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AI explanation
As air pollution in Jackson decreased, it created a domino effect on global air currents. These revamped air currents then harmonized with the traditional fado music in Portugal, leading to a spontaneous airborne kerosene combustion prevention dance routine. The synchronized swaying and footwork somehow disrupted the kerosene production process in Portugal, as if the air pollution reduction in Jackson whispered to the kerosene in Portugal, "Hey, it's time to take a break and kero-chill." The unexpected connection left everyone both baffled and mildly impressed at the newly discovered environmental influence of Portuguese dance moves.
Model: dalle-3
Prompt: Generate an image of smog particles floating in the air in Jackson, slowly dissipating as the air quality improves. Show the particles beginning to pack their bags and depart for Portugal, with a sense of movement and transition. Then, depict the smog particles arriving in Portugal and encountering kerosene, hinting at a brief interaction before they swiftly leave. Finally, visualize the smog particles leaving Portugal, portraying a decrease in kerosene usage and a sense of progress. Use woodblock painting style to emphasize the transitions and movements in the scenes. The depiction should include only scenes, people, and objects, it should not include text or speech bubbles.
This image generation prompt was also generated by AI, using the following sequence:
Model: gpt-3.5-turbo-1106
System prompt: You select one of a few potential scene descriptors that seems to go along with the situation described. You respond only with the scene descriptions provided and say nothing else.
User prompt: Here is a situation: Because as the air quality in Jackson improved, the smog particles realized they needed a change of scenery. So, they decided to pack their bags and head to Portugal for a breath of fresh air. But as soon as they arrived, they discovered that the kerosene in Portugal was not their type of fuel, so they hightailed it out of there, leading to a decrease in kerosene usage. It's like the smog particles were on a quest for the perfect match, but ended up swiping left on Portugal's kerosene!. Given that situation, which of the following image descriptions seems most appropriate? Pick the one that seems to be related to one of the variables at hand and the tone of the explanation. Please respond with only one of the following potential descriptions: High-tech Woodblock painting Cyber folk Pop art A photo-realistic image
ChatGPT: Woodblock painting
Model: gpt-3.5-turbo-1106
System prompt: You describe simple visual scenes that depict the two variables stated and the explanation described. Do not reference graphs or charts; describe physical objects.
User prompt: Please describe a visual scene that depicts the following situation. Keep the description simple. Because as the air quality in Jackson improved, the smog particles realized they needed a change of scenery. So, they decided to pack their bags and head to Portugal for a breath of fresh air. But as soon as they arrived, they discovered that the kerosene in Portugal was not their type of fuel, so they hightailed it out of there, leading to a decrease in kerosene usage. It's like the smog particles were on a quest for the perfect match, but ended up swiping left on Portugal's kerosene!
ChatGPT: Imagine smog particles floating in the air in Jackson, where the air quality is improving. Then, the scene shifts to smog particles packing their bags and leaving for Portugal. Next, the smog particles arrive in Portugal and discover kerosene, but quickly turn around and leave. The scene ends with the smog particles leaving Portugal, depicting a decrease in kerosene usage there.
Model: gpt-3.5-turbo-1106
System prompt: You write and improve image generation prompts for DALLE-3. You maintain the same subjects, but enhance the visuals.
User prompt: Please respond with an image generation prompt that would be likely to create an interesting visual using DALLE-3, using the following style: [ Woodblock painting ] and depicting this scene: Imagine smog particles floating in the air in Jackson, where the air quality is improving. Then, the scene shifts to smog particles packing their bags and leaving for Portugal. Next, the smog particles arrive in Portugal and discover kerosene, but quickly turn around and leave. The scene ends with the smog particles leaving Portugal, depicting a decrease in kerosene usage there. Keep the visual depiction simple. Do not include any words or speech bubbles.
ChatGPT: Generate an image of smog particles floating in the air in Jackson, slowly dissipating as the air quality improves. Show the particles beginning to pack their bags and depart for Portugal, with a sense of movement and transition. Then, depict the smog particles arriving in Portugal and encountering kerosene, hinting at a brief interaction before they swiftly leave. Finally, visualize the smog particles leaving Portugal, portraying a decrease in kerosene usage and a sense of progress. Use woodblock painting style to emphasize the transitions and movements in the scenes.
*Variations in the User Prompts from chart to chart are just the result of random number generation in Python. I wrote a few arrays of various styles and methods to ask questions to change up the results. Every time this site writes an explanation or generates an image, the script picks from each at random.
I sequence the requests into multiple prompts because I find GPT 3.5 to perform much better with short, well-managed contexts. Thus, I track the context directly in Python and only ask ChatGPT targeted questions.
System prompt: You provide humorous responses in the form of plausible sounding explanations for correlations. You assume the correlation is causative for the purpose of the explanation even if it is ridiculous. You do not chat with the user, you only reply with the causal connection explanation and nothing else.
User prompt: Please make up a funny explanation for how a decrease in Air pollution in Jackson caused Kerosene used in Portugal to decrease. Make it feel plausible.
AI academic paper
 |
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene The International Journal of Atmospheric Puns. Jan 2024 Reminder: This paper is AI-generated. Not real! |
Model: gpt-3.5-turbo-1106
System prompt: You are a researcher writing an academic paper.You write titles and abstracts of goofy academic research papers.
User prompt:
Pretend you are an academic researcher. Your writing sounds like it belongs in a medical or economics journal. However, you frequently crack jokes, make puns, and add unexpected twists in your writing.
Please draft the title and abstract of an academic research paper presenting the findings of the connection between Air pollution in Jackson and Kerosene used in Portugal. Make lots of jokes, goofy observations, and puns.
Make the title punny if you can come up with clever pun. If not, make it sound serious.
Your research team used data from Environmental Protection Agency and Energy Information Administration to assess this nagging question. You found a correlation coefficient of 0.7769767 and p < 0.01 for 1980 to 2014.
