--- name: seaborn description: "Seaborn Statistical Visualization workflow skill. Use this skill when the user needs Seaborn is a Python visualization library for creating publication-quality statistical graphics. Use this skill for dataset-oriented plotting, multivariate analysis, automatic statistical estimation, and complex multi-panel figures with minimal code and the operator should preserve the upstream workflow, copied support files, and provenance before merging or handing off." version: "0.0.1" category: development tags: ["seaborn", "python", "visualization", "library", "for", "creating", "publication-quality", "statistical"] complexity: advanced risk: safe tools: ["codex-cli", "claude-code", "cursor", "gemini-cli", "opencode"] source: community author: "sickn33" date_added: "2026-04-15" date_updated: "2026-04-25" --- # Seaborn Statistical Visualization ## Overview This public intake copy packages `plugins/antigravity-awesome-skills-claude/skills/seaborn` from `https://github.com/sickn33/antigravity-awesome-skills` into the native Omni Skills editorial shape without hiding its origin. Use it when the operator needs the upstream workflow, support files, and repository context to stay intact while the public validator and private enhancer continue their normal downstream flow. This intake keeps the copied upstream files intact and uses the `external_source` block in `metadata.json` plus `ORIGIN.md` as the provenance anchor for review. # Seaborn Statistical Visualization Imported source sections that did not map cleanly to the public headings are still preserved below or in the support files. Notable imported sections: Design Philosophy, Core Plotting Interfaces, Plotting Functions by Category, Multi-Plot Grids, Figure-Level vs Axes-Level Functions, Data Structure Requirements. ## When to Use This Skill Use this section as the trigger filter. It should make the activation boundary explicit before the operator loads files, runs commands, or opens a pull request. - You need publication-quality statistical graphics directly from tabular datasets. - You are exploring multivariate relationships, distributions, or grouped comparisons with minimal plotting code. - You want seaborn's dataset-oriented API and statistical defaults on top of matplotlib. - Use when the request clearly matches the imported source intent: Seaborn is a Python visualization library for creating publication-quality statistical graphics. Use this skill for dataset-oriented plotting, multivariate analysis, automatic statistical estimation, and complex.... - Use when the operator should preserve upstream workflow detail instead of rewriting the process from scratch. - Use when provenance needs to stay visible in the answer, PR, or review packet. ## Operating Table | Situation | Start here | Why it matters | | --- | --- | --- | | First-time use | `metadata.json` | Confirms repository, branch, commit, and imported path through the `external_source` block before touching the copied workflow | | Provenance review | `ORIGIN.md` | Gives reviewers a plain-language audit trail for the imported source | | Workflow execution | `SKILL.md` | Starts with the smallest copied file that materially changes execution | | Supporting context | `SKILL.md` | Adds the next most relevant copied source file without loading the entire package | | Handoff decision | `## Related Skills` | Helps the operator switch to a stronger native skill when the task drifts | ## Workflow This workflow is intentionally editorial and operational at the same time. It keeps the imported source useful to the operator while still satisfying the public intake standards that feed the downstream enhancer flow. 1. Confirm the user goal, the scope of the imported workflow, and whether this skill is still the right router for the task. 2. Read the overview and provenance files before loading any copied upstream support files. 3. Load only the references, examples, prompts, or scripts that materially change the outcome for the current request. 4. Execute the upstream workflow while keeping provenance and source boundaries explicit in the working notes. 5. Validate the result against the upstream expectations and the evidence you can point to in the copied files. 