Assured Clear Distance Ahead

The Assured Clear Distance Ahead (ACDA) is the distance ahead of any terrestrial locomotive device such as a land vehicle,^[1]^[2]^[3] watercraft,^[4]^[5]^[6] skates, or skis,^[7]^[8]^[9]^[10]^[11]^[12]^[13]^[14]^[15]^[16]^[17] although commonly an automobile, which can be seen to be clear of hazards by the driver, within which they should be able to bring the device to a halt;^[18] drivers generally may not pose an "immediate hazard" upon where or when they cannot assure such distance ahead is clear. It is one of the most fundamental principles governing ordinary care and the duty of care for all methods of conveyance, and is frequently used to determine if a driver is in proper control and is a nearly universally implicit consideration in vehicular accident liability.^[19]^[20] The rule is a precautionary trivial burden required to avert the great probable gravity of precious life loss and momentous damage^[21]^[22]^[23]^[24]^[25]^[26]^[27]^[28]—the former of which has a priceless intrinsic value and a pricey to invaluable instrumental value.^[29]^[30] Satisfying the ACDA rule is necessary but not sufficient to comply with the more generalized basic speed law, and accordingly, it may be used as both a layman's criterion and judicial test for courts to use in determining if a particular speed is negligent, but not to prove it is safe. As a spatial standard of care, it also serves as required explicit and fair notice of prohibited conduct so unsafe speed laws are not void for vagueness.^[31]^[32]^[33]

This distance is typically both determined and constrained by the proximate edge of clear visibility, but it may be attenuated to a margin of which beyond hazards may reasonably be expected to spontaneously appear. The rule is the specific spatial case of the common law basic speed rule,^[34] and an application of volenti non fit injuria. The two-second rule may be the limiting factor governing the ACDA, when the speed of forward traffic is what limits the basic safe speed, and a primary hazard of collision could result from following any closer.^[35]

1 ACDA as common law rule or statute
- 1.1 Origins
- 1.2 Present
  - 1.2.1 Universal Standard of Care
2 Determining the ACDA
3 ACDA Rule specific case generalized to the Basic Speed Law
4 Safe speed
- 4.1 Relationship of posted speed limits to the explicitness of driver care standard
5 Famous tragedies
6 "Assurance" beyond proximate edge of clear visibility as transference of liability
7 Derivations
8 Tables of reference constants and safe speeds
9 See also
10 Notes
11 References
- 11.1 Further reading: tertiary sources

ACDA as common law rule or statute

Origins

As with the genesis of most legal doctrine governing problems which precede a legislative solution, the ACDA principle generally originates to decisional precedent by high courts which reasoned general common sense rules of conduct of which naturally follow from the repetitive process of determining specific culpability.^[6]^[22]^[36]^[37]^[38]^[39] Legislation often subsequently followed which either superfluously codified and endorsed or revised these principles,^[5]^[40] of which courts would in turn continue to flesh out the details.^[41]^[42]^[43] By the late 1920s, the term "assured clear distance ahead" came into widespread use as the identity of this standard of care.^[44]^[45] Much of the earliest published record naturally pertains to high stakes wrecks^[6]^[38] among vessels^[46] or vehicles^[47] as defined in those times, though the obvious principle applies to chariots and might in fact be time immemorial.^[34]^[48]^[49]

Present

Horses may still be expected to use the roadways, as well bicycles and automobiles.^[50]^[51]^[52] The former are a regular appearance in both urban areas and in the country, and are commonly exercised by commuters and Amish. Many roads are unchanged since the 1800s while controlled-access highways have been invented specifically for the automobile.^[53] Ships now have marine radar that allows one to view tens of miles beyond the eye. "At common law a motorist is required to regulate his speed so that he can stop within the range of his vision. In numerous jurisdictions, this rule has been incorporated in statutes which typically require that no person shall drive any motor vehicle in and upon any public road or highway at a greater speed than will permit him to bring it to a stop within the assured clear distance ahead."^[19]^[34] Decisional law usually settles the circumstances by which a portion of the roadway is assuredly clear without it being mentioned in statute.^[54] States where the judiciary has explicitly established the state's ACDA law include Indiana,^[55] Iowa,^[43] Kansas,^[56] Louisiana,^[57]^[58] Michigan,^[59]^[60]^[61] New York,^[62] North Carolina,^[63] Ohio,^[42]^[64] Tennessee,^[39]^[65] Vermont,^[66] and Wisconsin.^[38]^[67] California maintains this duty,^[68]^[69]^[70]^[71]^[72]^[73]^[74]^[75] notwithstanding whatever the care of an ordinary person.^[76]^[77]^[78]^[79]^[80]^{[Note 1]}

Many states have further passed statutes which require their courts to more inflexibly weigh the ACDA in their determination of reasonable speed or behavior. Such statutes do so in part by designating ACDA violations as a citable driving offense, thus burdening an offending driver to rebut a presumption of negligence. States with such explicit ACDA standard of care provisions include: Iowa,^[81] Michigan,^[82] Ohio,^[83] Oklahoma,^[84] Pennsylvania,^[85] and Texas.^[86]

States which apply the principle by statute to watercraft on navigable waterways include all 171 member states of the International Maritime Organization,^[87] notwithstanding membership: Great Britain and its common law inheriting Commonwealth of Nations,^[6]^[36] The United States,^[22]^[37]^[41] Florida,^[88] Hawaii,^[89] Illinois,^[90] Louisiana,^[91] Michigan,^[92] Montana,^[93] Oregon,^[94] Texas,^[95] and West Virginia.^[96]

Most state issued driver handbooks either instruct or mention the ACDA rule as required care or safe practice.^[18]^[79]^[97]^[98]^[99]^[100]^[101]^[102]

Explicit ACDA statutes and regulations,^[103] especially those of which create a citable driving or maritime offense, are aimed at preventing harm that could result from potentially negligent behavior—whereas the slightly more obscure common law ACDA doctrine is most easily invoked to remedy actual damages that have already occurred as a result of such negligence. Unsafe speed statutes are immune from being void for vagueness^[33] when they contain explicit ACDA clauses. Explicit and implicit ACDA rules govern millions of North American drivers.

Universal Standard of Care

There has been an increased interest in the ACDA as a universal standard of care^[104]^[105] that has been brought about by recent technological and social changes such as: event data recorders,^[106]^[107] dashcams, self-driving cars,^[108]^[109] safe cities and multi-use movements,^[110]^[111]^[112]^[113]^[114]^[115]^[116]^[117]^[118]^[119]^[120] and a movement to reduce claims by speeders against governments for "dangerous conditions" when operating speeds exceed a roads inferred design speed.^[121]

Collision liability has historically benefited the law profession by being cloaked as a mixture of fact and law, but with EDR's precisely preserving "a state of facts" often repeated with differing trial outcomes, collisions are less a question of fact, but of law.^[104]^[105]^[122]^[123]^[124] Electronic access to precise EDR data and rulings with new ideological modeling tools, can now expose judges as consistent political advocates for differing special road user interests.^[125]^[126]^[127]^[128] Furthermore, the law needs to be clear, precise, and uniform^[129]^[130] at a national level for the panoply of automobile manufacturers with the strict liability for their programming of law-abiding self-driving vehicles.^[108]^[109] It is foreseeable that two self-driving car makes can collide because their algorithm of the law letter is different;^[108] a resolvable issue that has been troubling human drivers for decades. The ACDA is a standard with descriptive mathematics, much of which are used in reverse by road engineers when designing or re-engineering roads to a speed criteria—for which its users were expected to follow.^[131]

