How to Find Your Lactate Threshold

Sven Ahrens2026년 6월 12일

lactate thresholdLTHRthresholdtestingtraining zones

The most practical way for most athletes to find their lactate threshold is a 30-minute solo time trial: warm up, then ride or run as hard as you can sustain for 30 minutes, all by yourself. Your average heart rate over the final 20 minutes is a good estimate of your lactate-threshold heart rate (LTHR). You then use that single number to set every training zone. That is the whole answer. The rest of this article explains what the threshold actually is, why it is the best anchor for your zones, and the other ways to find it when you want pace or power instead of heart rate.

What is lactate threshold?

Your muscles always produce lactate, even at rest. At easy intensities your body clears it as fast as you make it, so blood lactate stays low and steady. As you go harder, production eventually outpaces clearance and lactate starts to accumulate in the blood. The intensity at which that tipping point happens is your lactate threshold.

There are really two landmarks, not one. The first is LT1, the aerobic threshold, where blood lactate first rises clearly above its resting baseline, typically around 2 mmol/L. This marks the top of your truly easy, conversational pace. The second is LT2, the anaerobic threshold (also called the lactate threshold or maximal lactate steady state), where lactate begins climbing steeply and can no longer be held stable, typically around 4 mmol/L. LT2 is the hard ceiling you cannot hold for long, and it is the landmark most threshold tests are chasing.

These two landmarks split your training into the three intensities most modern coaches care about: easy work below LT1, the gray zone between the two, and hard work at or above LT2.

Why is threshold the best anchor for training zones?

Many zone systems are built on percentages of maximum heart rate, but max HR is a poor anchor: it is hard to measure safely, it barely responds to training, and the same percentage means very different things for two athletes with the same max.

Threshold is better because it is a physiological event that you can actually feel and that shifts as you get fitter. Two runners with an identical max HR can have very different thresholds, and the fitter one threshold sits higher. Anchoring your zones to threshold therefore puts the zone boundaries where your physiology actually changes, and it lets the zones move up as your fitness improves. That is why systems like Friel's HR zones and Coggan's power zones are built around threshold rather than max. If you want to see how different systems carve up the range, compare the heart-rate zone models.

How do you do the 30-minute LTHR field test?

This is the field test popularized by coach Joe Friel, and it estimates LT2 heart rate.

Warm up thoroughly, at least 10 to 15 minutes of easy effort with a few short pickups.
Go alone. Racing other people or drafting skews your effort and your heart rate.
Time-trial for 30 minutes at the hardest pace you can hold evenly for the full duration. Do not sprint the first few minutes.
Start the lap or average function at the 10-minute mark and record your average heart rate for the final 20 minutes.

That final-20-minute average is your estimated LTHR. The reason you ignore the first 10 minutes is that heart rate lags effort early on, so including it would drag the average down. Once you have the number, plug it into the calculator below to get your full set of heart-rate zones.

젖산 역치 심박수

165bpm

사이클링 LTHR

존	범위	무엇을 단련하는가
Z1	능동적 회복 ≤ 132 bpm	회복용 스핀; 다리를 풀어줍니다. RPE 1–2, 매우 쉬움.
Z2	지구력 134–147 bpm	유산소 기초와 지방 대사. RPE 3–4, 하루 종일 갈 수 있는 페이스.
Z3	템포 149–153 bpm	유산소 지구력, '스위트'한 꾸준한 운동. RPE 5–6, 편안하게 힘듦.
Z4	역치 155–163 bpm	젖산 역치; 지속 가능한 강도. RPE 7–8, 20–60분 한계.
Z5a	VO₂max 165–168 bpm	최대 유산소 파워. RPE 9, 3–8분 노력.
Z5b	무산소 능력 170–175 bpm	무산소 능력, 짧고 날카로운 노력. RPE 9–10, 30초–3분.
Z5c	신경근 ≥ 177 bpm	스프린트 파워와 신경근 구동력. RPE 10, 전력 질주.

능동적 회복

≤ 132 bpm

지구력

134–147 bpm

템포

149–153 bpm

역치

155–163 bpm

Z5a

VO₂max

165–168 bpm

Z5b

무산소 능력

170–175 bpm

Z5c

신경근

≥ 177 bpm

Z1 · 능동적 회복. 회복용 스핀; 다리를 풀어줍니다. RPE 1–2, 매우 쉬움.

Z2 · 지구력. 유산소 기초와 지방 대사. RPE 3–4, 하루 종일 갈 수 있는 페이스.