6. Escalate or hand off to a related skill when the work moves out of this imported workflow's center of gravity. 7. Before merge or closure, record what was used, what changed, and what the reviewer still needs to verify. ### Imported Workflow Notes #### Imported: Overview Seaborn is a Python visualization library for creating publication-quality statistical graphics. Use this skill for dataset-oriented plotting, multivariate analysis, automatic statistical estimation, and complex multi-panel figures with minimal code. #### Imported: Design Philosophy Seaborn follows these core principles: 1. **Dataset-oriented**: Work directly with DataFrames and named variables rather than abstract coordinates 2. **Semantic mapping**: Automatically translate data values into visual properties (colors, sizes, styles) 3. **Statistical awareness**: Built-in aggregation, error estimation, and confidence intervals 4. **Aesthetic defaults**: Publication-ready themes and color palettes out of the box 5. **Matplotlib integration**: Full compatibility with matplotlib customization when needed ## Examples ### Example 1: Ask for the upstream workflow directly ```text Use @seaborn to handle . Start from the copied upstream workflow, load only the files that change the outcome, and keep provenance visible in the answer. ``` **Explanation:** This is the safest starting point when the operator needs the imported workflow, but not the entire repository. ### Example 2: Ask for a provenance-grounded review ```text Review @seaborn against metadata.json and ORIGIN.md, then explain which copied upstream files you would load first and why. ``` **Explanation:** Use this before review or troubleshooting when you need a precise, auditable explanation of origin and file selection. ### Example 3: Narrow the copied support files before execution ```text Use @seaborn for . Load only the copied references, examples, or scripts that change the outcome, and name the files explicitly before proceeding. ``` **Explanation:** This keeps the skill aligned with progressive disclosure instead of loading the whole copied package by default. ### Example 4: Build a reviewer packet ```text Review @seaborn using the copied upstream files plus provenance, then summarize any gaps before merge. ``` **Explanation:** This is useful when the PR is waiting for human review and you want a repeatable audit packet. ### Imported Usage Notes #### Imported: Quick Start ```python import seaborn as sns import matplotlib.pyplot as plt import pandas as pd # Load example dataset df = sns.load_dataset('tips') # Create a simple visualization sns.scatterplot(data=df, x='total_bill', y='tip', hue='day') plt.show() ``` ## Best Practices Treat the generated public skill as a reviewable packaging layer around the upstream repository. The goal is to keep provenance explicit and load only the copied source material that materially improves execution. - Data Preparation Always use well-structured DataFrames with meaningful column names: `python # Good: Named columns in DataFrame df = pd.DataFrame({'bill': bills, 'tip': tips, 'day': days}) sns.scatterplot(data=df, x='bill', y='tip', hue='day') # Avoid: Unnamed arrays sns.scatterplot(x=xarray, y=yarray) # Loses axis labels ### 2. - Choose the Right Plot Type Continuous x, continuous y: scatterplot, lineplot, kdeplot, regplot Continuous x, categorical y: violinplot, boxplot, stripplot, swarmplot One continuous variable: histplot, kdeplot, ecdfplot Correlations/matrices: heatmap, clustermap Pairwise relationships: pairplot, jointplot ### 3. - Use Figure-Level Functions for Faceting python # Instead of manual subplot creation sns.relplot(data=df, x='x', y='y', col='category', colwrap=3) # Not: Creating subplots manually for simple faceting ### 4. - Leverage Semantic Mappings Use hue, size, and style to encode additional dimensions: python sns.scatterplot(data=df, x='x', y='y', hue='category', # Color by category size='importance', # Size by continuous variable style='type') # Marker style by type ### 5. - Control Statistical Estimation Many functions compute statistics automatically. - Understand and customize: python # Lineplot computes mean and 95% CI by default