In a trend epitomized by the Great American streetcar scandal,^[128]^[132] and accelerated by red scare^[133] hysteria, automobile interests became very powerful through the 1980s, even filing one-sided amicus curiae briefs to narrow precedent making it difficult for all prior types of users to exercise their easement to the roadways; its goal was towards making all roads controlled-access highways. In at least one jurisdiction, it could no longer be said "as a matter of law" whether a cyclist is a discernible object for which a motorist with proper lookout had a duty see; an intolerant jury could fault a cyclist for "being in the way" notwithstanding that objects are less discernible and more "sudden" as one travels with reckless speed.^[64] Common law precedent was eroded through the creation of distinctions where none really exists (i.e. visibility of cyclist v.s. pedestrian v.s. warning triangle). These successes in-part contributed to mass congestion, smog, high fuel prices, and obesity, which waned the power of this lobby, and now green multi-modal transportation is Federally encouraged.^[111]^[112]^[113]^[114] The ACDA common law rule is more critical than ever to public safety in such multi-modal environment. A continued lack of such standard, or its effective enforcement by both police and judges may substantially diminish the legality of humans ever driving in the future.^[134]^[135]^[136]^[137]^[138]

Determining the ACDA

Static ACDA

Forward "line-of-sight" distance

The range of visibility of which is the de facto ACDA, is usually that distance before which an ordinary person can see small hazards—such as a traffic cone or buoy—with 20/20 vision. This distance may be attenuated by specific conditions such as atmospheric opacity,^[72] blinding glare,^[139] darkness,^[18]^[73] road design,^[71]^[140] and adjacent environmental hazards including civil and recreational activities,^[34] horse-drawn vehicle,^[51] ridden animal,^[51] livestock,^[51] deer,^[141] crossing traffic,^[142] and parked cars. The ACDA may also be somewhat attenuated on roads with lower functional classification.^[25]^[34]^[140] This is because the probability of spontaneous traffic increases proportionally to the density of road access points, and this density reduces the distance a person exercising ordinary care can be assured that a road will be clear; such reduction in the ACDA is readily apparent from the conditions, even when a specific access point or the traffic thereon is not.^[143]^{[Note 2]} Furthermore, even though a through-driver may typically presume all traffic will stay assuredly clear when required by law, such driver may not take such presumption when circumstances provide actual knowledge under ordinary care that such traffic cannot obey the law.^[143] During times of darkness, one can see ahead about 250 feet with low beams, and about 350–500 feet with high beams.^[18] This clear distance corresponds to a maximum safe speed of 52 mph and 65-81 mph respectively on dry pavement with good tires,^[144] which is attenuated further by convex and lateral road curvature; safe speed is always dynamic.

Intersections

As a corollary to the rule that drivers generally may not pose an "immediate hazard" upon where or when they cannot assure such distance ahead is clear, it follows that others may presume that no vehicle is posing an "immediate hazard" from beyond where they can see with proper lookout. Where there are cross roads or side roads with view obstructions, the assured clear distance terminates at the closest path of potential users of the roadway until there is such a view which assures the intersection will remain clear. In such situations, approach speed must be reduced in preparation for entering or crossing a road or intersection or the unmarked pedestrian crosswalks^[145]^[146] and bike paths^[147] they create because of potential hazards.^[148]^[149]^[150]^[151]^[152]^[153] This jurisprudence arises in-part because of the known difficulty in estimating the distance and velocity of an approaching vehicle,^[153]^[154]^[155] which is psychophysically explained by its small angular size and belated divergence from an asymptotically null rate of expansion, which is beyond the subtended angular velocity detection threshold (SAVT) limits of visual acuity^[156]^[157]^[158]^[159]^[160] by way of the Stevens' power law^[159] and Weber–Fechner law, until the vehicle may be dangerously close; subjective constancy and the visual angle illusion^[161] may also play a role.^{[Note 3]}^{[Note 4]} Vehicles that are approaching an intersection from beyond the SAVT limit cannot be reliably distinguished between moving or parked, though they may be traveling at such an imprudent speed as to pose an immediate hazard. In this circumstance, it is impossible for the entering driver to have fair notice that his or her contemplated conduct is forbidden by such hazard,^[31]^[155] and any legal expectation to the contrary would implicate violating the vagueness doctrine of the US Constitution.^[31]^{[Note 5]} It is the duty of the through-driver to slow down^[80]^[149]^[150]^[151] and apply the ACDA principle specifically to the intersection.^[18]^[34]^[49]^[140]^[142] See Table of detection thresholds.

When approaching an un-signalized intersection controlled by a stop sign, the assured clear distance ahead is:

ACDA_{si}=V ( \sqrt{\frac{2d_i}{a_i}} + t_{pc} )

Normal acceleration " $a i$ " for a passenger vehicle from a stop up to 20 mph is about 0.15g, with more than 0.3g being difficult to exceed.^[148] The distance " $d i$ " is the sum of the measured limit line setback distance—which is typically regulated by a Manual on Uniform Traffic Control Devices, at often between 4 and 30 feet in the United States^[162]^[163]^[164]—and the crosswalk, parking lane, and road shoulder width. A vehicle accelerating from a stop travels this distance in time $t i = \sqrt 2d i ⁄ a i$ while through traffic travels a distance equal to their speed multiplied by that time. The time $t pc$ , for the stopped motorist, is the sum of perception time and the time required to actuate an automatic transmission or shift to first gear which is usually between $ 1 ⁄ 2$ to one second.^[165]

ACDA as a function of horizontal sight distance

Horizontal clearance is measured from the edge of the traveled way to the bottom of the nearest object, tree trunk or shrub foliage mass face, plant setback, or mature growth.^[131]^[166] Horizontal sight distance is not to be confused with the clear recovery zone which provides hazardous vegetation set-back to allow errant vehicles to regain control, and is exclusive to a mowed and limbed-up forest which can allow adequate sight distance, but unsafe recovery.^[166] The height and lateral distance of plants restrict the horizontal sight distance, at times obscuring wildlife which may be spooked by an approaching vehicle and run across the road to escape with their herd.^[141]^[166] This principle also applies to approaching vehicles and pedestrians at uncontrolled intersections and to a lesser degree by un-signalized intersections controlled by a yield sign. Horizontal sight distance " $d hsd$ " affects the ACDA because the time $ti=<templatestyles src="Sfrac/styles.css" />dhsd/Vi$ it takes for an intercepting object, animal, pedestrian, or vehicle with speed " $V i$ " to transverse this distance after emerging from the proximate edge of lateral visibility affords a vehicle with speed " $V$ " a clear distance of " $V*t i$ ." Thus, the assured clear intercept distance " $ACDA si$ " is:

ACDA_{si}=\frac{V d_{hsd}}{V_i}

The faster one drives, the farther down-road an interceptor must be in order to be able to transverse the horizontal sight distance in time to collide, however this says nothing of whether the vehicle can stop by the end of this type of assured clear distance. Equating this distance to the total stopping distance and solving for speed yields one's maximum safe speed as purely dictated by the horizontal sight distance.

Dynamic "following" distance

The ACDA may also be dynamic as to the moving distance past which a motorist can be assured be to able to stay clear of a foreseeable dynamic hazard—such as to maintain a distance as to be able to safely swerve around a bicyclist should he succumb to a fall—without requiring a full stop beforehand, if doing so could be exercised with due care towards surrounding traffic. Quantitatively this distance is a function of the appropriate time gap and the operating speed: $d ACDA =t gap \cdot v$ . The assured clear distance ahead rule, rather than being subject to exceptions, is not really intended to apply beyond situations in which a vigilant ordinarily prudent person could or should anticipate.^[19] A common way to violate the dynamic ACDA is by tailgating.