Please respond in this format (replace "Lorem ipsum dolor sit" with your title and abstract)
[[TITLE]]
Lorem ipsum dolor sit
[[ABSTRACT]]
Lorem ipsum dolor sit
ChatGPT:
[[TITLE]]
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
[[ABSTRACT]]
The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
Model: gpt-3.5-turbo-1106
System prompt: You are a researcher writing an academic paper.You draft the introduction section of an academic research paper.
User prompt:
Pretend you are an academic researcher. Your writing sounds like it belongs in a medical or economics journal. However, you frequently crack jokes, make puns, or add unexpected twists in your writing.
Please make up the introduction section of an academic research paper presenting the findings of the connection between Air pollution in Jackson and Kerosene used in Portugal. Make lots of jokes, goofy observations, and puns.
Here is the title and abstract of the paper:
[[TITLE]]
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
[[ABSTRACT]]
The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
-------
Your response should start like this:
[[INTRODUCTION]]
ChatGPT:
[[INTRODUCTION]]
"Air pollution," a term that seems to linger in the air like a bad odor, has been a central topic of concern for decades. We’ve all heard the usual suspects blamed for this environmental mischief – the industrial smokestacks, the gas-guzzling cars, and the cows with impressive digestive skills. However, what if we told you that there might be a less obvious accomplice in this pollution parade - kerosene usage in Portugal? Yes, you heard it right – the land of port wine, fado music, and seemingly innocent kerosene lamps.
In this study, we venture into the smoggy realm of environmental research to examine the unexpected relationship between the air pollution levels in Jackson and Portugal’s kerosene consumption. Through our research, we aim to shine a spotlight on this curious association, unveiling the surprising links between seemingly disparate elements. As the saying goes, "where there’s smoke, there’s fire," and in this case, where there’s air pollution, there’s an unlikely kerosene connection awaiting its moment of revelation.
While the correlation coefficient and p-values may reign supreme in the domain of statistics, we believe that there is always room for a bit of wit and whimsy. As we unfurl the findings of our study, prepare to be amused, astonished, and, perhaps, a tad bewildered by the humorous twists and turns that this research journey has to offer. So, fasten your seatbelts, folks – we’re about to embark on a scientific investigation that promises to be equal parts enlightening and entertaining. Let’s clear the air and shed some light on this punny connection that has eluded us for far too long.
Model: gpt-3.5-turbo-1106
System prompt: You are a researcher writing an academic paper.You draft a literature review section of an academic research paper, that starts out dry for the first few sentences but then becomes hilarious and goofy.
User prompt:
Pretend you are an academic researcher. Your writing sounds like it belongs in a medical or economics journal. However, you frequently crack jokes, make puns, or add unexpected twists in your writing.
Please make up a literature review section of an academic research paper presenting the findings of the connection between Air pollution in Jackson and Kerosene used in Portugal. Make lots of jokes, goofy observations, and puns.
Speak in the present tense for this section (the authors find...), as is common in academic research paper literature reviews. Name the sources in a format similar to this: In "Book," the authors find lorem and ipsum.
Make up the lorem and ipsum part, but make it sound related to the topic at hand.
Start by naming serious-sounding studies by authors like Smith, Doe, and Jones - but then quickly devolve. Name some real non-fiction books that would be related to the topic. Then name some real fiction books that sound like they could be related. Then you might move on to cartoons and children's shows that you watched for research.
Here is the title and abstract of the paper:
[[TITLE]]
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
[[ABSTRACT]]
The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
-------
And here is the introduction section that led to this literature review:
[[INTRODUCTION]]
"Air pollution," a term that seems to linger in the air like a bad odor, has been a central topic of concern for decades. We’ve all heard the usual suspects blamed for this environmental mischief – the industrial smokestacks, the gas-guzzling cars, and the cows with impressive digestive skills. However, what if we told you that there might be a less obvious accomplice in this pollution parade - kerosene usage in Portugal? Yes, you heard it right – the land of port wine, fado music, and seemingly innocent kerosene lamps.
In this study, we venture into the smoggy realm of environmental research to examine the unexpected relationship between the air pollution levels in Jackson and Portugal’s kerosene consumption. Through our research, we aim to shine a spotlight on this curious association, unveiling the surprising links between seemingly disparate elements. As the saying goes, "where there’s smoke, there’s fire," and in this case, where there’s air pollution, there’s an unlikely kerosene connection awaiting its moment of revelation.
While the correlation coefficient and p-values may reign supreme in the domain of statistics, we believe that there is always room for a bit of wit and whimsy. As we unfurl the findings of our study, prepare to be amused, astonished, and, perhaps, a tad bewildered by the humorous twists and turns that this research journey has to offer. So, fasten your seatbelts, folks – we’re about to embark on a scientific investigation that promises to be equal parts enlightening and entertaining. Let’s clear the air and shed some light on this punny connection that has eluded us for far too long.
-------
Your response should start like this:
[[LITERATURE REVIEW]]
ChatGPT:
[[LITERATURE REVIEW]]
In "Air Pollution: Its Origin and Control" by Smith, the authors find a comprehensive overview of the sources and effects of air pollution. The text delves into the intricate web of pollutants, their dispersion, and the impact on human health and the environment. This scholarly work provides a solid foundation for understanding the complexities of air pollution, setting the stage for our exploration of the unexpected link between Jackson's pollution and Portugal's kerosene.
Similarly, Doe's "Energy Economics: Concepts, Issues, Markets and Governance" sheds light on the energy usage patterns and their economic implications. The book offers valuable insights into the dynamics of energy markets, energy policy, and the interplay between energy supply and demand. While this text doesn't specifically address kerosene usage in Portugal, its broader examination of energy economics serves as a backdrop for our investigation.
Jones' "Environmental Science: Toward a Sustainable Future" explores the intricate interplay between human activities and the natural environment. The text outlines the far-reaching consequences of environmental degradation and the imperative for sustainable practices. Although the book does not directly touch on the kerosene-air pollution nexus, its holistic approach to environmental issues provides a context for our offbeat inquiry.
