Sans Superellipse Onbep 9 is a regular weight, normal width, monoline, upright, normal x-height font.
Keywords: ui design, app interfaces, signage, product branding, data display, clean, modern, technical, friendly, neutral, clarity, system design, modern branding, interface focus, geometric cohesion, rounded corners, squared rounds, geometric, compact, high contrast counters.
A clean sans with a superellipse construction: curves resolve into rounded-rectangle shapes and corners are softly squared rather than fully circular. Strokes stay even and consistent, producing crisp silhouettes and clear counters. Uppercase forms are straightforward and sturdy, while the lowercase shows compact, efficient shapes with rounded terminals and a tidy rhythm. Numerals follow the same squared-round logic, giving them a cohesive, UI-ready feel and stable alignment in text.
Well-suited for interface typography, dashboards, and product UI where clear shapes and consistent stroke weight help maintain legibility. It can also work for modern brand systems, packaging, and wayfinding that benefit from a geometric, rounded-corner aesthetic. The numerals feel particularly apt for settings that mix text and figures, such as navigation, forms, and labels.
The overall tone is modern and quietly technical, with a friendly edge coming from the softened corners. It reads as pragmatic and system-like rather than expressive, suggesting clarity and utility over personality. The geometry adds a contemporary, slightly engineered vibe that still feels approachable.
The design appears intended to provide a contemporary sans that bridges geometric precision and everyday readability. By using squared-round curves and consistent strokes, it aims for a controlled, recognizable texture that holds up in both short labels and longer blocks of text.
Round characters (like O/C/G) lean toward a rounded-rectangle footprint, and joins/terminals consistently avoid sharp points. The design maintains a steady texture in paragraphs, with letterforms that favor legibility and uniformity over calligraphic modulation.