Measurement

The most accurate way to determine the ACDA is to directly measure it. Whereas this is impractical, sight distance formulas can be used with less direct measurements as rough baseline estimates. The empirical assured clear distance ahead calculated with computer vision, range finding, traction control, and GIS, such as by properly programming computer hardware used in autonomous cars, can be recorded to later produce or color baseline ACDA and safe speed maps for accident investigation, traffic engineering, and show disparities between safe speed and 85th percentile "operating" speed.^[167] Self-driving cars^[168]^[109] may have a higher safe speed than human driven vehicles for a given ACDA where computer perception-reaction times are nearly instantaneous.

Discretion

The Assured Clear Distance Ahead can be subjective to the baseline estimate of a reasonable person or be predetermined by law. For example, whether one should have reasonably foreseen that a road was not assuredly clear past 75–100 meters because of tractors or livestock which commonly emerge from encroaching blinding vegetation is on occasion dependent on societal experience within the locale. In certain urban environments, a straight, traffic-less, through-street may not necessarily be assuredly clear past the entrance of the nearest visually obstructed intersection as law.^[34]^[140]^[143]^[153] Within the assured clear distance ahead, there is certainty that travel will be free from obstruction which is exclusive of a failure to appreciate a hazard. Collisions generally only occur within one's assured clear distance ahead which are "unavoidable" to them such that they have zero comparative negligence including legal acts of god and abrupt unforeseeably wanton negligence by another party. Hazards which penetrate one's proximate edge of clear visibility and compromise their ACDA generally require evasive action.

Drivers need not and are not required to precisely determine the maximum safe speed from real-time mathematical calculations of sight distances and stopping distances for their particular vehicle.^[154] Motor vehicle operators of average intelligence^[105]^[169] are constantly required to utilize their kinesthetic memory in all sorts of driving tasks including every time they break to a full stop at a stop line in a panoply of conditions.^[69]^[170] Like throwing a softball, one does not have to mathematically calculate a trajectory or firing solution in order to hit a target with repeated accuracy. During the earliest stages of learning how to drive, one develops a memory of when to start breaking (how long it takes) from various speeds in order to stop at the limit line.^[170] While there may be a degree of variance of such skill in seasoned drivers, they generally do not have the discretion in engaging in a behavior such as driving a speed above which no reasonable minds might differ as to whether it is unsafe or that one could come to a stop within the full distance ahead.^[151]^[169]

Seconds of distance to stop rule

Drivers and law enforcement alike can easily^[171] use a rule of thumb to estimate minimal stopping distance in terms of how many seconds of travel ahead at their current speed. For speed " $v$ " in miles per hour, this rule of thumb is as follows:

\color{Sepia}{t\approx\frac{v}{20} + 1 \quad \text{(Seconds of distance to stop rule)}}

If this distance is greater than the ACDA, they need to slow down. While most experienced drivers develop a broad intuition required by everyday breaking,^[170] this rule of thumb can still benefit some to recalibrate expectations for rare hard breaking, particularly from high speeds. Additional simple corrections can be made to compensate for the environment and driving ability. Read more about the Seconds of Distance to Stop Rule.

ACDA Rule specific case generalized to the Basic Speed Law

The ACDA distances are a principal component to be evaluated in the determination of the maximum safe speed (V_BSL) under the basic speed law, without which the maximum safe speed cannot be determined. As mathematical statements are more precise than verbal statements alone,^[21] the relation of the ACDA as a subset of the basic speed rule for land based vehicles may be objectively quantified as follows:

V_{BSL}= \begin{cases} \sqrt{(\mu +e)^2 g^2 t_{prt}^2+ 2 (\mu + e) g d_{ACDA_s} } - (\mu+e) g t_{prt}, & \mbox{if } V_{ACDA_s} \le V_{ACDA_{si1}} \mbox{ or } V_{ACDA_{si2}} \mbox{ or } V_{ACDA_d} \mbox{ or } V_{cs} \mbox{ or } V_{cl}\\ \\ 2 g (\mu + e) (\frac{d_{hsd}}{v_i}-t_{prt}), & \mbox{if } V_{ACDA_{si1}} < V_{ACDA_s} \mbox{ or } V_{ACDA_{si2}} \mbox{ or } V_{ACDA_d} \mbox{ or } V_{cs} \mbox{ or } V_{cl}\\ \\ 2 g (\mu + e )(\sqrt{\frac{2 d_{sl}}{a_i}}+t_{pc}-t_{prt}), & \mbox{if } V_{ACDA_{si2}} < V_{ACDA_s} \mbox{ or } V_{ACDA_{si1}} \mbox{ or } V_{ACDA_d} \mbox{ or } V_{cs} \mbox{ or } V_{cl}\\ \\ \frac{d_{ACDA_d}}{t_g}, & \mbox{if } V_{ACDA_d}< V_{ACDA_s} \mbox{ or } V_{ACDA_{si1}} \mbox{ or } V_{ACDA_{si2}} \mbox{ or } V_{cs} \mbox{ or } V_{cl} \\ \\ \sqrt{ \frac{(\mu+e) g r}{1-\mu e}}, & \mbox{if } V_{cs}<V_{ACDA_s} \mbox{ or } V_{ACDA_{si1}} \mbox{ or } V_{ACDA_{si2}} \mbox{ or } V_{ACDA_d} \mbox{ or } V_{cl} \\ \\ V_{cl}, & \mbox{if } V_{cl}< V_{ACDA_s} \mbox{ or } V_{ACDA_{si 1}} \mbox{ or } V_{ACDA_{si 2}} \mbox{ or } V_{ACDA_d} \mbox{ or } V_{cs} \end{cases}

The value of the variable "e" is the sine of the angle of inclination of the road's slope. For a level road this value is zero, and for small angles it approximates the road's percent grade divided by one hundred.

e=sin(\theta) \approx \theta \approx tan(\theta) = \frac{%grade}{100}

^{[Note 6]}

The maximum velocity permitted by the Assured Clear Distance Ahead is controlling of safe speed (V_BSL) for only the top and two cases. Safe speed may be greater or less than the actual legal speed limit depending upon the conditions along the road.^[148]

^{[Note 7]}

See reference V_BSL derivations for basic physics explanation.

ACDA: forward line-of-sight

For the top case, the maximum speed is governed by the assured clear "line-of-sight", as when the "following distance" aft of forward traffic and "steering control" are both adequate. Common examples include when there is no vehicle to be viewed, or when there is a haze or fog that would prevent visualizing a close vehicle in front. This maximum velocity is denoted by the case variable $V_{ACDA_s}$ , the friction coefficient is symbolized by $\mu$ —and itself a function of the tire type and road conditions, the distance $d_{ACDA_s}$ is the static ACDA, the constant $g$ is the acceleration of gravity, and interval $t_{prt}$ is the perception-reaction time—usually between 1.0 and 2.5 seconds.^[172]^[173]

See Table of safe speed versus forward line-of-sight

ACDA: horizontal line-of-sight

The second case describes the relationship of horizontal sight distance on safe speed. It is the maximum speed at which a vehicle can come to a full stop before an object, with speed V_i, can intercept after having emerged and traveled across the horizontal sight distance "d_hsd." Urban and residential areas have horizontal sight distances that tend to be closely obstructed by parked cars, utility poles, street furnishing, fencing, signage, and landscaping, but have slower intercepting speeds of children, pedestrians, backing cars, and domestic animals. These interceptors combined with dense usage results in collisions that are more probable and much more likely to inflict harm to an outside human life. In rural areas, swift-moving spooked wildlife such as deer,^[141] elk, moose, and antelope are more likely to intercept a roadway at over 30 mph (48 kph). Wildlife will frequently transit across a road before a full stop is necessary, however collisions with large game are foreseeably lethal, and a driver generally has a duty not to harm his or her passengers. The foreseeable intercept speed or defectively designed horizontal sight distance may vary "reasonably" with judicial discretion.