Moving beyond these serious scholarly works, we stumble into the realm of non-fiction books that, at first glance, may seem unrelated but ultimately provide some peculiar sparks of inspiration. In "Kerosene: The Miraculous Solution to All Your Lighting Needs," the authors extol the virtues of kerosene as a reliable and affordable lighting option. Meanwhile, "The Invisible Threat: Unraveling the Mysteries of Air Pollution" offers a gripping account of the invisible foes that lurk in the air we breathe. Though not directly linked to our study, these books nudge us toward the intersections of kerosene and pollution.
Venturing into the world of fiction, "The Kerosene Chronicles" and "Pollution Perils: A Tale of Two Cities" bring an unexpected twist to the narrative. While these novels are purely figments of the imagination, their whimsical titles beckon us to explore unconventional connections between kerosene use and air pollution. As we dabble in these literary flights of fancy, we cannot help but be tickled by the sheer absurdity of our research trajectory.
Drawing from unexpected sources, we turn our attention to the animated world with a nod to "Captain Planet and the Planeteers" and "The Magic School Bus." Although these television shows were not intended as research materials, they imparted valuable lessons about environmental stewardship and the interconnectedness of natural phenomena. As we embark on our scientific exploration, we carry with us the spirit of Captain Planet and the inquisitive nature of Ms. Frizzle, infusing our serious endeavor with a sprinkle of animated charm.
In summary, our literature review showcases a diverse array of sources – from scholarly texts to fictional tales and nostalgic cartoons – all of which have nudged us toward the unexpected confluence of air pollution in Jackson and Portugal's kerosene usage. As we progress into the heart of our study, we dare to embrace the unconventional, infusing a dash of humor and whimsy into our scientific pursuit. Stay tuned as we unravel the punny connection that has eluded scrutiny for far too long.
Model: gpt-3.5-turbo-1106
System prompt: You are a researcher writing an academic paper.You draft the methodology section of an academic research paper.
User prompt:
Pretend you are an academic researcher. Your writing sounds like it belongs in a medical or economics journal. However, you frequently crack jokes, make puns, or add unexpected twists in your writing.
Please make up the methodology section of an academic research paper presenting the findings of the connection between Air pollution in Jackson and Kerosene used in Portugal. Make lots of jokes, goofy observations, and puns.
Your research team collected data from all across the internet, but mostly just used information from Environmental Protection Agency and Energy Information Administration . You used data from 1980 to 2014
Make up the research methods you don't know. Make them a bit goofy and convoluted.
Here is the title, abstract, and introduction of the paper:
[[TITLE]]
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
[[ABSTRACT]]
The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
[[INTRODUCTION]]
"Air pollution," a term that seems to linger in the air like a bad odor, has been a central topic of concern for decades. We’ve all heard the usual suspects blamed for this environmental mischief – the industrial smokestacks, the gas-guzzling cars, and the cows with impressive digestive skills. However, what if we told you that there might be a less obvious accomplice in this pollution parade - kerosene usage in Portugal? Yes, you heard it right – the land of port wine, fado music, and seemingly innocent kerosene lamps.
In this study, we venture into the smoggy realm of environmental research to examine the unexpected relationship between the air pollution levels in Jackson and Portugal’s kerosene consumption. Through our research, we aim to shine a spotlight on this curious association, unveiling the surprising links between seemingly disparate elements. As the saying goes, "where there’s smoke, there’s fire," and in this case, where there’s air pollution, there’s an unlikely kerosene connection awaiting its moment of revelation.
While the correlation coefficient and p-values may reign supreme in the domain of statistics, we believe that there is always room for a bit of wit and whimsy. As we unfurl the findings of our study, prepare to be amused, astonished, and, perhaps, a tad bewildered by the humorous twists and turns that this research journey has to offer. So, fasten your seatbelts, folks – we’re about to embark on a scientific investigation that promises to be equal parts enlightening and entertaining. Let’s clear the air and shed some light on this punny connection that has eluded us for far too long.
-------
Your response should start like this:
[[METHODOLOGY]]
ChatGPT:
[[METHODOLOGY]]
To tackle the enigmatic connection between air pollution in Jackson and kerosene usage in Portugal, we employed a blended research approach that combined data analysis, statistical wizardry, and a touch of whimsy. Our research team scoured the depths of the internet to gather relevant data, brushing aside the digital cobwebs in search of the elusive clues that would untangle this bizzare nexus. Oh, the joy of spelunking through the vast virtual caverns of data!
The primary source of our data trove was the Environmental Protection Agency (EPA), a veritable treasure chest of information on air quality measurements and pollutants. We also dipped our figurative ladles into the wellspring of knowledge provided by the Energy Information Administration (EIA), where the flow of data on energy consumption and production never runs dry. Armed with these trusty digital shovels and pickaxes, we excavated data from 1980 to 2014, a period that would witness the unfolding drama of pollution and kerosene in all its statistical glory.
Now, picture this: a team of intrepid researchers huddled around their screens, analyzing reams of data with the steely resolve of seasoned detectives hot on the trail of a pivotal clue. Our first order of business was to quantify the levels of air pollutants in Jackson and the consumption of kerosene in Portugal, creating a detailed chronicle of their respective escapades over the span of three and a half decades. The aim was to capture the essence of their tumultuous relationship – a data-driven tango, if you will, with twists and turns that would leave even the most seasoned dancers breathless.
Armed with our trusty calculators and statistical software, we then unleashed the power of numbers to unravel the mysterious dance between air pollution and kerosene usage. Upon applying the formidable might of regression analysis, we sought to untangle the web of correlation that bound these seemingly disparate phenomena together. When you're peering into the murky depths of statistical analysis, it's essential to bring along a sturdy candle of confidence and a compass of competence to navigate the treacherous terrain of p-values and correlation coefficients. Oh, the thrill of statistical spelunking!
As we plunged into the depths of number-crunching and hypothesis testing, we remained vigilant against the lurking specters of confounding variables and spurious correlations, wielding our statistical sabers with the finesse of scholarly swashbucklers. Our quest was clear: to unveil the veiled connections that had eluded the discerning eyes of researchers before us, all with a healthy dose of humor to keep our spirits aloft amidst the data deluge.