sns.lineplot(data=df, x='time', y='value', errorbar='sd') # Use standard deviation instead # Barplot computes mean by default sns.barplot(data=df, x='category', y='value', estimator='median', # Use median instead errorbar=('ci', 95)) # Bootstrapped CI ### 6. - Combine with Matplotlib Seaborn integrates seamlessly with matplotlib for fine-tuning: python ax = sns.scatterplot(data=df, x='x', y='y') ax.set(xlabel='Custom X Label', ylabel='Custom Y Label', title='Custom Title') ax.axhline(y=0, color='r', linestyle='--') plt.tightlayout() ### 7. ### Imported Operating Notes #### Imported: Best Practices ### 1. Data Preparation Always use well-structured DataFrames with meaningful column names: ```python # Good: Named columns in DataFrame df = pd.DataFrame({'bill': bills, 'tip': tips, 'day': days}) sns.scatterplot(data=df, x='bill', y='tip', hue='day') # Avoid: Unnamed arrays sns.scatterplot(x=x_array, y=y_array) # Loses axis labels ``` ### 2. Choose the Right Plot Type **Continuous x, continuous y:** `scatterplot`, `lineplot`, `kdeplot`, `regplot` **Continuous x, categorical y:** `violinplot`, `boxplot`, `stripplot`, `swarmplot` **One continuous variable:** `histplot`, `kdeplot`, `ecdfplot` **Correlations/matrices:** `heatmap`, `clustermap` **Pairwise relationships:** `pairplot`, `jointplot` ### 3. Use Figure-Level Functions for Faceting ```python # Instead of manual subplot creation sns.relplot(data=df, x='x', y='y', col='category', col_wrap=3) # Not: Creating subplots manually for simple faceting ``` ### 4. Leverage Semantic Mappings Use `hue`, `size`, and `style` to encode additional dimensions: ```python sns.scatterplot(data=df, x='x', y='y', hue='category', # Color by category size='importance', # Size by continuous variable style='type') # Marker style by type ``` ### 5. Control Statistical Estimation Many functions compute statistics automatically. Understand and customize: ```python # Lineplot computes mean and 95% CI by default sns.lineplot(data=df, x='time', y='value', errorbar='sd') # Use standard deviation instead # Barplot computes mean by default sns.barplot(data=df, x='category', y='value', estimator='median', # Use median instead errorbar=('ci', 95)) # Bootstrapped CI ``` ### 6. Combine with Matplotlib Seaborn integrates seamlessly with matplotlib for fine-tuning: ```python ax = sns.scatterplot(data=df, x='x', y='y') ax.set(xlabel='Custom X Label', ylabel='Custom Y Label', title='Custom Title') ax.axhline(y=0, color='r', linestyle='--') plt.tight_layout() ``` ### 7. Save High-Quality Figures ```python fig = sns.relplot(data=df, x='x', y='y', col='group') fig.savefig('figure.png', dpi=300, bbox_inches='tight') fig.savefig('figure.pdf') # Vector format for publications ``` ## Troubleshooting ### Problem: The operator skipped the imported context and answered too generically **Symptoms:** The result ignores the upstream workflow in `plugins/antigravity-awesome-skills-claude/skills/seaborn`, fails to mention provenance, or does not use any copied source files at all. **Solution:** Re-open `metadata.json`, `ORIGIN.md`, and the most relevant copied upstream files. Check the `external_source` block first, then restate the provenance before continuing. ### Problem: The imported workflow feels incomplete during review **Symptoms:** Reviewers can see the generated `SKILL.md`, but they cannot quickly tell which references, examples, or scripts matter for the current task. **Solution:** Point at the exact copied references, examples, scripts, or assets that justify the path you took. If the gap is still real, record it in the PR instead of hiding it. ### Problem: The task drifted into a different specialization **Symptoms:** The imported skill starts in the right place, but the work turns into debugging, architecture, design, security, or release orchestration that a native skill handles better. **Solution:** Use the related skills section to hand off deliberately. Keep the imported provenance visible so the next skill inherits the right context instead of starting blind. ### Imported Troubleshooting Notes #### Imported: Troubleshooting ### Issue: Legend Outside Plot Area Figure-level functions place legends outside by default. To move inside: ```python g = sns.relplot(data=df, x='x', y='y', hue='category') g._legend.set_bbox_to_anchor((0.9, 0.5)) # Adjust position ``` ### Issue: Overlapping Labels ```python plt.xticks(rotation=45, ha='right') plt.tight_layout() ``` ### Issue: Figure Too Small For figure-level functions: ```python sns.relplot(data=df, x='x', y='y', height=6, aspect=1.5) ``` For axes-level functions: ```python fig, ax = plt.subplots(figsize=(10, 6)) sns.scatterplot(data=df, x='x', y='y', ax=ax) ``` ### Issue: Colors Not Distinct Enough ```python # Use a different palette sns.set_palette("bright") # Or specify number of colors palette = sns.color_palette("husl", n_colors=len(df['category'].unique())) sns.scatterplot(data=df, x='x', y='y', hue='category', palette=palette) ``` ### Issue: KDE Too Smooth or Jagged ```python # Adjust bandwidth sns.kdeplot(data=df, x='x', bw_adjust=0.5) # Less smooth sns.kdeplot(data=df, x='x', bw_adjust=2) # More smooth ``` ## Related Skills - `@00-andruia-consultant` - Use when the work is better handled by that native specialization after this imported skill establishes context. - `@00-andruia-consultant-v2` - Use when the work is better handled by that native specialization after this imported skill establishes context. - `@10-andruia-skill-smith` - Use when the work is better handled by that native specialization after this imported skill establishes context. - `@10-andruia-skill-smith-v2` - Use when the work is better handled by that native specialization after this imported skill establishes context. ## Additional Resources Use this support matrix and the linked files below as the operator packet for this imported skill. They should reflect real copied source material, not generic scaffolding. | Resource family | What it gives the reviewer | Example path | | --- | --- | --- | | `references` | copied reference notes, guides, or background material from upstream | `references/n/a` | | `examples` | worked examples or reusable prompts copied from upstream | `examples/n/a` | | `scripts` | upstream helper scripts that change execution or validation | `scripts/n/a` | | `agents` | routing or delegation notes that are genuinely part of the imported package | `agents/n/a` | | `assets` | supporting assets or schemas copied from the source package | `assets/n/a` | ### Imported Reference Notes #### Imported: Resources This skill includes reference materials for deeper exploration: ### references/ - `function_reference.md` - Comprehensive listing of all seaborn functions with parameters and examples - `objects_interface.md` - Detailed guide to the modern seaborn.objects API - `examples.md` - Common use cases and code patterns for different analysis scenarios Load reference files as needed for detailed function signatures, advanced parameters, or specific examples. #### Imported: Core Plotting Interfaces ### Function Interface (Traditional) The function interface provides specialized plotting functions organized by visualization type. Each category has **axes-level** functions (plot to single axes) and **figure-level** functions (manage entire figure with faceting). **When to use:** - Quick exploratory analysis - Single-purpose visualizations - When you need a specific plot type ### Objects Interface (Modern) The `seaborn.objects` interface provides a declarative, composable API similar to ggplot2. Build visualizations by chaining methods to specify data mappings, marks, transformations, and scales. **When to use:** - Complex layered visualizations - When you need fine-grained control over transformations - Building custom plot types - Programmatic plot generation ```python from seaborn import objects as so # Declarative syntax ( so.Plot(data=df, x='total_bill', y='tip') .add(so.Dot(), color='day') .add(so.Line(), so.PolyFit()) ) ``` #### Imported: Plotting Functions by Category ### Relational Plots (Relationships Between Variables) **Use for:** Exploring how two or more variables relate to each other - `scatterplot()` - Display individual observations as points - `lineplot()` - Show trends and changes (automatically aggregates and computes CI) - `relplot()` - Figure-level interface with automatic faceting **Key parameters:** - `x`, `y` - Primary variables - `hue` - Color encoding