See Table of safe speed versus horizontal line-of-sight

ACDA: intersectional setback

This third case regards safe speed around un-signalized intersections where a driver on an uncontrolled though street has a duty to slow down in crossing an intersection and permit controlled drivers to be able pass through the intersection without danger of collision.^[151] The driver on the through street must anticipate and hence not approach at an unsafe speed which would prevent another driver from being able to enter while traffic was some distance away, or would be unsafe to a driver who has already established control of the intersection under a prudent acceleration a_i, from a stop at a limit line a distance d_sl away.^[165]

ACDA: following distance

The pedantic fourth case applies when the dynamic ACDA "following distance" (d_{ACDA_d}) is less than the static ACDA "line-of-sight" distance (d_{ACDA_s}). A classic instance of this occurs when, from a visibility perspective, it would be safe to drive much faster were it not for a slower-moving vehicle ahead. As such, the dynamic ACDA is governing the basic speed rule, because in maintaining this distance, one cannot drive at a faster speed than that matching the forward vehicle. The "time gap" t_g or "time cushion" is the time required to travel the dynamic ACDA or "following distance" at the operating speed. Circumstances depending, this cushion might be manifested as a two-second rule or three-second rule.

See Table of 2-second following distances

Critical speed

In the fifth case, critical speed V_cs applies when road curvature is the factor limiting safe speed. A vehicle which exceeds this speed will slide out of its lane. Critical speed is a function of curve radius "r," superelevation or banking "e," and friction coefficient "μ;"^[148] the constant "g" again is the acceleration of gravity. However, most motorists will not tolerate a lateral acceleration exceeding 0.3g (μ=0.3) above which many will panic.^[174] Hence, critical speed may not resemble loss of control speed.^[174] Attenuated "side" friction coefficients are often used for computing critical speed.^[166] The formula is frequently approximated without the denominator for low angle banking which may be suitable for nearly all situations except the tightest radius of highway onramps.^[166]^[175] The principle of critical speed is often applied to the problem of traffic calming, where curvature is both used to govern maximum road speed, and used in traffic circles as a device to force drivers to obey their duty to slow down when approaching an intersection.^[149]^[150]

See Table of curvatures and critical speeds

Surface control

The bottom case is invoked when the maximum velocity for surface control V_cl is otherwise reached. Steering control is independent from any concept of clear distance ahead. If a vehicle cannot be controlled so as to safely remain within its lane above a certain speed and circumstance, then it is irrelevant how assuredly clear the distance is ahead. Using the example of the previous case, the safe speed on a curve may be such that a driver experiences a lateral acceleration of less than 0.3g despite that the vehicle may not slide until it experiences 0.8g. Speed wobble, hydroplaning, roll center, fishtailing, jackknife tendencies, potholes, washboarding, frost heaving,^[176] and tire speed rating are other factors limiting V_cl.

Safe speed

Safe speed is the maximum speed permitted by the basic speed law and negligence doctrine. Safe speed is not the same as the 85 percentile operating speed^[177] used by traffic engineers in establishing speed zones.^[148]^[162]^[178]^[179] Fog, snow, or ice can create conditions where most people drive too fast, and chain reaction accidents in such conditions are examples of where large groups of drivers collided because they failed to reduce speed for the conditions.^[148]^[180] The speeds at which most people drive can only be a very rough guide to safe speed,^[148] and an illegal or negligent custom or practice is not in itself excusable.^[76]^[105]^[181] Safe speed approximates the inferred design speed adjusted for environmental alterations and vehicle and person specific factors when V_{ACDA_s} is the limiting factor.^[182] The Solomon curve concept can create an approach-avoidance conflict within the driver who wishes neither to drive faster than is lawful and the conditions allow nor have an unsafe speed discrepancy between other vehicles on the road; it is never legal to go faster than the speed limit, and unilaterally reducing the risk of the latter can lead to a mass crash caused by the former.^[180]

Relationship of posted speed limits to the explicitness of driver care standard

Many people are challenged by the concept of unsafe speed because they find it vague and arbitrary.^[33] It is well known that people instead resolve such challenges by attribute substitution,^[183] which in this case can mean simply emulating the behaviors of others. In accord with the cultural theory of risk, indeed a substantial part of a driver's risk perception comes from comparing their contemplated conduct to the behavior of others; this includes the safeness of a given speed, notwithstanding the actual risk. As a result of this uncorrected vagueness, group behavior can often be in opposition to safe speed and still be governing a hazardous posted speed limit. By Federal law, posted speed limits are generally within 5 mph of the 85th-percentile speed of free-flowing traffic.^[131]^[162]^[178]^[179]^[184] Functionality, this amounts to citizens "voting" a street's speed limit with their gas pedal from the influence of groupshift. As people generally follow explicit rules all the time of which they do not agree, it is often simply a jurisdiction's failure in their law to sufficiently quantify and disseminate fair notice of an explicit standard of care, such as the ACDA rule. Most DMV driver manuals teach the practice, but far fewer states explicitly back it up in their actual statutes and law enforcement.^[18]^[79]^[97]^[98] If drivers were mindful of the ACDA, the operating speed would by definition not exceed the inferred design speed.^[131]^[179] Furthermore, many jurisdictions increasingly distorted^[185] policing focuses on driving while "influenced," often pull-over slower quartile sober night-time drivers moving no faster than they can stop within the radius of their headlights;^[18] this discourages adjusting speed downward from anything but the posted "maximum speed" permitted by law—which is determined as previously described.

Famous tragedies

Actor James Dean's 85 mph car crash, Princess Diana's death, and the sinking of the RMS Titanic^[22]^[41] after colliding with an iceberg at night are all well publicized tragedies which resulted from a failure to maintain an assured clear distance ahead.