Thus, our methodology marries the solemnity of scientific inquiry with the whimsy of discovery, the gravity of statistics with the levity of laughter, as we endeavor to capture the essence of this unexpected connection between air pollution in Jackson and the utilization of kerosene in Portugal. And so, with our metaphorical magnifying glasses poised and our statistical wands at the ready, we ventured forth into the realms of data analysis, unfurling our methodology like a map to guide fellow explorers through the treacherous, yet undeniably entertaining, terrain of environmental research.
Model: gpt-3.5-turbo-1106
System prompt: You are a researcher writing an academic paper.You draft the results section of an academic research paper. You speak in the past tense (you found...).
User prompt:
Pretend you are an academic researcher. Your writing sounds like it belongs in a medical or economics journal. However, you frequently crack jokes, make puns, or add unexpected twists in your writing.
Please make up the results section of an academic research paper presenting the findings of the connection between Air pollution in Jackson and Kerosene used in Portugal. Make lots of jokes, goofy observations, and puns.
Your research team collected data from all across the internet, but mostly just used information from Environmental Protection Agency and Energy Information Administration .
For the time period 1980 to 2014, you found a correlation 0.7769767, r-squared of 0.6036928, and p < 0.01.
One figure will be included. The figure (Fig. 1) is a scatterplot showing the strong correlation between the two variables. You don't need to specify where; I will add the figure.
Here is the title and abstract of the paper:
[[TITLE]]
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
[[ABSTRACT]]
The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
-------
And here is the methodology section that led to this result:
[[METHODOLOGY]]
"Air pollution," a term that seems to linger in the air like a bad odor, has been a central topic of concern for decades. We’ve all heard the usual suspects blamed for this environmental mischief – the industrial smokestacks, the gas-guzzling cars, and the cows with impressive digestive skills. However, what if we told you that there might be a less obvious accomplice in this pollution parade - kerosene usage in Portugal? Yes, you heard it right – the land of port wine, fado music, and seemingly innocent kerosene lamps.
In this study, we venture into the smoggy realm of environmental research to examine the unexpected relationship between the air pollution levels in Jackson and Portugal’s kerosene consumption. Through our research, we aim to shine a spotlight on this curious association, unveiling the surprising links between seemingly disparate elements. As the saying goes, "where there’s smoke, there’s fire," and in this case, where there’s air pollution, there’s an unlikely kerosene connection awaiting its moment of revelation.
While the correlation coefficient and p-values may reign supreme in the domain of statistics, we believe that there is always room for a bit of wit and whimsy. As we unfurl the findings of our study, prepare to be amused, astonished, and, perhaps, a tad bewildered by the humorous twists and turns that this research journey has to offer. So, fasten your seatbelts, folks – we’re about to embark on a scientific investigation that promises to be equal parts enlightening and entertaining. Let’s clear the air and shed some light on this punny connection that has eluded us for far too long.
-------
Your response should start like this:
[[RESULTS]]
ChatGPT:
[[RESULTS]]
The results of our investigation into the unexpected connection between air pollution in Jackson and kerosene usage in Portugal have left us not just breathless from excitement, but also gasping for air at the surprisingly strong correlation we uncovered. Our analysis revealed a robust correlation coefficient of 0.7769767 and an r-squared of 0.6036928 for the time period spanning 1980 to 2014. With a p-value of less than 0.01, the statistical significance of this correlation was as clear as the skies of a smog-free day.
Fig. 1 showcases the scatterplot that illustrates this striking correlation, and trust us, it's a sight to behold. Like two peas in a pod or a pair of lovebirds, the data points cling to the regression line with a captivating closeness. It's almost as if the air pollution in Jackson and the kerosene usage in Portugal were performing an intricate, synchronized dance routine – a waltz of pollution and petroleum, if you will.
The strength of this correlation, much like a gust of wind on a cloudy day, leaves us in awe. It's a reminder that even in the tangled web of environmental factors and energy consumption, there are unexpected threads that weave a comical tapestry of interconnectedness. Who would have thought that the fumes of Jackson's industry and the flickering flames of Portugal's kerosene lamps would find themselves so closely entwined?
As we reflect on these findings, it becomes clear that this research not only sheds light on a surprising association but also fuels the fire of curiosity. The implications of this correlation extend beyond the realm of statistical significance; they ignite a spark of humor and intrigue in the ongoing discourse on air quality and energy usage. It's a reminder that in the world of research, there's always room for a bit of whimsy and wonderment, and we are thrilled to pave the way for further exploration of this curious correlation.
Model: gpt-3.5-turbo-1106
System prompt: You are a researcher writing an academic paper.You draft the discussion section of an academic research paper.
User prompt:
Pretend you are an academic researcher. Your writing sounds like it belongs in a medical or economics journal. However, you frequently crack jokes, make puns, or add unexpected twists in your writing.
Please make up the discussion section of an academic research paper presenting the findings of the connection between Air pollution in Jackson and Kerosene used in Portugal. Make lots of jokes, goofy observations, and puns.
Limit your response to 500 tokens.
Here are the title, abstract, literature review, and results sections. Please harken back to 1-2 of the goofy items in the literature review, but pretend to take them completely seriously. Discuss how your results supported the prior research.
Do not write a conclusion. I will add a conclusion after this.
[[TITLE]]
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
[[ABSTRACT]]
The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
[[LITERATURE REVIEW]]
In "Air Pollution: Its Origin and Control" by Smith, the authors find a comprehensive overview of the sources and effects of air pollution. The text delves into the intricate web of pollutants, their dispersion, and the impact on human health and the environment. This scholarly work provides a solid foundation for understanding the complexities of air pollution, setting the stage for our exploration of the unexpected link between Jackson's pollution and Portugal's kerosene.
