Free bond convexity calculator — compute convexity and combine it with duration for accurate price-change estimates when interest rates move significantly.
Bond convexity measures the curvature in the price-yield relationship. While duration provides a linear approximation of price sensitivity, convexity captures the second-order effect, improving the estimate when yields change by more than a few basis points. Positive convexity is desirable because it means bond prices rise more when yields fall than they decline when yields rise.
Our Bond Convexity Calculator computes both the convexity measure and the combined duration-plus-convexity price-change estimate. Enter your bond parameters and a hypothetical yield shift to see how much the convexity adjustment matters. Convexity measures the curvature in the price-yield relationship that duration alone misses. For bonds with significant convexity, a simple duration estimate underestimates price gains when rates fall and overestimates losses when rates rise. This calculator computes both modified duration and convexity, then combines them to show the adjusted price change for any given interest rate shift. Understanding convexity is particularly valuable for investors holding callable bonds, mortgage-backed securities, or long-maturity instruments where the nonlinear effect becomes pronounced.
Duration alone underestimates price gains when rates fall and overestimates losses when rates rise. For large yield swings or long-maturity bonds, the error can be substantial. Adding convexity corrects the approximation and gives portfolio managers a far more reliable estimate of how bond values will change. Understanding convexity also helps investors evaluate callable bonds, where negative convexity caps upside potential.
Convexity = (1 / (P × (1+y)^2)) × Sum[t(t+1) × PV(CF_t), t=1..n]. Price Change with Convexity ≈ [-ModDur × Dy + 0.5 × Convexity × Dy^2] × Price, where Dy is the yield change in decimal form.
Result: Convexity 223.4 / Duration-Convexity Price Change -$208.15
A 20-year, 5% bond at 4% yield has a modified duration near 13 and convexity around 223. For a 2% yield increase, duration alone predicts a $355 loss, but adding convexity reduces the estimate to about $310 — a meaningful difference. Without convexity, you overestimate the price decline.
The relationship between a bond price and its yield is not a straight line — it is a curve. Duration measures the slope of this curve at a single point, providing a useful but imperfect linear approximation. Convexity captures the curvature itself, allowing a quadratic fit that is significantly more accurate for larger rate changes.
Consider a 30-year Treasury bond with a modified duration of 20. Duration predicts that a 1% rate rise would cause a 20% price decline. But the actual decline is closer to 18% because of convexity. Over billions of dollars in institutional portfolios, that 2% difference is enormous. Risk managers rely on convexity to set accurate hedges and Value-at-Risk estimates.
All else equal, a bond with higher convexity is more attractive because it offers an embedded benefit from volatility. Some strategies deliberately seek high-convexity positions by favoring bullet (non-callable) bonds, long maturities, and lower coupons. MBS investors, by contrast, must manage the negative convexity inherent in prepayable mortgage pools through hedging or structuring.
Convexity measures how much the price-yield curve bends. If duration is the slope of the curve, convexity is the curvature. More curvature means the bond price falls less than duration predicts when rates rise and gains more when rates fall. It improves the accuracy of price-change estimates beyond what duration alone provides.
Positive convexity means asymmetric payoffs: for equal-sized rate increases and decreases, the price gain from falling rates exceeds the price loss from rising rates. Investors effectively benefit from volatility. This is why traders are willing to pay more for bonds with higher convexity.
Negative convexity occurs with callable bonds and mortgage-backed securities. As rates fall, the issuer is likely to call the bond, capping the price rise. This creates a region where the price-yield curve bends downward — the opposite of the normal convex shape — meaning investors lose the benefit of rate declines.
Convexity matters most for large yield changes (over 50 basis points) and for long-duration bonds. For a 2-year bond with small rate moves, the convexity adjustment is negligible. For a 30-year bond facing a 200 basis-point shift, it can make a difference of several percent of market value.
Duration gives the first-order (linear) estimate of price change, while convexity provides the second-order (quadratic) correction. The combined formula is: ΔP ≈ -ModDur × Δy × P + 0.5 × Convexity × (Δy)^2 × P. This two-term Taylor expansion is much more accurate than duration alone for non-trivial rate moves.
Yes. Portfolio convexity is the weighted average of individual bond convexities, using market-value weights. This allows portfolio managers to target a specific convexity profile by mixing bonds with different maturities, coupons, and embedded options.