"Assurance" beyond proximate edge of clear visibility as transference of liability

A general principle in liability doctrine is than an accident which would not have occurred except for the action or inaction of some person or entity contrary to a duty such as the exercise of proper care was the result of negligence. The liability space from which one can recover^[186] is typically, themselves, other parties, or nobody.^[187] Jurisdictional exceptions permitting one to legally take "assurance" that the distance will be clear beyond the proximate edge of clear visibility and choose such a speed accordingly, transfers classic common law liability from that driver for his or her "blind" actions. This duty to assure clear distance ahead is inevitably transferred, as an externality to everybody or thing else who must instead warn the driver, such as the government, its road engineers, and maintainers.^[77]^[121]^[188]

As it is generally probable and foreseeable that, chance will permit, and at some point there will be an obstruction beyond some driver's line of sight, such an entitlement challenges centuries^[6]^[36] of precedent in negligence doctrine in addition to posing difficult policy and engineering challenges. It also violates the calculus of negligence^[21] because speed is an inherent factor in vehicular accidents which are a leading cause of priceless life loss^[23]^[26]^[27]^[29]^[30]^[153] and lawsuits, and the burden of a precautions speed is radically lower than the former.^[30]

The assumption of risk resulting from the unsafe activity of driving faster than one can stop within one's vision, does not depend ex post facto on what you happened to hit, for which by nature you could not have known; it could have been a moose or a luxury car. Furthermore, modern times still provide no legal remedies for Darwinian misfortune upon the entire class of unwarnable accidents where drivers and their passengers would not have collided into the likes of a moose,^[141] livestock,^[51] fallen tree, rock, jetsam, horse-drawn vehicle,^[51] stalled vehicle,^[189] school bus, garbage truck, mail carrier, snowplow, washout, snow drift, or slid off the road, were it not for their decisions to drive faster than dictated by the assured clear distance ahead. Regardless of what behavior an authority might encourage by fabricating new rights, it remains timeless that constituents cannot sue the wind for causing a wreck when it inevitably violates a "modern right to drive faster than permitted by the ACDA" by failing to warning them it knocked down a tree in a forest with lots of trees which all eventually fall down. In this specific regard, jurisdictions which grant drivers the liberty to be fools from their own folly, are also condoning the collateral damage and life loss which is expected to occur. Moreover, modern life-entrusting consumers of driving services and driver-less cars^[109] who suffer such caused injury are left without legal remedy for foreseeable outcome of imprudent speed; this in-turn unnecessarily transfers a substantive portion of the ACDA liability space into act of god, government claims, strict liability, or other findings from legal fiction which the justice system generally abhors. What modern times are changing is that one may assure the distance is clear ahead virtually through the Internet of Things, as smart cars connect to get information from smart highways or pass what they see ahead or measure to traffic behind.^[190] A fundamental corollary of the ACDA rule is that technology, expectations, and desires may modernize, but the laws of physics can not and do not.^[48]^[49] The deceleration coefficients and reactions times may change from conveyance by chariot, horse and buggy, internal combustion engine, electric motor, and by driver-less car, but the equations governing stopping distances are immutable. Finally, where it is the policy of the law not to fault well intending diligent citizens for innocent mistakes,^[154]^[155] human life reaps continued benefit from the ACDA duty of which instills the necessary room to survive uninjured from such foreseeable and excusable error while adding redundancy in the responsibility to avoid a collision; mere unilateral duties laid down to assure the safety of others tend to result in hazardous risk compensation by those unfettered parties^[191] resulting in a moral hazard.

Allowing one to drive faster than their vision permits them to safely stop, results in there being no core standard of care regarding safe speed making unsafe speed laws void for vagueness.^[32] The ACDA minimum standard gives fair notice of what conduct is prohibited, and people of ordinary intelligence can apply their breaking experience or the seconds of distance to stop rule to the distance they can see;^[170] once one is allowed to cruise-on without control beyond the edge of visibility, there is little consensus on what arbitrary speed is unsafe, or what to assume of the vague conditions there-past.^[33]

To be able to guarantee "assurance" beyond proximate edge of clear visibility, in doing so exempting ACDA duty, a road must be designed and maintained such that there is not a chance of obstruction in one's lane beyond the proximate edge of clear visibility. A road's vertical profile must be assured to have such a curvature as not to hide hazards close behind its crests. Discretion for drivers and pedestrians to enter onto a potentially occupied lane from a side street must be assuredly eliminated such as with fences, merge lanes, or signalized access. There must also be an assurance of no opportunity for animals and debris to enter from side lots, and that there are continuous multi-hourly maintenance patrols performed. Furthermore, such road sections must be distinguished from other roads so that the driver could clearly and immediately know when he or she may or may not take such extended "assurance." Few roads might meet these requirements except some of the highest functional classification controlled-access highways such as freeways and autobahns.^[25]

Even if such criteria are met, the law must also exempt driver liability for maintaining clear distance ahead. In most democracies, such liability for failures of the distance to remain clear beyond line of sight would ultimately be transferred to its taxpayers.^[121] This only generally occurs when governments have been tasked by constituents or their courts to take the responsibly to design and maintain roadways that "assure" the distance will be clear beyond the proximate edge of clear visibility. Pressures to make such changes may arise from cultural normalization of deviance and unnecessary risk, misunderstanding the purpose of the road functional classification system, underestimation of increased risk, and reclamation of commute time.^[25]

One of the greatest difficulties created by such an extension of the ACDA is the frequency at which roads reduce their functional classification^[25] unbeknownst to drivers who continue unaware they have lost this extended "assurance" or don't understand the difference. Such nuance in applicable jurisdictions is a prolific source of accidents.^[149] In the United States, there is no explicit road marking promising clear distance beyond line of sight in the Manual on Uniform Traffic Control Devices, although there are signs communicating "limited sight distance," "hill blocks view," "crossroad ahead," and "freeway ends."^[192] A partial solution to this challenge is to remove driver discretion in determining whether the ACDA is extended beyond line of sight, by explicitly designating this law change to certain marked high functional classification roadways having meet strict engineering criteria.^[25]

The ACDA rule is analogous to aviation visual flight rules, and its discussed exception—allowed only in a well regulated control zone—is analogous to instrument flight rules. Unlike both visual and instrumental flight rules, where federal and international administrative law applies seamlessly and uniformly across the states, the ACDA rule governing ground transportation is relatively variegated across states and judicial circuits.^[32]^[62]^[130]^[193]^[194] Primitive patchwork governance over a prominent interstate commercial subject, in a modern era where citizens quickly and more frequently travel father than ever before, creates problems for modern driver-less cars which are programmed, distributed, sold, and traded at national levels.^[129]^[168]^[109] As opposed to a strict standard of care,^[78]^[104]^[105]^[195] delegation of such standard to a jury^[196] assumes the representativeness heuristic^[197] for twelve people to determine ordinary care representative of everyone while ignoring its insensitivity to sample size, which of course when applied to multiple cases involving identical situational circumstances results in many verdicts with opposing extreme views,^[105] which works against the utility of the law by making it arbitrarily vague.^[104]^[105] A national uniformity standard which either administratively lays down the ACDA law as has been done for aircraft, or requires states to legislatively enact in order to receive federal DOT funding as has been done for the national legal drinking age, is a subject of debate for those who argue far more people die in cars than in aircraft.^[23]^[26]^[153]^[198] While group polarization towards safety has shifted the criminal blood alcohol threshold below levels for which the risk is statistically marginal,^[24]^[199] the tolerance for speeding—of which each speed unit increment carries an equatable risk relative to BAC^[24]—remains relatively neglected. Speed is responsible for more crashes and economic loss than is alcohol.^[23] The discrepancy may be partly explained by powerful special interest groups that are lobbying against drunk driving and for loser speed regulation.^[185]^[200]

Derivations

Case 1: Safe speed as a function of forward line-of-sight

Derivation of ACDA 1

Forces on a vehicle skidding down a grade of angle θ.