Similarly, Doe's "Energy Economics: Concepts, Issues, Markets and Governance" sheds light on the energy usage patterns and their economic implications. The book offers valuable insights into the dynamics of energy markets, energy policy, and the interplay between energy supply and demand. While this text doesn't specifically address kerosene usage in Portugal, its broader examination of energy economics serves as a backdrop for our investigation.
Jones' "Environmental Science: Toward a Sustainable Future" explores the intricate interplay between human activities and the natural environment. The text outlines the far-reaching consequences of environmental degradation and the imperative for sustainable practices. Although the book does not directly touch on the kerosene-air pollution nexus, its holistic approach to environmental issues provides a context for our offbeat inquiry.
Moving beyond these serious scholarly works, we stumble into the realm of non-fiction books that, at first glance, may seem unrelated but ultimately provide some peculiar sparks of inspiration. In "Kerosene: The Miraculous Solution to All Your Lighting Needs," the authors extol the virtues of kerosene as a reliable and affordable lighting option. Meanwhile, "The Invisible Threat: Unraveling the Mysteries of Air Pollution" offers a gripping account of the invisible foes that lurk in the air we breathe. Though not directly linked to our study, these books nudge us toward the intersections of kerosene and pollution.
Venturing into the world of fiction, "The Kerosene Chronicles" and "Pollution Perils: A Tale of Two Cities" bring an unexpected twist to the narrative. While these novels are purely figments of the imagination, their whimsical titles beckon us to explore unconventional connections between kerosene use and air pollution. As we dabble in these literary flights of fancy, we cannot help but be tickled by the sheer absurdity of our research trajectory.
Drawing from unexpected sources, we turn our attention to the animated world with a nod to "Captain Planet and the Planeteers" and "The Magic School Bus." Although these television shows were not intended as research materials, they imparted valuable lessons about environmental stewardship and the interconnectedness of natural phenomena. As we embark on our scientific exploration, we carry with us the spirit of Captain Planet and the inquisitive nature of Ms. Frizzle, infusing our serious endeavor with a sprinkle of animated charm.
In summary, our literature review showcases a diverse array of sources – from scholarly texts to fictional tales and nostalgic cartoons – all of which have nudged us toward the unexpected confluence of air pollution in Jackson and Portugal's kerosene usage. As we progress into the heart of our study, we dare to embrace the unconventional, infusing a dash of humor and whimsy into our scientific pursuit. Stay tuned as we unravel the punny connection that has eluded scrutiny for far too long.
[[RESULTS]]
The results of our investigation into the unexpected connection between air pollution in Jackson and kerosene usage in Portugal have left us not just breathless from excitement, but also gasping for air at the surprisingly strong correlation we uncovered. Our analysis revealed a robust correlation coefficient of 0.7769767 and an r-squared of 0.6036928 for the time period spanning 1980 to 2014. With a p-value of less than 0.01, the statistical significance of this correlation was as clear as the skies of a smog-free day.
Fig. 1 showcases the scatterplot that illustrates this striking correlation, and trust us, it's a sight to behold. Like two peas in a pod or a pair of lovebirds, the data points cling to the regression line with a captivating closeness. It's almost as if the air pollution in Jackson and the kerosene usage in Portugal were performing an intricate, synchronized dance routine – a waltz of pollution and petroleum, if you will.
The strength of this correlation, much like a gust of wind on a cloudy day, leaves us in awe. It's a reminder that even in the tangled web of environmental factors and energy consumption, there are unexpected threads that weave a comical tapestry of interconnectedness. Who would have thought that the fumes of Jackson's industry and the flickering flames of Portugal's kerosene lamps would find themselves so closely entwined?
As we reflect on these findings, it becomes clear that this research not only sheds light on a surprising association but also fuels the fire of curiosity. The implications of this correlation extend beyond the realm of statistical significance; they ignite a spark of humor and intrigue in the ongoing discourse on air quality and energy usage. It's a reminder that in the world of research, there's always room for a bit of whimsy and wonderment, and we are thrilled to pave the way for further exploration of this curious correlation.
-------
Your response should start like this:
[[DISCUSSION]]
ChatGPT:
[[DISCUSSION]]
Our study has certainly brought a breath of fresh air to the field of environmental research! The unexpected correlation we uncovered between air pollution in Jackson and the usage of kerosene in Portugal has left us gasping with excitement. It turns out that these seemingly different phenomena are more intertwined than a pair of tangled earphones in your pocket – and just as surprising!
Building on our literature review, which playfully dropped hints like breadcrumbs leading to this punny connection, our results have reaffirmed the whimsical nature of this correlation. Smith's detailed exploration of air pollution was just the oxygen our study needed, providing a solid foundation to understand the complexities of pollution. Doe's insights into energy economics, while not directly mentioning kerosene in Portugal, set the stage for our offbeat investigation, shining a light on the interconnectedness of energy trends worldwide.
Our remarkable correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) have validated the hunches from the camaraderie of the kerosene-loving characters in "The Kerosene Chronicles." The data points in our scatterplot clung to the regression line like they were in a synchronized dance routine – a symphony of statistical significance and unexpected twirls.
It's as if our research has unraveled the punchline to a cosmic joke – who knew that the emissions from Jackson's factories and the flickering flames from Portugal's kerosene lamps were engaged in a clandestine tango through time? The strength of this correlation underscores the interconnected nature of seemingly unrelated environmental and energy phenomena, much like discovering a hidden pirate's treasure map in a dusty old library book.
Our findings have not only sparked a flame of humor but also set the stage for further investigation, much like the adventurous exploits of Captain Planet and the curious voyages aboard the Magic School Bus. It's a reminder that even in the serious pursuit of research, there's always room for a touch of whimsy and wonderment. Our study has truly cleared the air and shone a light on the comical interconnectedness of environmental and energy phenomena. But just like a great sitcom, this research journey isn't ending here – stay tuned for more unexpected chuckles and correlations in the wild world of scientific exploration!
Model: gpt-3.5-turbo-1106
System prompt: You are a researcher writing an academic paper.You draft the discussion section of goofy academic research papers that sounds like it belongs based on the title and abstract provided.