Z3 · 템포. 유산소 지구력, '스위트'한 꾸준한 운동. RPE 5–6, 편안하게 힘듦.

Z4 · 역치. 젖산 역치; 지속 가능한 강도. RPE 7–8, 20–60분 한계.

Z5a · VO₂max. 최대 유산소 파워. RPE 9, 3–8분 노력.

Z5b · 무산소 능력. 무산소 능력, 짧고 날카로운 노력. RPE 9–10, 30초–3분.

Z5c · 신경근. 스프린트 파워와 신경근 구동력. RPE 10, 전력 질주.

LTHR 기반 존은 나이 추정치가 아닌 실제 역치에 기준을 두므로 %HRmax보다 더 개인화되어 있습니다. 사이클링과 러닝의 LTHR은 다르므로 종목별로 따로 테스트하세요.
필드 테스트: 워밍업 후 강도 높은 30분 단독 타임 트라이얼을 라이딩하거나 달립니다. LTHR은 마지막 20분의 평균 심박수입니다(Friel 프로토콜).

당신의 개인 맞춤 결과가 담긴 PDF와, 언제든 다시 열 수 있는 QR 코드.

You can read more about how the bands are derived on the LTHR zones page.

How do you find your threshold pace from a race?

If you would rather anchor running zones to pace than to heart rate, you do not need a separate test at all. A recent all-out race result already contains the information. The Daniels-Gilbert VDOT system converts a race time and distance into a single fitness score, then derives your threshold (tempo) pace, easy pace, interval pace, and more from it. A recent 5K, 10K, or half marathon works well. Enter your result in the VDOT calculator to get threshold pace directly, no time trial required.

How do you find threshold power on the bike?

Cyclists usually anchor to power rather than heart rate because power responds instantly and is not affected by heat, fatigue, or caffeine the way heart rate is. The common approach is a 20-minute time trial: take your average power for the 20 minutes and multiply by 0.95 to estimate Functional Threshold Power (FTP), an approximation of the power you could hold for about an hour.

A more robust method is Critical Power, which uses two or three all-out efforts of different durations (for example 3 and 12 minutes) to model the highest power you can sustain aerobically. Critical Power tends to track LT2 more reliably than a single 20-minute test. You can model it on the Critical Power page.

Heart rate, pace, or power: which threshold should you use?

Use the metric that matches your sport and equipment, and do not expect the three to line up perfectly.

Power (cycling, and increasingly running with a footpod) is the most direct measure of output. It reacts immediately and is unaffected by conditions, so it is the best choice when you have a meter.
Pace (running) is direct outdoors on flat ground but lies on hills, in wind, or on trails, where power or heart rate behave better.
Heart rate is available to everyone and reflects internal strain, but it drifts upward over long efforts (cardiac drift), lags sudden changes, and responds to heat, sleep, and caffeine.

Many athletes anchor zones to power or pace for the workout target and watch heart rate as a sanity check. They are measuring the same threshold from different angles.

What are the honest caveats?

The headline numbers are population averages, not laws. The "4 mmol/L" definition of LT2 is a convenient average: real individual thresholds range roughly from 2.5 to 6 mmol/L, so a fixed cutoff misclassifies plenty of people. Field tests inherit this: the 30-minute test estimates threshold well for most athletes but can be off if you pace badly, test on a bad day, or are new to hard efforts and cannot yet push to a true maximum.

Conditions matter too. Heat, altitude, dehydration, illness, and poor sleep all move your numbers, so test in conditions similar to how you train. And thresholds change: retest every 6 to 8 weeks during a training block, because the whole point of training is to push the threshold higher. Treat your number as a working estimate you refine over time, not a permanent verdict.

What about a lab test?

The gold standard is a graded lab test. You exercise at steadily increasing intensities while a technician takes small blood samples (usually from a fingertip or earlobe) at each stage and plots lactate against intensity. This is the only method that measures lactate directly rather than estimating it, and it can pin down both LT1 and LT2 individually instead of assuming a fixed value. If you have access to a sports lab and want precise, personalized landmarks, it is worth doing once. For most athletes, the field tests above get you close enough to train effectively, for free.

Sources

Joe Friel describes the 30-minute time-trial method for estimating lactate-threshold heart rate and the LTHR-based zones derived from it. Jack Daniels and Jimmy Gilbert developed the VDOT system used to derive threshold and training paces from a recent race result.