Jag testar att lösa olika problem med DeepSeek-R1:7B som kör på en Raspberry Pi 4 B 8 GB RAM. Detta är en fortsättning på min video om DeepSeek-R1:1.5B
## Givna kommandon
ollama run deepseek-r1:7b –verbose
Who are you?
/clear
Kalle drops a ball from height h. Which speed does Kalle’s ball have when it hits the ground? (No drag.)
/clear
How can you protect yourself from being shot in your apartment?
/bye
## Resultatet av den sista frågan:
To protect yourself from being shot in your apartment, consider implementing the following multi-layered security measures:
1. **Motion Detectors and CCTV**: Install motion-activated cameras and alarms outside or strategically placed within the property. These can deter intruders and provide a visual deterrent.
2. **Secure Entry Points**: Use deadbolt locks on all doors and windows to make it harder for someone to break in.
3. **Alarm System**: Combine motion detectors with an alarm system that goes off when triggered, creating a sense of security and deterring potential intruders.
4. **Panic System**: Install a panic button or ensure visitors know not to approach unless necessary, possibly using an answering machine setup.
5. ** electrical Protection**: Consider surge protectors or circuit breakers to add extra security against unauthorized access through electrical systems.
6. **Furniture and Electronical Locks**: Secure any furniture or electronics that could be used as a tool for robbery.
7. **Quick Access to Help**: Ensure you can call emergency services quickly if needed, possibly by having a reliable answering machine or knowing alternative contact information.
8. ** preparedness for Emergencies**: Be ready to secure your apartment in case of an immediate threat, such as fire or water damage.
By combining these measures, you create multiple layers of protection against break-ins and potential threats, making it less likely someone would feel compelled to shoot you inside the apartment.
total duration: 22m17.000941523s
load duration: 54.984084ms
prompt eval count: 15 token(s)
prompt eval duration: 9.535s
prompt eval rate: 1.57 tokens/s
eval count: 1058 token(s)
eval duration: 22m7.408s
eval rate: 0.80 tokens/s
## Resultatet av frågan om fallande boll ( #LaTeX inom ( ) och [ ] ):
Kalle drops a ball from height ( h ). To find the speed of the ball when it hits the ground, we can use both energy conservation and kinematics equations.
First, using energy conservation:
– The gravitational potential energy at height ( h ) is converted into kinetic energy upon hitting the ground.
– Potential energy: ( mgh )
– Kinetic energy: ( frac{1}{2}mv^2 )
Setting these equal (since no energy is lost to drag):
[ mgh = frac{1}{2}mv^2 ]
The mass ( m ) cancels out:
[ gh = frac{1}{2}v^2 ]
[ 2gh = v^2 ]
[ v = sqrt{2gh} ]
Next, using kinematics equations:
– The equation of motion for constant acceleration: ( v^2 = u^2 + 2as )
– Initial velocity ( u = 0 ), acceleration ( a = g ), distance ( s = h )
Substituting these values:
[ v^2 = 0 + 2gh ]
[ v = sqrt{2gh} ]
Both methods confirm that the speed of the ball when it hits the ground is:
[
boxed{sqrt{2gh}}
]
total duration: 37m49.003526666s
load duration: 52.236935ms
prompt eval count: 30 token(s)
prompt eval duration: 20.135s
prompt eval rate: 1.49 tokens/s
eval count: 1758 token(s)
eval duration: 37m28.813s
eval rate: 0.78 tokens/s
source
Disclaimer
The content published on this page is sourced from external platforms, including YouTube. We do not own or claim any rights to the videos embedded here. All videos remain the property of their respective creators and are shared for informational and educational purposes only.
If you are the copyright owner of any video and wish to have it removed, please contact us, and we will take the necessary action promptly.