Starting with Newton's Second Law of Motion and the Laws of Friction:

F_{total} = F_{friction} + F_{gravity} \sin{\theta}

F_{total} = \mu F_{normal} + m g \sin{\theta}

F_{total} = \mu m g \cos{\theta} + m g \sin{\theta}

Equating the net force to mass times acceleration:

F_{total}= m a

\mu m g \cos{\theta} + m g \sin{\theta} = m a

a = g(\mu \cos{\theta} + \sin{\theta})

Invoking the equations of motion and substituting acceleration:

d = \frac{v^2}{ 2 a}

d = \frac{v^2}{ 2 g(\mu \cos{\theta} + \sin{\theta})}

Small-angle approximation:

\sin{\theta} \approx \theta

\cos{\theta} \approx 1 - \frac {\theta^2}{2}

Substituting the small angle approximations, and exploiting that the product of a small angle squared, in radians, with the friction coefficient, θ²μ, is insignificant (for a steep 20% slope and a good friction coef. of 0.8, this equals (.2)²x0.8≈0.03):

d \approx \frac{v^2}{ 2 g[\mu (1 - \frac {\theta^2}{2} ) + \theta]} \approx \frac{v^2}{ 2 g(\mu + \theta)}

Now, the total stopping distance is the sum of the breaking and perception-reaction distances:

d_{total} = d_{breaking} + d_{perception-reaction}

d_{total} \approx \frac{v^2}{ 2 g(\mu + \theta)} + v t_{pr}

Isolating zero as preparation to solve for velocity:

\frac{1}{2 g (\mu + \theta)} v^2 + v t_{prt} - d_{total} \approx 0

Completing the square or invoking the quadratic formula to find the solution:

v \approx \sqrt{(\mu + \theta)^2 g^2 t_{prt}^2+ 2 (\mu + \theta) g d_{total} } - ( \mu + \theta ) g t_{prt}

Use small-angle approximation to obtain a more field-able version of the above solution in terms of percent grade/100 "e" instead of an angle θ in radians:

\theta \approx tan(\theta) = \frac{%grade}{100}

Substituting the angle as described produces the form of the formula of case 1 ():

V_{BSL1} \approx \sqrt{(\mu + e)^2 g^2 t_{prt}^2+ 2 (\mu + e) g d_{ACDA} } - (\mu+e) g t_{prt}

The Basic Speed Law constrains the Assured Clear Distance Ahead to the total stopping distance, and the small angle value of road grades approximates the superelevation "e."

Many roadways are level, in which case the small angle approximations or superelevation may be dropped altogether:

V_{BSL1} = \sqrt{\mu^2 g^2 t_{prt}^2+ 2 \mu g d_{ACDA} } - \mu g t_{prt}

This model ignores the effects of air drag, rolling resistance, lift, and relativity as a vehicle's great momentum and weight dominate these factors; they increase the complexity of the formulas while insubstantially changing the outcomes in practically all driving situations except ultra-low-mass bicycles stopping from inherently dangerously high speeds; usability to the layman and conformance with current standard engineering assumptions^[131]^[144] is the objective and a vehicle's lift factor is often inaccessible. Learn a level ground model with most of those effects here or read about the automobile drag coefficient.

Case 2: Safe speed as a function of horizontal line-of-sight

Derivation of ACDA 2

The time required for an obstruction with speed v_i to transect the horizontal sight distance d_i:

t = \frac{d_i}{v_i}

The time required to travel down a road at speed v to said obstruction of distance d away:

t= \frac{d}{v}

Equating the two times:

\frac{d}{v} = \frac{d_i}{v_i}

Solving for this distance:

d=\frac{v d_{i}}{v_i}

Equating this to the total stopping distance, which is the sum of breaking and perception-reaction distances:

\frac{v d_{i}}{v_i} = \frac{v^2}{2 g (\mu + e)} + v t_{prt}

Isolating zero, and factoring out a v:

v [ \frac{v}{2 g (\mu + e)} + (t_{prt} - \frac{ d_{i}}{v_i}) ] = 0

Solving for the non-trivial case (or may distribute v in equation above and apply quadratic formula for same result):

\frac{v}{2 g (\mu + e)} + (t_{prt} - \frac{ d_{i}}{v_i}) = 0

The solution to the above equation, which provides the maximum safe speed as a function of horizontal sight distance, intercept velocity, and road-tire friction coefficient:

v = 2 g (\mu + e) ( \frac{ d_{i}}{v_i} - t_{prt})

Case 3: Safe speed as a function of intersectional setback

Derivation of ACDA 3

The time required for a vehicle to enter a controlled intersection from a stop is the sum of the perception time (t_p), the time required to actuate an automatic transmission or shift to first gear (t_c), and the time to accelerate and enter or traverse the road (t_a). The sum of the first two quantities is t_pc.

t= t_p + t_c + t_a = t_{pc} + t_a

The time required for a vehicle entering with acceleration a_i to transect the sum of the setback and shoulder distances d_i under uniform acceleration a_i from a stop via the equations of motion:

t_a =\sqrt{ \frac{ 2 d_i }{a_i} }

The time required to travel down a road at speed v to said obstruction of distance d away:

t= \frac{d}{v}

Equating the two times:

\frac{d}{v} =\sqrt{ \frac{ 2 d_i }{a_i} } + t_{pc}

Solving for this distance:

d = v ( \sqrt{ \frac{ 2 d_i }{a_i} } + t_{pc} )

Equating this to the total stopping distance, which is the sum of breaking and perception-reaction distances:

v ( \sqrt{ \frac{ 2 d_i }{a_i} } + t_{pc} )= \frac{v^2}{2 g (\mu + e)} + v t_{prt}

Isolating zero, and factoring out a v:

v [ \frac{v}{2 g (\mu + e)} + (t_{prt} - \sqrt{ \frac{ 2 d_i }{a_i} } - t_{pc} ) ] = 0

Solving for the non-trivial case (or may distribute v in equation above and apply quadratic formula for same result):

\frac{v}{2 g (\mu + e)} + (t_{prt} - \sqrt{ \frac{ 2 d_i }{a_i} } - t_{pc} ) = 0

The solution to the above equation, which provides the maximum safe speed as a function of horizontal setback, intercept acceleration, and road-tire friction coefficient:

v = 2 g (\mu + e) ( \sqrt{ \frac{ 2 d_i }{a_i} } + t_{pc} - t_{prt})

Case 4: Safe speed as a function of following distance

Derivation of ACDA 4

From the equations of motion:

t_g = \frac{d}{v}

Isolating for speed:

v = \frac{d}{t_g}

Case 5: Safe speed as a function of critical speed

Derivation of ACDA 5

Forces on a vehicle skidding down a grade of angle θ.

Starting with Newton's Laws of Motion, the Laws of Friction, and Centripetal force:

F_{centripetal} \cos{ \theta } = F_{friction} + F_{gravity} \sin{\theta}

Substituting formulas for Centripetal force, frictional force, and gravitational force:

m \frac{v^2}{r} \cos{ \theta } = \mu F_{normal} + m g \sin{\theta}

The normal force is equal and opposite to the sum of the gravitational and centripetal components:

m \frac{v^2}{r} \cos{ \theta } = \mu (m g \cos{\theta} + m \frac{v^2}{r} \sin{ \theta } ) + m g \sin{\theta}

Isolate v terms:

\frac{v^2}{r} \cos{ \theta } - \mu \frac{v^2}{r} \sin{ \theta } = g (\mu \cos{\theta} + \sin{\theta} )

Then solve for v:

v^2 ( \cos{ \theta } - \mu \sin{ \theta } ) = g r (\mu \cos{\theta} + \sin{\theta} )

To obtain:

v = \sqrt { \frac{g r (\mu \cos{\theta} + \sin{\theta} ) } { \cos{ \theta } - \mu \sin{ \theta } } }

This is the full solution, however most corners are banked at less than 15 degrees (≈28% grade), so in such conditions, a fieldable small angle approximation may be used.

