With our surface styling now properly configured, we're ready to dive into the analytical capabilities that make Civil 3D such a powerful tool for site analysis. Let's begin by setting up a slope analysis—one of the most critical evaluations for any civil engineering project.

First, we'll change our analysis type to "slopes" from the dropdown menu. This immediately shifts our interface to focus on slope-specific tools and parameters, giving us access to specialized legend options tailored for slope visualization.

You'll notice we now have two legend options available: "slope" and "standard." For slope analysis, the dedicated slope legend provides optimal clarity and industry-standard formatting, so we'll select that option to ensure our output meets professional expectations.

When we navigate to "edit current selection," you'll discover something important: our slope legend operates as a table style—the same fundamental structure we use for parcel tables and other Civil 3D data presentations. This consistency across the platform means skills learned in one area transfer seamlessly to others, making you more efficient as you master the software.

The table style interface reveals several powerful customization tabs. The Information tab controls basic metadata like name and description. The Data Properties section governs text appearance, wrapping behavior, view orientation settings, and table splitting options—particularly useful when dealing with large datasets that span multiple sheets. You can also configure sorting preferences and define text formatting for titles, headers, and data cells, including text height and style specifications that should align with your firm's CAD standards.

Moving to the table structure itself, you'll see the default columns: number, minimum slope, maximum slope, area, and color. These provide comprehensive slope information for most applications. However, Civil 3D offers additional data options if your analysis requires more detail.

By adding a new column and exploring the available properties, you'll find options for surface range data, 2D and 3D area calculations, and granular slope measurements. While these additional parameters can be valuable for specialized analyses, the default configuration typically provides sufficient information for standard slope evaluation. In most cases, you'll want to maintain a clean, readable table that communicates essential information without overwhelming your audience.

The Display and Summary tabs round out the table customization options, allowing you to control which elements appear and how summary information is presented. For this exercise, we'll maintain the default slope legend configuration to focus on the analysis setup process.

Now comes the critical step: defining our slope ranges. Setting this to four ranges provides good granularity without creating excessive complexity. The key is establishing ranges that align with your project's specific requirements and local regulations—different jurisdictions often have varying slope criteria for development feasibility.

Civil 3D intelligently populates the minimum and maximum slope values based on your actual surface data, providing a realistic foundation for your range definitions. While the interface may still display "scheme reds" in the dropdown, note that we're actually using a rainbow color scheme—this is a common display quirk that doesn't affect the actual analysis output.

The "scale scheme to fit" option automatically distributes your color scheme across your defined ranges, which can be helpful for quick visualizations. However, manually setting ranges often provides more meaningful results aligned with engineering standards and regulatory requirements.

Let's establish practical slope ranges. For our first range, we'll set 0 to 25%—typically representing areas suitable for standard development with minimal grading requirements. To do this, simply modify the maximum slope value to 25% and press Enter.

Here's where understanding Civil 3D's logic becomes crucial: when defining subsequent ranges, you must ensure logical progression. If you attempt to set a minimum value that equals or exceeds the maximum value, Civil 3D will flag this as an error—a safeguard that prevents invalid range definitions that could compromise your analysis.

For our second range, we'll establish 25% to 35%—representing moderately steep slopes that may require additional engineering considerations. Set the maximum value to 35% first, then Civil 3D will automatically adjust the minimum to 25%, creating a seamless transition from the previous range.

Our third range will span 35% to 45%—typically indicating significant slope challenges requiring specialized design approaches and potentially increased construction costs. Again, set the maximum to 45%, and the system handles the logical progression.

The final range captures everything above 45%, extending to the surface maximum of 476.37%—representing extremely steep or vertical conditions that may be undevelopable or require significant retaining structures.

When you click Apply, Civil 3D processes the entire surface and applies your color-coded analysis. The results provide immediate visual feedback: red areas indicate gentle slopes (0-25%) ideal for development, green shows moderate slopes (25-35%) requiring careful design consideration, aqua represents challenging slopes (35-45%) demanding specialized solutions, and purple highlights extreme slopes (45%+) that present significant engineering challenges.

You may notice small triangular shapes in the analysis—these reflect the underlying TIN structure of your surface model. Each triangle represents a facet of the triangulated irregular network, and the color indicates that facet's calculated slope. Understanding this relationship helps you interpret the analysis results and explains why some areas show sharp color transitions along triangle edges.

With our slope analysis complete and saved, we're ready to move forward with generating the professional table output that will communicate these findings effectively in our construction documents. The next phase involves placing and formatting this analytical data within our drawing environment.