
- Provide guidelines for maintenance and troubleshooting.
10. Deployment or Display:
- Deploy the synthetic deer in its intended environment or display it as desired.
- Ensure it meets safety standards and regulations if applicable.
@the_speak_inglish
161.3K
THHow to make a deer? Here’s a general step-by-step outline of how it could be approached:
1. **Design and Planning:**
- Define the purpose of the synthetic deer (e.g., for research, decoration, robotics).
- Create a detailed design including dimensions, appearance, and functionality.
2. **Materials and Components:**
- Gather materials such as synthetic fur, mechanical components (motors, sensors), and structural materials (plastic, metal).
- Choose electronic components for any interactive features (LED eyes, sound effects).
3. **Constructing the Body:**
- Build the skeleton or frame using lightweight materials like aluminum or plastic tubing.
- Attach joints and mechanisms for mobility (legs, head movement).
- Cover the frame with synthetic fur or materials that mimic deer skin.
4. **Electronic Integration:**
- Install motors and actuators for movement (e.g., walking, turning head).
- Integrate sensors for environmental awareness (e.g., proximity sensors to avoid obstacles).
- Wire components for power supply and control (Arduino or Raspberry Pi may be used for control).
5. **Detailing and Aesthetics:**
- Sculpt or mold facial features and antlers if applicable.
- Paint or apply finishing touches to enhance realism (e.g., texture painting, weathering effects).
6. **Testing and Calibration:**
- Test mobility and electronic functionalities.
- Calibrate sensors and actuators to ensure smooth operation.
7. **Final Adjustments:**
- Fine-tune movements and appearance based on testing feedback.
- Secure all components to prevent wear or malfunction.
8. **Optional Features:**
- Consider adding additional features like sound effects, infrared night vision, or remote control capabilities depending on the project’s requirements.
9. **Documentation and Maintenance:**
- Document the build process and specifications for future reference.
- Provide guidelines for maintenance and troubleshooting.
10. **Deployment or Display:**
- Deploy the synthetic deer in its intended environment or display it as desired.
- Ensure it meets safety standards and regulations if applicable.
@the_speak_inglis
10.1K
ENMechatronics engineering doesn’t always get the spotlight, but it’s one of the most future-proof careers out there. You’re basically the bridge between mechanical, electrical, and computer systems. The people who make robots move, cars drive themselves, and factories run smarter.
My opinion is that mechatronics engineers aren’t just “engineers in between.” They’re systems thinkers.
If you’re thinking about career security; AI, automation, and robotics are only growing. Mechatronics engineers will be the ones turning that tech into reality.
Tip: Start building projects early. Even something small like Arduino or Raspberry Pi robotics can set you apart
#engineeringstudent #college #mechanicalengineering #engineeringmajor #engineering
@engioneering
60.1K
TI👇What’s in demand for tech skills in 2023? 📈 Here are 5 of the top skills to learn right now:
🤖 AI and Machine Learning - AI is being rapidly adopted with over 50% of companies using chatbots by 2030 (Gartner). Learn in-demand frameworks like TensorFlow and PyTorch to become an AI Engineer. Salaries average $142k in the US!
☁️ Cloud Computing - Cloud has gone mainstream with 77% of enterprises having at least 1 cloud app. Get AWS certified or take cloud computing courses on Coursera to gain in-demand skills.
🤝 SQL - SQL skills are growing rapidly with 74% annual growth reported on LinkedIn. Take an online SQL basics course to query databases. Even business analysts use SQL regularly.
🤖 Robotics - The robotics market is projected to reach $237 billion by 2027. Tap into this growth by trying robotics projects at home with Raspberry Pi and Arduino boards. Fun hobby with career potential!
☁️ Low Code - With low code, you can build apps faster with less manual coding. The low code mindset is key.
What tech skills are you hoping to gain right now? Let me know in the comments!
#tech #technology #coding
@tiffintech
72.0K
JOपिंपळनेर शहरात झालेल्या तिहेरी हत्याकांडाच्या निषेधार्थ मोर्चात संतप्त नागरिकांची प्रतिक्रिया
#reels #viral #sakri #dhule #rpi
@journalist_umakant_ahirrao
1.6M
I_The Speak English Daily
Goal + 100K
DAY 1/1000
Please follow the page
How to make a deer? Here's a general step-by-step outline of how it could be approached:
1. Design and Planning:
- Define the purpose of the synthetic deer (e.g., for research, decoration, robotics).
- Create a detailed design including dimensions, appearance, and functionality.
2. Materials and Components:
- Gather materials such as synthetic fur, mechanical components (motors, sensors), and structural materials (plastic, metal).
- Choose electronic components for any interactive features (LED eyes, sound effects).
3. Constructing the Body:
- Build the skeleton or frame using lightweight materials like aluminum or plastic tubing.
Attach joints and mechanisms for mobility (legs, head movement).
- Cover the frame with synthetic fur or materials that mimic deer skin.
4. Electronic Integration:
- Install motors and actuators for movement (e.g., walking, turning head).
- Integrate sensors for environmental awareness (e.g., proximity sensors to avoid obstacles).
- Wire components for power supply and control (Arduino or Raspberry Pi may be used for control).
5. Detailing and Aesthetics:
- Sculpt or mold facial features and antlers if applicable.
- Paint or apply finishing touches to enhance realism (e.g., texture painting, weathering effects).
6. Testing and Calibration:
- Test mobility and electronic functionalities.
Calibrate sensors and actuators to ensure smooth operation.
7. Final Adjustments:
- Fine-tune movements and appearance based on testing feedback.
- Secure all components to prevent wear or malfunction.
8. Optional Features:
- Consider adding additional features like sound effects, infrared night vision, or remote control
9. Documentation and Maintenance:
- Document the build process and specifications for future reference.
- Provide guidelines for maintenance and troubleshooting.
10. Deployment or Display:
- Deploy the synthetic deer in its intended environment or display it as desired.
- Ensure it meets safety standards and regulations if applicable.
@i_am_the_inglish_
✨ Guida alla Scoperta #Rpi2030
Instagram ospita thousands of post sotto #Rpi2030, creando uno degli ecosistemi visivi più vivaci della piattaforma.
L'enorme raccolta #Rpi2030 su Instagram presenta i video più coinvolgenti di oggi. I contenuti di @the_speak_inglish, @the_speak_inglis and @i_am_the_inglish_ e altri produttori creativi hanno raggiunto thousands of post a livello globale.
Cosa è di tendenza in #Rpi2030? I video Reels più visti e i contenuti virali sono in evidenza sopra.
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Domande Frequenti Su #Rpi2030
Con Pictame, puoi sfogliare tutti i reels e i video #Rpi2030 senza accedere a Instagram. Nessun account richiesto e la tua attività rimane privata.
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