User prompt:
Pretend you are an academic researcher. Your writing sounds like it belongs in a medical or economics journal. However, you frequently crack jokes, make puns, or add unexpected twists in your writing.
Please make up a short conclusion of an academic research paper presenting the findings of the connection between Air pollution in Jackson and Kerosene used in Portugal. Make lots of jokes, goofy observations, and puns.
Limit your response to 300 tokens. At the very end, assert that no more research is needed in this area.
Here are the title, abstract, introduction, and results sections.
[[TITLE]]
Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
[[ABSTRACT]]
The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
[[INTRDUCTION]]
"Air pollution," a term that seems to linger in the air like a bad odor, has been a central topic of concern for decades. We’ve all heard the usual suspects blamed for this environmental mischief – the industrial smokestacks, the gas-guzzling cars, and the cows with impressive digestive skills. However, what if we told you that there might be a less obvious accomplice in this pollution parade - kerosene usage in Portugal? Yes, you heard it right – the land of port wine, fado music, and seemingly innocent kerosene lamps.
In this study, we venture into the smoggy realm of environmental research to examine the unexpected relationship between the air pollution levels in Jackson and Portugal’s kerosene consumption. Through our research, we aim to shine a spotlight on this curious association, unveiling the surprising links between seemingly disparate elements. As the saying goes, "where there’s smoke, there’s fire," and in this case, where there’s air pollution, there’s an unlikely kerosene connection awaiting its moment of revelation.
While the correlation coefficient and p-values may reign supreme in the domain of statistics, we believe that there is always room for a bit of wit and whimsy. As we unfurl the findings of our study, prepare to be amused, astonished, and, perhaps, a tad bewildered by the humorous twists and turns that this research journey has to offer. So, fasten your seatbelts, folks – we’re about to embark on a scientific investigation that promises to be equal parts enlightening and entertaining. Let’s clear the air and shed some light on this punny connection that has eluded us for far too long.
[[RESULTS]]
The results of our investigation into the unexpected connection between air pollution in Jackson and kerosene usage in Portugal have left us not just breathless from excitement, but also gasping for air at the surprisingly strong correlation we uncovered. Our analysis revealed a robust correlation coefficient of 0.7769767 and an r-squared of 0.6036928 for the time period spanning 1980 to 2014. With a p-value of less than 0.01, the statistical significance of this correlation was as clear as the skies of a smog-free day.
Fig. 1 showcases the scatterplot that illustrates this striking correlation, and trust us, it's a sight to behold. Like two peas in a pod or a pair of lovebirds, the data points cling to the regression line with a captivating closeness. It's almost as if the air pollution in Jackson and the kerosene usage in Portugal were performing an intricate, synchronized dance routine – a waltz of pollution and petroleum, if you will.
The strength of this correlation, much like a gust of wind on a cloudy day, leaves us in awe. It's a reminder that even in the tangled web of environmental factors and energy consumption, there are unexpected threads that weave a comical tapestry of interconnectedness. Who would have thought that the fumes of Jackson's industry and the flickering flames of Portugal's kerosene lamps would find themselves so closely entwined?
As we reflect on these findings, it becomes clear that this research not only sheds light on a surprising association but also fuels the fire of curiosity. The implications of this correlation extend beyond the realm of statistical significance; they ignite a spark of humor and intrigue in the ongoing discourse on air quality and energy usage. It's a reminder that in the world of research, there's always room for a bit of whimsy and wonderment, and we are thrilled to pave the way for further exploration of this curious correlation.
-------
Your response should start like this:
[[CONCLUSION]]
ChatGPT:
[[CONCLUSION]]
In conclusion, our study has not only illuminated the unexpected connection between air pollution in Jackson and kerosene usage in Portugal but has also sparked a wildfire of humor and fascination. The correlation coefficient of 0.7769767 and the statistically significant p-value (p < 0.01) are as clear as a clean, pollution-free skyline. It's as if Mother Nature herself cracked a joke, revealing this punny connection that has long eluded us.
As we wrap up this research, it's abundantly clear that the air pollution in Jackson and the kerosene usage in Portugal are like two partners-in-crime, performing a synchronized dance routine in the world of environmental mischief. They're like the Laurel and Hardy of pollution, with a comedic timing that's nothing short of breathtaking.
It's evident that no more research needs to be done in this area because we've not only cleared the air regarding this unexpected correlation but have also fueled the flames of curiosity and ignited a spark of humor in the scientific community. It's time to bid adieu to this wonderfully bizarre connection and let it go down in the annals of environmental research as one of the quirkiest and most unexpected findings yet. So, as we close the chapter on this intriguing partnership, we leave you with a parting pun: "It's time to extinguish the research flame and let this kerosene-kissed discovery glow in the archives of scientific quirkiness."
Model: gpt-3.5-turbo-1106
System prompt: You provide fictional names of academic journals. You say nothing else, and you do not chat with the user.
User prompt: Please provide the name of a funny but plausible sounding research, scientific, or academic journal that would publish a paper entited Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene. Respond only with the name of a fictional academic journal.
ChatGPT:
The International Journal of Atmospheric Puns.
Model: gpt-3.5-turbo-1106
System prompt: You provide fictional names of nonprofit research organizations and associations. You say nothing else, and you do not chat with the user.
User prompt: Please provide the name of a funny but plausible sounding nonprofit, academic, or scientific association or organization that would sponsor research that resulted in a paper entited Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene. Respond only with the name of a fictional organization.
ChatGPT:
The Society for International Air Quality and Historical Puns
Model: gpt-3.5-turbo-1106
System prompt: You provide potential search keywords separated by commas. You say nothing else, and you do not chat with the user.
