Status: True
Assertion
The Earth’s diameter at the equator is roughly 12,742 kilometres.
Results
The Earth can be approximated as an oblate spheroid due to its rotation; measurements for the Earth’s polar and equatorial diameters are accurate and widely accepted, reflecting a true difference attributed to rotational effects; comparing celestial bodies like Jupiter and Saturn, their shapes can also be approximated based on observations due to rapid rotations. These statements align with scientific understanding of planetary geometry and the influence of rotation on shape.
Assumptions
# Assumptions:
– The Earth can be approximated as an oblate spheroid due to its rotation.
– Measurements for Earth’s polar and equatorial diameters are accurate and widely accepted (e.g., 12,714 km for the polar diameter and approximately 12,742 km for the equatorial diameter).
– The difference between the Earth’s polar and equatorial diameters is primarily attributed to its rotation rather than other factors such as gravitational influences or internal structure.
– When comparing celestial bodies like Jupiter and Saturn, their shapes can also be approximated based on observations (e.g., oblate spheroids due to rapid rotation), allowing for a meaningful comparison with Earth’s dimensions.
– The provided diameters of Jupiter and Saturn are accurate enough to enable comparisons, acknowledging that precise measurements may vary slightly depending on the source.
– The context of comparing planetary sizes is based on understanding their physical characteristics rather than specific geological or atmospheric features, which could also affect size perceptions but are not directly relevant to this discussion.
Fact Checker Output
<|assistant|> – True: The Earth can be approximated as an oblate spheroid due to its rotation. This approximation holds because the centrifugal force caused by Earth’s rotation causes a bulging at the equator and flattening at the poles, making it more of an oblate spheroid rather than a perfect sphere.
– True: Measurements for Earth’s polar and equatorial diameters are accurate and widely accepted. The figures given (12,714 km for the polar diameter and approximately 12,742 km for the equatorial diameter) align with data provided by organizations such as NASA, making them reliable for comparison purposes.
– True: The difference between the Earth’s polar and equatorial diameters is primarily attributed to its rotation rather than other factors like gravitational influences or internal structure. While those factors do affect planetary shapes slightly (e.g., tidal forces), they are not significant enough compared to the effect of rotation on Earth’s oblateness.
– True: When comparing celestial bodies like Jupiter and Saturn, their shapes can also be approximated based on observations due to rapid rotations that make
Model Used
microsoft/Phi-3-mini-4k-instruct-gguf
Script Name
fact_checker_mongodb.py
Script Code
import os
import sys
import requests
from langchain_openai.llms import OpenAI
from langchain.prompts import PromptTemplate
from dotenv import load_dotenv
from statements import get_random_statement
from mongodb_helper import insert_record # Import MongoDB helper functions
import html
# Load environment variables from .env file
load_dotenv()
# Define category IDs
CATEGORY_IDS = {
"True": 2,
"False": 3,
"Debatable": 4,
"Unknown": 6
}
def create_wordpress_post(title, content, category):
data = {
"title": title,
"content": content,
"status": "publish",
"categories": [CATEGORY_IDS[category]]
}
response = requests.post(
os.getenv("WORDPRESS_POSTS_URL"),
json=data,
auth=(os.getenv("WORDPRESS_USERNAME"), os.getenv("WORDPRESS_PASSWORD"))
)
if response.status_code == 201:
print("Blog post created successfully.")
else:
print(f"Failed to create blog post: {response.status_code} - {response.text}")
def fact_check(assertion):
llm = OpenAI(temperature=0.7, model=os.getenv("MODEL_NAME"))
# Define the prompt templates
assertion_template = """{assertion}\n\n"""
assertion_prompt = PromptTemplate(input_variables=["assertion"], template=assertion_template)
assumptions_template = """Here is a statement:
{statement}
Make a bullet point list of the assumptions required to support the above statement.\n\n"""
assumptions_prompt = PromptTemplate(input_variables=["statement"], template=assumptions_template)
fact_checker_template = """Here is a bullet point list of assertions:
{assertions}
For each assumption, determine whether it is true or false. Explain your reasoning.\n\n"""
fact_checker_prompt = PromptTemplate(input_variables=["assertions"], template=fact_checker_template)
answer_template = """
Here is the information to classify the statement:
{facts}
Based on the above information, how would you classify the statement? Respond with one of the following options followed by a colon and space:
- True: [Explanation]
- False: [Explanation]
- Debatable: [Explanation]
"""
answer_prompt = PromptTemplate(input_variables=["facts"], template=answer_template)
# Format prompts and extract the string content
formatted_assertion = assertion_prompt.format_prompt(assertion=assertion).text
assertion_output = llm.invoke(formatted_assertion)
formatted_assumptions = assumptions_prompt.format_prompt(statement=assertion_output).text
assumptions_output = llm.invoke(formatted_assumptions)
formatted_fact_checker = fact_checker_prompt.format_prompt(assertions=assumptions_output).text
fact_checker_output = llm.invoke(formatted_fact_checker)
formatted_answer = answer_prompt.format_prompt(facts=fact_checker_output).text
final_output = llm.invoke(formatted_answer)
return {
"assertion_output": assertion_output,
"assumptions_output": assumptions_output,
"fact_checker_output": fact_checker_output,
"final_output": final_output,
}
def extract_status_and_reasoning(final_output):
final_output = final_output.strip()
if "True:" in final_output:
status_start = final_output.find("True:")
status = "True"
elif "False:" in final_output:
status_start = final_output.find("False:")
status = "False"
elif "Debatable:" in final_output:
status_start = final_output.find("Debatable:")
status = "Debatable"
else:
return "Unknown", final_output
reasoning = final_output[status_start + len(status) + 1:].strip()
return status, reasoning
if __name__ == "__main__":
if len(sys.argv) > 1:
assertion = sys.argv[1]
else:
assertion = get_random_statement()
print(assertion)
submission = fact_check(assertion)
# Print the detailed outputs to inspect their structure
for key, value in submission.items():
print(f"{key}: {value}")
# Extract the final output for status determination and reasoning
final_output = submission['final_output']
status, reasoning = extract_status_and_reasoning(final_output)
# Record the result in MongoDB
try:
print("Attempting to insert record into MongoDB...")
insert_record(
script_name="fact_checker_mongodb.py",
script_code=html.escape(open(__file__).read()),
assertion=assertion,
status=status,
submission=submission, # Store the entire submission for detailed analysis
model=os.getenv("MODEL_NAME")
)
print("Record inserted into MongoDB successfully.")
except Exception as e:
print(f"Failed to insert record into MongoDB: {e}")
print(final_output)
# Create a blog post on WordPress
blog_title = f"Fact Check: {assertion}"
blog_content = f"""
<h1>Status: {status}</h1>
<h2>Assertion</h2>
<p>{assertion}</p>
<h2>Results</h2>
<p>{reasoning}</p>
<h3>Assumptions</h3>
<p>{submission['assumptions_output']}</p>
<h3>Fact Checker Output</h3>
<p>{submission['fact_checker_output']}</p>
<h4>Model Used</h4>
<p>{os.getenv("MODEL_NAME")}</p>
<h4>Script Name</h4>
<p>fact_checker_mongodb.py</p>
<h4>Script Code</h4>
<pre>{html.escape(open(__file__).read())}</pre>
"""
create_wordpress_post(blog_title, blog_content, status)
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