Substituting small-angle approximations sinθ≈θ, cos≈1-θ²/2:

v \approx \sqrt { \frac{g r [\mu (1- \frac {\theta^2} {2}) + \theta ] } { 1- \frac {\theta^2}{2} - \mu \theta } }

Exploit that a small angle squared, in radians, is insignificant by substituting θ²≈0 which obtains the formula used in case 5 (also tanθ≈e):

v \approx \sqrt { \frac{g r (\mu + \theta ) } { 1 - \mu \theta } } \approx \sqrt { \frac{g r (\mu + e ) } { 1 - \mu e } }

Seconds of distance to stop rule

Derivation of Seconds of distance to stop rule

The Seconds of distance to stop rule is ultimately originated to and proved by the following basic physics:

We first obtain the total stopping distance, and then convert it into travel time—which is more applicable by the driver.

d_{total} = d_{breaking} + d_{perception-reaction}

Invoking the equations of motion

d_{breaking}=\frac{v^2}{2 a}

d_{total} = \frac{v^2}{2 a} + v t_{prt}

where

a=\mu g

The time it takes to casually traverse the stopping distance at the travel speed is

t=\frac{d_{total}}{v}

Substituting the former into the latter

t=\frac{v}{2 \mu g}+t_{prt}

Now this can be simplified into the rule of thumb form

t=C \cdot v + t_{prt}

by noting

C=\frac{v \cdot f}{2 \mu g}

substituting (US Customary units)

\mu \approx \tfrac{7}{10}

(dry) or

\tfrac{5}{10}

(wet) or

\lessapprox \tfrac{2}{10}

(snow);

g \approx 32

,

f=\tfrac{22}{15}

(convert mph to fps);

t_{prt}=1.5

hence

c=\tfrac{1}{30}

(dry),

\tfrac{1}{20}

(wet), and

\tfrac{1}{10}

(snow)

we get seconds of distance to stop rule (in MPH)

t=\frac{v}{30} + 1.5

(dry pavement)

t=\frac{v}{20} + 1.5

(wet pavement)

t=\frac{v}{10} + 1.5

(snow, hard-packed)

The dry rule does allow one to travel faster in dry weather, but expect emergency deceleration to be a bit uncomfortable. If one desires to remember only one rule, use the wet one. However, because the difference between wet and dry is half-a-second at 30 MPH and one second at 60 MPH, and because dividing by two is easier than three, we can use a correctable rule of thumb:

\color{Sepia}{t\approx\frac{v}{20} + 1 \quad \text{(general rule-of-thumb)}}

................(instead add 2+ in wet or complex conditions, and also instead divide by 10 in snow/ice)

The rule is very easy to apply in one's head while driving: simply divide your speed (MPH) by 10 and again by 2, then add 1. That's it! If one is going sixty mph, divide by ten to get 6, then divide by two to get 3; adding a one-second reaction time, we get that you can generally stop beyond 4 seconds of distance ahead. Drivers that require additional perception-reaction time, such as novices, elderly, or those in complex or adverse environments can benefit by adding additional seconds.^[201]^[202]

The time to traverse your stopping distance at travel speed should not be confused with the breaking time to come to a full stop, which is a number nearly twice this value ( $t=<templatestyles src="Sfrac/styles.css" />v/μ g+tptr$ ). As one is continually slowing down while breaking, it will naturally take longer to get to the stopping limit.

A more correct perception-reaction time of one-and-a-half seconds is commonly used by the mathematically inclined.^[144]^[173] Doing so to obtain your "Seconds of distance to stop" for dry pavement and then converting time to actual distance by multiplying it by the travel velocity and $<templatestyles src="Sfrac/styles.css" />22/15$ to convert MPH to fps will yield results in close agreement with this table.

Tables of reference constants and safe speeds

Reference Constants

Table of perception-reaction times

Table of perception-reaction times

**Perception-reaction times [seconds]^[172]^[203]**
Anticipated Object	Unexpected Object	Unexpected signal
0.72	1.28	1.27

Table of tire-roadway friction coefficients

Table of tire-roadway friction coefficients

**Average value of tire friction coefficient^[204]**
Road surface	Peak value (μ_s)	Sliding value (μ_d)
Asphalt and concrete (dry)	0.80 − 0.90	0.75
Asphalt (wet)	0.50 − 0.70	0.45 − 0.60
Concrete (wet)	0.80	0.70
Gravel	0.60	0.55
Earth road (dry)	0.68	0.65
Earth road (wet)	0.55	0.40 − 0.50
Snow (hard-packed)	0.20	0.15
Ice	0.10	0.07

Table of acceleration values

Table of acceleration vales

**Acceleration values^[148]**
Car	Truck	Bicycle
0.15g	0.085-0.138g^[205]

See Car specific accelerations

Table of intercept values

Table of intercept vales

**Approach speeds of hazards which may foreseeably intercept the roadway**
pedestrian(walk/run)	bicycle	cat	dog	deer	elk
3.1-5.6 mph/27.78 mph^[206]	14.7f/s^[207]	29.8 mph	63.5 km/h	48.2 km/h	72.4 km/h

See more animal intercept speeds. See article on speed.

Table of tire speed ratings

Table of tire speed ratings

**Tire speed rating^[208]**
Code	mph	km/h	Code	mph	km/h
A1	3	5	L	75	120
A2	6	10	M	81	130
A3	9	15	N	87	140
A4	12	20	P	94	150
A5	16	25	Q	100	160
A6	19	30	R	106	170
A7	22	35	S	112	180
A8	25	40	T	118	190
B	31	50	U	124	200
C	37	60	H	130	210
D	40	65	V	149	240
E	43	70	Z	over 149	over 240
F	50	80	W	168	270
G	56	90	(W)	over 168	over 270
J	62	100	Y	186	300
K	68	110	(Y)	over 186	over 300

See article on Tire Codes

Safe Speeds

Table of ACDA: forward line-of-sight

Table of ACDA: forward line-of-sight

**Average safe speed as a function of assured clear distance ahead^[144]**
ACDA [meters]	ACDA [feet]	Safe speed [km/h]	Safe speed [mph]
1	3.3	2.3	1.4
2.5	8.2	5.6	3.5
4	13.1	8.6	5.3
5.5	18.0	11.4	7.1
7	23.0	14.1	8.8
8.5	27.9	16.7	10.4
10	32.8	19.1	11.9
15	49	27	16
30	98	45	28
45	148	60	37
60	197	73	45
75	246	84	52
90	295	95	59
105	344	105	65
120	394	114	71
135	443	122	76
150	492	130	81
165	541	138	86
180	591	146	91
195	640	153	95
210	689	160	99
225	738	166	103
240	787	173	107
255	837	179	111
270	886	185	115
285	935	191	119
300	984	197	122

The speed values in this table are produced from the formula using an "average" coefficient of friction (μ) of 0.7, and a perception-reaction time of 1.5 seconds. Speed values specific to a given circumstance can be obtained with the same formula using the appropriate reference constants specific to the circumstance.