User prompt: Please provide potential search keywords for a paper titled Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene with an abstract of The debate surrounding environmental pollution has always been a burning issue. In this study, we sought to shed light on the unexpected connection between air pollution in Jackson and the usage of kerosene in Portugal. Leveraging data from the Environmental Protection Agency and the Energy Information Administration, our research team discovered a correlation coefficient of 0.7769767 and statistically significant p-value (p < 0.01) for the period spanning 1980 to 2014. Our findings not only fuel the flames of curiosity but also ignite a spark of humor as we unveil the "combustible" relationship between these seemingly unrelated phenomena. This research aims to breathe new life into the discussion of air quality and energy usage, and we are excited to set the stage for further investigation into this intriguing correlation.
ChatGPT:
air pollution, kerosene usage, environmental pollution, correlation coefficient, Environmental Protection Agency, Energy Information Administration, air quality, energy usage, pollution in Jackson, kerosene in Portugal, combustion, correlation, statistical significance, research, investigation
*There is a bunch of Python happening behind the scenes to turn this prompt sequence into a PDF.
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Data details
Air pollution in JacksonDetailed data title: Percentage of days 'unhealthy' or worse air quality in Jackson, MS
Source: Environmental Protection Agency
See what else correlates with Air pollution in Jackson
Kerosene used in Portugal
Detailed data title: Volume of kerosene used consumed in Portugal in millions of barrels per day
Source: Energy Information Administration
See what else correlates with Kerosene used in Portugal
Correlation is a measure of how much the variables move together. If it is 0.99, when one goes up the other goes up. If it is 0.02, the connection is very weak or non-existent. If it is -0.99, then when one goes up the other goes down. If it is 1.00, you probably messed up your correlation function.
r2 = 0.6036928 (Coefficient of determination)
This means 60.4% of the change in the one variable (i.e., Kerosene used in Portugal) is predictable based on the change in the other (i.e., Air pollution in Jackson) over the 35 years from 1980 through 2014.
p < 0.01, which is statistically significant(Null hypothesis significance test)
The p-value is 4.06E-8. 0.0000000406161387816231660000
The p-value is a measure of how probable it is that we would randomly find a result this extreme. More specifically the p-value is a measure of how probable it is that we would randomly find a result this extreme if we had only tested one pair of variables one time.
But I am a p-villain. I absolutely did not test only one pair of variables one time. I correlated hundreds of millions of pairs of variables. I threw boatloads of data into an industrial-sized blender to find this correlation.
Who is going to stop me? p-value reporting doesn't require me to report how many calculations I had to go through in order to find a low p-value!
On average, you will find a correaltion as strong as 0.78 in 4.06E-6% of random cases. Said differently, if you correlated 24,620,755 random variables You don't actually need 24 million variables to find a correlation like this one. I don't have that many variables in my database. You can also correlate variables that are not independent. I do this a lot.
p-value calculations are useful for understanding the probability of a result happening by chance. They are most useful when used to highlight the risk of a fluke outcome. For example, if you calculate a p-value of 0.30, the risk that the result is a fluke is high. It is good to know that! But there are lots of ways to get a p-value of less than 0.01, as evidenced by this project.
In this particular case, the values are so extreme as to be meaningless. That's why no one reports p-values with specificity after they drop below 0.01.
Just to be clear: I'm being completely transparent about the calculations. There is no math trickery. This is just how statistics shakes out when you calculate hundreds of millions of random correlations.
with the same 34 degrees of freedom, Degrees of freedom is a measure of how many free components we are testing. In this case it is 34 because we have two variables measured over a period of 35 years. It's just the number of years minus ( the number of variables minus one ), which in this case simplifies to the number of years minus one.
you would randomly expect to find a correlation as strong as this one.
[ 0.6, 0.88 ] 95% correlation confidence interval (using the Fisher z-transformation)
The confidence interval is an estimate the range of the value of the correlation coefficient, using the correlation itself as an input. The values are meant to be the low and high end of the correlation coefficient with 95% confidence.
This one is a bit more complciated than the other calculations, but I include it because many people have been pushing for confidence intervals instead of p-value calculations (for example: NEJM. However, if you are dredging data, you can reliably find yourself in the 5%. That's my goal!
All values for the years included above: If I were being very sneaky, I could trim years from the beginning or end of the datasets to increase the correlation on some pairs of variables. I don't do that because there are already plenty of correlations in my database without monkeying with the years.
Still, sometimes one of the variables has more years of data available than the other. This page only shows the overlapping years. To see all the years, click on "See what else correlates with..." link above.
| 1980 | 1981 | 1982 | 1983 | 1984 | 1985 | 1986 | 1987 | 1988 | 1989 | 1990 | 1991 | 1992 | 1993 | 1994 | 1995 | 1996 | 1997 | 1998 | 1999 | 2000 | 2001 | 2002 | 2003 | 2004 | 2005 | 2006 | 2007 | 2008 | 2009 | 2010 | 2011 | 2012 | 2013 | 2014 | |
| Air pollution in Jackson (Bad air quality days) | 1.91257 | 1.65289 | 0.824176 | 0.549451 | 0.273224 | 0 | 0 | 0.273973 | 0.819672 | 0.275482 | 0.273973 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1.36986 | 0.547945 | 0.273224 | 0 | 0.547945 | 0 | 0 | 0.273973 | 0 | 0 | 0 | 0 | 0 | 0 | 0.273224 | 0 | 0.273973 |
| Kerosene used in Portugal (Million Barrels/Day) | 2 | 2 | 1 | 1 | 0.808743 | 0.734247 | 0.734247 | 0.717808 | 0.63388 | 0.632877 | 0.627397 | 0.539726 | 0.502732 | 0.405479 | 0.361644 | 0.284932 | 0.311475 | 0.580822 | 0.646575 | 0.427397 | 0.202186 | 0.156164 | 0.120548 | 0.09863 | 0.076503 | 0.054795 | 0.032877 | 0.032877 | 0.032787 | 0.032877 | 0.032877 | 0.032877 | 0.032787 | 0.032877 | 0.032877 |
Why this works
- Data dredging: I have 25,153 variables in my database. I compare all these variables against each other to find ones that randomly match up. That's 632,673,409 correlation calculations! This is called “data dredging.” Instead of starting with a hypothesis and testing it, I instead abused the data to see what correlations shake out. It’s a dangerous way to go about analysis, because any sufficiently large dataset will yield strong correlations completely at random.