for additional categorical/continuous variable - `size` - Point/line size encoding - `style` - Marker/line style encoding - `col`, `row` - Facet into multiple subplots (figure-level only) ```python # Scatter with multiple semantic mappings sns.scatterplot(data=df, x='total_bill', y='tip', hue='time', size='size', style='sex') # Line plot with confidence intervals sns.lineplot(data=timeseries, x='date', y='value', hue='category') # Faceted relational plot sns.relplot(data=df, x='total_bill', y='tip', col='time', row='sex', hue='smoker', kind='scatter') ``` ### Distribution Plots (Single and Bivariate Distributions) **Use for:** Understanding data spread, shape, and probability density - `histplot()` - Bar-based frequency distributions with flexible binning - `kdeplot()` - Smooth density estimates using Gaussian kernels - `ecdfplot()` - Empirical cumulative distribution (no parameters to tune) - `rugplot()` - Individual observation tick marks - `displot()` - Figure-level interface for univariate and bivariate distributions - `jointplot()` - Bivariate plot with marginal distributions - `pairplot()` - Matrix of pairwise relationships across dataset **Key parameters:** - `x`, `y` - Variables (y optional for univariate) - `hue` - Separate distributions by category - `stat` - Normalization: "count", "frequency", "probability", "density" - `bins` / `binwidth` - Histogram binning control - `bw_adjust` - KDE bandwidth multiplier (higher = smoother) - `fill` - Fill area under curve - `multiple` - How to handle hue: "layer", "stack", "dodge", "fill" ```python # Histogram with density normalization sns.histplot(data=df, x='total_bill', hue='time', stat='density', multiple='stack') # Bivariate KDE with contours sns.kdeplot(data=df, x='total_bill', y='tip', fill=True, levels=5, thresh=0.1) # Joint plot with marginals sns.jointplot(data=df, x='total_bill', y='tip', kind='scatter', hue='time') # Pairwise relationships sns.pairplot(data=df, hue='species', corner=True) ``` ### Categorical Plots (Comparisons Across Categories) **Use for:** Comparing distributions or statistics across discrete categories **Categorical scatterplots:** - `stripplot()` - Points with jitter to show all observations - `swarmplot()` - Non-overlapping points (beeswarm algorithm) **Distribution comparisons:** - `boxplot()` - Quartiles and outliers - `violinplot()` - KDE + quartile information - `boxenplot()` - Enhanced boxplot for larger datasets **Statistical estimates:** - `barplot()` - Mean/aggregate with confidence intervals - `pointplot()` - Point estimates with connecting lines - `countplot()` - Count of observations per category **Figure-level:** - `catplot()` - Faceted categorical plots (set `kind` parameter) **Key parameters:** - `x`, `y` - Variables (one typically categorical) - `hue` - Additional categorical grouping - `order`, `hue_order` - Control category ordering - `dodge` - Separate hue levels side-by-side - `orient` - "v" (vertical) or "h" (horizontal) - `kind` - Plot type for catplot: "strip", "swarm", "box", "violin", "bar", "point" ```python # Swarm plot showing all points sns.swarmplot(data=df, x='day', y='total_bill', hue='sex') # Violin plot with split for comparison sns.violinplot(data=df, x='day', y='total_bill', hue='sex', split=True) # Bar plot with error bars sns.barplot(data=df, x='day', y='total_bill', hue='sex', estimator='mean', errorbar='ci') # Faceted categorical plot sns.catplot(data=df, x='day', y='total_bill', col='time', kind='box') ``` ### Regression Plots (Linear Relationships) **Use for:** Visualizing linear regressions and residuals - `regplot()` - Axes-level regression plot with scatter + fit line - `lmplot()` - Figure-level with faceting support - `residplot()` - Residual plot for assessing model fit **Key parameters:** - `x`, `y` - Variables to regress - `order` - Polynomial regression order - `logistic` - Fit logistic regression - `robust` - Use robust regression (less sensitive to outliers) - `ci` - Confidence interval width (default 95) - `scatter_kws`, `line_kws` - Customize scatter and line properties ```python # Simple linear regression sns.regplot(data=df, x='total_bill', y='tip') # Polynomial regression with faceting