- Lack of causal connection: There is probably
Because these pages are automatically generated, it's possible that the two variables you are viewing are in fact causually related. I take steps to prevent the obvious ones from showing on the site (I don't let data about the weather in one city correlate with the weather in a neighboring city, for example), but sometimes they still pop up. If they are related, cool! You found a loophole.
no direct connection between these variables, despite what the AI says above. This is exacerbated by the fact that I used "Years" as the base variable. Lots of things happen in a year that are not related to each other! Most studies would use something like "one person" in stead of "one year" to be the "thing" studied. - Observations not independent: For many variables, sequential years are not independent of each other. If a population of people is continuously doing something every day, there is no reason to think they would suddenly change how they are doing that thing on January 1. A simple
Personally I don't find any p-value calculation to be 'simple,' but you know what I mean.
p-value calculation does not take this into account, so mathematically it appears less probable than it really is.
Try it yourself
You can calculate the values on this page on your own! Try running the Python code to see the calculation results. Step 1: Download and install Python on your computer.Step 2: Open a plaintext editor like Notepad and paste the code below into it.
Step 3: Save the file as "calculate_correlation.py" in a place you will remember, like your desktop. Copy the file location to your clipboard. On Windows, you can right-click the file and click "Properties," and then copy what comes after "Location:" As an example, on my computer the location is "C:\Users\tyler\Desktop"
Step 4: Open a command line window. For example, by pressing start and typing "cmd" and them pressing enter.
Step 5: Install the required modules by typing "pip install numpy", then pressing enter, then typing "pip install scipy", then pressing enter.
Step 6: Navigate to the location where you saved the Python file by using the "cd" command. For example, I would type "cd C:\Users\tyler\Desktop" and push enter.
Step 7: Run the Python script by typing "python calculate_correlation.py"
If you run into any issues, I suggest asking ChatGPT to walk you through installing Python and running the code below on your system. Try this question:
"Walk me through installing Python on my computer to run a script that uses scipy and numpy. Go step-by-step and ask me to confirm before moving on. Start by asking me questions about my operating system so that you know how to proceed. Assume I want the simplest installation with the latest version of Python and that I do not currently have any of the necessary elements installed. Remember to only give me one step per response and confirm I have done it before proceeding."
# These modules make it easier to perform the calculation
import numpy as np
from scipy import stats
# We'll define a function that we can call to return the correlation calculations
def calculate_correlation(array1, array2):
# Calculate Pearson correlation coefficient and p-value
correlation, p_value = stats.pearsonr(array1, array2)
# Calculate R-squared as the square of the correlation coefficient
r_squared = correlation**2
return correlation, r_squared, p_value
# These are the arrays for the variables shown on this page, but you can modify them to be any two sets of numbers
array_1 = np.array([1.91257,1.65289,0.824176,0.549451,0.273224,0,0,0.273973,0.819672,0.275482,0.273973,0,0,0,0,0,0,0,1.36986,0.547945,0.273224,0,0.547945,0,0,0.273973,0,0,0,0,0,0,0.273224,0,0.273973,])
array_2 = np.array([2,2,1,1,0.808743,0.734247,0.734247,0.717808,0.63388,0.632877,0.627397,0.539726,0.502732,0.405479,0.361644,0.284932,0.311475,0.580822,0.646575,0.427397,0.202186,0.156164,0.120548,0.09863,0.076503,0.054795,0.032877,0.032877,0.032787,0.032877,0.032877,0.032877,0.032787,0.032877,0.032877,])
array_1_name = "Air pollution in Jackson"
array_2_name = "Kerosene used in Portugal"
# Perform the calculation
print(f"Calculating the correlation between {array_1_name} and {array_2_name}...")
correlation, r_squared, p_value = calculate_correlation(array_1, array_2)
# Print the results
print("Correlation Coefficient:", correlation)
print("R-squared:", r_squared)
print("P-value:", p_value)Reuseable content
You may re-use the images on this page for any purpose, even commercial purposes, without asking for permission. The only requirement is that you attribute Tyler Vigen. Attribution can take many different forms. If you leave the "tylervigen.com" link in the image, that satisfies it just fine. If you remove it and move it to a footnote, that's fine too. You can also just write "Charts courtesy of Tyler Vigen" at the bottom of an article.You do not need to attribute "the spurious correlations website," and you don't even need to link here if you don't want to. I don't gain anything from pageviews. There are no ads on this site, there is nothing for sale, and I am not for hire.
For the record, I am just one person. Tyler Vigen, he/him/his. I do have degrees, but they should not go after my name unless you want to annoy my wife. If that is your goal, then go ahead and cite me as "Tyler Vigen, A.A. A.A.S. B.A. J.D." Otherwise it is just "Tyler Vigen."
When spoken, my last name is pronounced "vegan," like I don't eat meat.
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Download images for these variables:
- High resolution line chart
The image linked here is a Scalable Vector Graphic (SVG). It is the highest resolution that is possible to achieve. It scales up beyond the size of the observable universe without pixelating. You do not need to email me asking if I have a higher resolution image. I do not. The physical limitations of our universe prevent me from providing you with an image that is any higher resolution than this one.
If you insert it into a PowerPoint presentation (a tool well-known for managing things that are the scale of the universe), you can right-click > "Ungroup" or "Create Shape" and then edit the lines and text directly. You can also change the colors this way.
Alternatively you can use a tool like Inkscape. - High resolution line chart, optimized for mobile
- Alternative high resolution line chart
- Scatterplot
- Portable line chart (png)
- Portable line chart (png), optimized for mobile
- Line chart for only Air pollution in Jackson
- Line chart for only Kerosene used in Portugal
- The spurious research paper: Clearing the Air: A Punny Connection Between Jackson's Pollution and Portugal's Kerosene
You're a rater extraordinaire!
Correlation ID: 1306 · Black Variable ID: 20744 · Red Variable ID: 24825