sns.lmplot(data=df, x='total_bill', y='tip', col='time', order=2, ci=95) # Check residuals sns.residplot(data=df, x='total_bill', y='tip') ``` ### Matrix Plots (Rectangular Data) **Use for:** Visualizing matrices, correlations, and grid-structured data - `heatmap()` - Color-encoded matrix with annotations - `clustermap()` - Hierarchically-clustered heatmap **Key parameters:** - `data` - 2D rectangular dataset (DataFrame or array) - `annot` - Display values in cells - `fmt` - Format string for annotations (e.g., ".2f") - `cmap` - Colormap name - `center` - Value at colormap center (for diverging colormaps) - `vmin`, `vmax` - Color scale limits - `square` - Force square cells - `linewidths` - Gap between cells ```python # Correlation heatmap corr = df.corr() sns.heatmap(corr, annot=True, fmt='.2f', cmap='coolwarm', center=0, square=True) # Clustered heatmap sns.clustermap(data, cmap='viridis', standard_scale=1, figsize=(10, 10)) ``` #### Imported: Multi-Plot Grids Seaborn provides grid objects for creating complex multi-panel figures: ### FacetGrid Create subplots based on categorical variables. Most useful when called through figure-level functions (`relplot`, `displot`, `catplot`), but can be used directly for custom plots. ```python g = sns.FacetGrid(df, col='time', row='sex', hue='smoker') g.map(sns.scatterplot, 'total_bill', 'tip') g.add_legend() ``` ### PairGrid Show pairwise relationships between all variables in a dataset. ```python g = sns.PairGrid(df, hue='species') g.map_upper(sns.scatterplot) g.map_lower(sns.kdeplot) g.map_diag(sns.histplot) g.add_legend() ``` ### JointGrid Combine bivariate plot with marginal distributions. ```python g = sns.JointGrid(data=df, x='total_bill', y='tip') g.plot_joint(sns.scatterplot) g.plot_marginals(sns.histplot) ``` #### Imported: Figure-Level vs Axes-Level Functions Understanding this distinction is crucial for effective seaborn usage: ### Axes-Level Functions - Plot to a single matplotlib `Axes` object - Integrate easily into complex matplotlib figures - Accept `ax=` parameter for precise placement - Return `Axes` object - Examples: `scatterplot`, `histplot`, `boxplot`, `regplot`, `heatmap` **When to use:** - Building custom multi-plot layouts - Combining different plot types - Need matplotlib-level control - Integrating with existing matplotlib code ```python fig, axes = plt.subplots(2, 2, figsize=(10, 10)) sns.scatterplot(data=df, x='x', y='y', ax=axes[0, 0]) sns.histplot(data=df, x='x', ax=axes[0, 1]) sns.boxplot(data=df, x='cat', y='y', ax=axes[1, 0]) sns.kdeplot(data=df, x='x', y='y', ax=axes[1, 1]) ``` ### Figure-Level Functions - Manage entire figure including all subplots - Built-in faceting via `col` and `row` parameters - Return `FacetGrid`, `JointGrid`, or `PairGrid` objects - Use `height` and `aspect` for sizing (per subplot) - Cannot be placed in existing figure - Examples: `relplot`, `displot`, `catplot`, `lmplot`, `jointplot`, `pairplot` **When to use:** - Faceted visualizations (small multiples) - Quick exploratory analysis - Consistent multi-panel layouts - Don't need to combine with other plot types ```python # Automatic faceting sns.relplot(data=df, x='x', y='y', col='category', row='group', hue='type', height=3, aspect=1.2) ``` #### Imported: Data Structure Requirements ### Long-Form Data (Preferred) Each variable is a column, each observation is a row. This "tidy" format provides maximum flexibility: ```python # Long-form structure subject condition measurement 0 1 control 10.5 1 1 treatment 12.3 2 2 control 9.8 3 2 treatment 13.1 ``` **Advantages:** - Works with all seaborn functions - Easy to remap variables to visual properties - Supports arbitrary complexity - Natural for DataFrame operations ### Wide-Form Data Variables are spread across columns. Useful for simple rectangular data: ```python # Wide-form structure control treatment 0 10.5 12.3 1 9.8 13.1 ``` **Use cases:** - Simple time series - Correlation matrices - Heatmaps - Quick plots of array data **Converting wide to long:** ```python df_long = df.melt(var_name='condition', value_name='measurement') ``` #### Imported: Color Palettes Seaborn provides carefully designed color palettes for different data types: ### Qualitative Palettes (Categorical Data) Distinguish categories through hue variation: - `"deep"` - Default, vivid colors - `"muted"` - Softer, less saturated - `"pastel"` - Light, desaturated - `"bright"` - Highly saturated - `"dark"` - Dark values - `"colorblind"` - Safe for color vision deficiency ```python sns.set_palette("colorblind") sns.color_palette("Set2") ``` ### Sequential Palettes (Ordered Data) Show progression from low to high values: - `"rocket"`, `"mako"` - Wide luminance range (good for heatmaps) - `"flare"`, `"crest"` - Restricted luminance (good for points/lines) - `"viridis"`, `"magma"`, `"plasma"` - Matplotlib perceptually uniform ```python sns.heatmap(data, cmap='rocket') sns.kdeplot(data=df, x='x', y='y', cmap='mako', fill=True) ``` ### Diverging Palettes (Centered Data) Emphasize deviations from a midpoint: - `"vlag"` - Blue to red - `"icefire"` - Blue to orange - `"coolwarm"` - Cool to warm - `"Spectral"` - Rainbow diverging ```python sns.heatmap(correlation_matrix, cmap='vlag', center=0) ``` ### Custom Palettes ```python # Create custom palette custom = sns.color_palette("husl", 8) # Light to dark gradient palette = sns.light_palette("seagreen", as_cmap=True) # Diverging palette from hues palette = sns.diverging_palette(250, 10, as_cmap=True) ``` #### Imported: Theming and Aesthetics ### Set Theme `set_theme()` controls overall appearance: ```python # Set complete theme sns.set_theme(style='whitegrid', palette='pastel', font='sans-serif') # Reset to defaults sns.set_theme() ``` ### Styles Control background and grid appearance: - `"darkgrid"` - Gray background with white grid (default) - `"whitegrid"` - White background with gray grid - `"dark"` - Gray background, no grid - `"white"` - White background, no grid - `"ticks"` - White background with axis ticks ```python sns.set_style("whitegrid") # Remove spines sns.despine(left=False, bottom=False, offset=10, trim=True) # Temporary style with sns.axes_style("white"): sns.scatterplot(data=df, x='x', y='y') ``` ### Contexts Scale elements for different use cases: - `"paper"` - Smallest (default) - `"notebook"` - Slightly larger - `"talk"` - Presentation slides - `"poster"` - Large format ```python sns.set_context("talk", font_scale=1.2) # Temporary context with sns.plotting_context("poster"): sns.barplot(data=df, x='category', y='value') ``` #### Imported: Common Patterns ### Exploratory Data Analysis ```python # Quick overview of all relationships sns.pairplot(data=df, hue='target', corner=True) # Distribution exploration sns.displot(data=df, x='variable', hue='group', kind='kde', fill=True, col='category') # Correlation analysis corr = df.corr() sns.heatmap(corr, annot=True, cmap='coolwarm', center=0) ``` ### Publication-Quality Figures ```python sns.set_theme(style='ticks', context='paper', font_scale=1.1) g = sns.catplot(data=df, x='treatment', y='response', col='cell_line', kind='box', height=3, aspect=1.2) g.set_axis_labels('Treatment Condition', 'Response (μM)') g.set_titles('{col_name}') sns.despine(trim=True) g.savefig('figure.pdf', dpi=300, bbox_inches='tight') ``` ### Complex Multi-Panel Figures ```python # Using matplotlib subplots with seaborn fig, axes = plt.subplots(2, 2, figsize=(12, 10)) sns.scatterplot(data=df, x='x1', y='y', hue='group', ax=axes[0, 0]) sns.histplot(data=df, x='x1', hue='group', ax=axes[0, 1]) sns.violinplot(data=df, x='group', y='y', ax=axes[1, 0]) sns.heatmap(df.pivot_table(values='y', index='x1', columns='x2'), ax=axes[1, 1], cmap='viridis') plt.tight_layout() ``` ### Time Series with Confidence Bands ```python # Lineplot automatically aggregates and shows CI sns.lineplot(data=timeseries, x='date', y='measurement', hue='sensor', style='location', errorbar='sd') # For more control g = sns.relplot(data=timeseries, x='date', y='measurement', col='location', hue='sensor', kind='line', height=4, aspect=1.5, errorbar=('ci', 95)) g.set_axis_labels('Date', 'Measurement (units)') ``` #### Imported: Limitations - Use this skill only when the task clearly matches the scope described above. - Do not treat the output as a substitute for environment-specific validation, testing, or expert review. - Stop and ask for clarification if required inputs, permissions, safety boundaries, or success criteria are missing.