Table of ACDA: horizontal line-of-sight

Table of ACDA: horizontal line-of-sight

**Safe speed as a function of horizontal clearance for 9 km/h (5.6 mph) intercept object (i.e. child)**
HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
3.0	10	0	0
4.0	13.1	4.9	3.1
4.5	14.8	14.8	9.2
5.0	16.4	24.7	15.4
5.5	18.0	34.6	21.5
6	20	44	28
7	23	64	40
8	26	84	52
9	30	104	65
10	33	124	77
11	36	143	89
12	39	163	101

This table demonstrates why alleyways, parking lots, parks, and residential areas frequently set 5-15 mph speed limits when the side clearance from the road is less than 15 feet. An urban or residential street which permits a maximum speed limit of 25 mph under its very best conditions (roadsides cleared of visual obstructions past a 20-foot maintained right of way), may in practice be unsafe to drive at more than 10 mph within sections with utilized curbside parking. This table also suggests that the safe speed could be greater than a statutory 25 mph posted speed, where roadside clearance is sufficient such that no "foreseeable" object could emerge from the proximate edge of roadside visibility, transect the cleared area, and intercept the lane before the driver could come to a halt. However, wary road design engineers may have differing views of foreseeable intercept speeds than that reflected by the 85th percentile speed chosen by the public. This can have unfortunate consequences where a mass commuting public is unfamiliar with or does not appreciate specific local hazards. Narrow lane widths are purposely used for traffic calming, because careful drivers universally choose their speed depending on the roadway width.^[209] Standard horizontal clearances are commonly set by AASHTO guidelines or a jurisdiction's department of transportation.^[131]^[210]

**Safe speed as a function of horizontal clearance for 16 km/h (10 mph) intercept object (i.e. domestic animals)**
HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
7	23	4	2
8	26	15	9
9	30	26	16
10	33	37	23
11	36	48	30
12	39	59	37
13	43	70	44
14	46	82	51
15	49	93	58
16	52	104	65
17	56	115	71
18	59	126	78
19	62	137	85
20	66	148	92
21	69	159	99
22	72	171	106
23	75	182	113
24	79	193	120
25	82	204	127

**Safe speed as a function of horizontal clearance for 48.2 km/h (30 mph) intercept object (i.e. deer)**
HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
20	66	0	0
21	69	3	2
22	72	7	4
23	75	11	7
24	79	14	9
25	82	18	11
26	85	22	14
27	89	26	16
28	92	29	18
29	95	33	20
30	98	37	23
31	102	40	25
32	105	44	27
33	108	48	30
34	112	51	32
35	115	55	34
36	118	59	37
37	121	62	39
38	125	66	41
39	128	70	43
40	131	74	46
41	135	77	48
42	138	81	50
43	141	85	53
44	144	88	55
45	148	92	57
46	151	96	59
47	154	99	62
48	157	103	64
49	161	107	66
50	164	110	69

The speed values in these tables are produced from the formula using an "average" coefficient of friction (μ) of 0.7, and a perception-reaction time of 1.5 seconds. Speed values specific to a given circumstance can be obtained with the same formula using the appropriate reference constants specific to the circumstance.

Table of ACDA: intersectional setback

Table of ACDA: intersectional setback

**Approach speed as a function of setback distance (acceleration=0.15g)^[211]**
Setback [meters]	Setback [feet]	Approach speed [m/s]
0	0	0
0.5	1.6	11.3
1	3	16
1.5	4.9	19.6
2	7	23
3	10	28
4	13	32
5	16	36
6	20	39
8	26	45
10	33	51
12	39	55
14	46	60
16	52	64
18	59	68
20	66	72
22	72	75
24	79	78
26	85	82
28	92	85
30	98	88

Table of following distances

Table of following distances (2 second rule)

**Following distance (2 second rule)**
Speed [km/h]	Speed [mph]	Following distance [meters]	Following distance [feet]
0	0	0	0
5	3	3	9
10	6	6	18
15	9	8	27
20	12	11	36
25	16	14	46
30	19	17	55
35	22	19	64
40	25	22	73
45	28	25	82
50	31	28	91
55	34	31	100
60	37	33	109
65	40	36	118
70	43	39	128
75	47	42	137
80	50	44	146
85	53	47	155
90	56	50	164
95	59	53	173
100	62	56	182
105	65	58	191
110	68	61	200
115	71	64	210
120	75	67	219
125	78	69	228
130	81	72	237
135	84	75	246
140	87	78	255
145	90	81	264
150	93	83	273

Table of critical speeds

Table of critical speeds

**Average physical critical speeds on level surface (e=0, μ=0.7)**
Radius [meters]	Radius [feet]	Safe speed [km/h]	Safe speed [mph]
5	16.4	21.1	13.1
10	33	30	19
20	66	42	26
30	98	52	32
40	131	60	37
50	164	67	41
60	197	73	45
70	230	79	49
80	262	84	52
90	295	89	56
100	328	94	59
110	361	99	61
120	394	103	64
130	427	108	67
140	459	112	69
150	492	116	72
160	525	119	74
170	558	123	76
180	591	127	79
190	623	130	81
200	656	133	83

The speed values in this table are produced from the formula using an "average" coefficient of friction (μ) of 0.7 and zero superelevation. Speed values specific to a given circumstance can be obtained with the same formula using the appropriate reference constants specific to the circumstance.

**Average psychological critical speeds on level surface (e=0, μ=0.3)^[174]**
Radius [meters]	Radius [feet]	Safe speed [km/h]	Safe speed [mph]
5	16	14	9
10	33	20	12
15	49	24	15
20	66	28	17
25	82	31	19
30	98	34	21
35	115	37	23
40	131	39	24
45	148	41	26
50	164	44	27
55	180	46	28
60	197	48	30
65	213	50	31
70	230	52	32
75	246	53	33
80	262	55	34
85	279	57	35
90	295	59	36
95	312	60	37
100	328	62	38
105	344	63	39
110	361	65	40
115	377	66	41
120	394	68	42
125	410	69	43
130	427	70	44
140	459	73	45
145	476	74	46
150	492	76	47
155	509	77	48
160	525	78	49
170	558	81	50
175	574	82	51
180	591	83	51
185	607	84	52
190	623	85	53
200	656	87	54
205	673	88	55
210	689	89	56
220	722	92	57
230	755	94	58
240	787	96	59
245	804	97	60
250	820	98	61
260	853	100	62
280	919	103	64
300	984	107	66
320	1050	110	69
340	1115	114	71
360	1181	117	73
380	1247	120	75
400	1312	124	77
420	1378	127	79
440	1444	130	80
460	1509	132	82
480	1575	135	84
500	1640	138	86

Most motorists will not tolerate a lateral acceleration exceeding 0.3g (μ=0.3) above which many will panic.^[174]

Table of detection thresholds

Table of detection thresholds: SAVT

**Table of detection thresholds: SAVT**
Speed [KM/H]	Speed [MPH]	Detection Distance [m]	Detection Distance [ft]	Time to Collision [s]
	5		38
	10		54
	15		66
	20		77
	25		86
	30		94
	35		101
	40		108
	45		115
	50		121
	55		127
	60		133
	65		138
	70		143
	75		148
	80		153

Notes

↑ In addition to being old common law principle, ACDA case law jurisprudence buttressed the legislature's implicit intent in its Basic Speed Law, and further limited transference of liability for ACDA negligence to the state—under the California Tort Claims Act—for insufficient sight distance at the speed of which the driver chose. See CVC § 22350, CVC § 22358.5, Cal Gov. Code § 830.4, Cal Gov. Code § 830.8, and Cal Gov. Code § 831. See CACI Form 1120 for details.
↑ For this reason, full corner sight distance is almost never required for individual driveways in urban high-density residential areas, and street parking is commonly permitted within the right-of-way.
↑ While the Gestalt effect is generally valuable in processing visual information, ambiguity such as that specific to approaching distant vehicles can also lead to problematic multistable perception, erroneous filling-in, and spectacular failure such as the Ebbinghaus illusion, Delboeuf illusion, and Ponzo illusion. Such honest human error insidiously arises through unconscious inferences from insufficient, distracting, or illusory information—it is especially important to foresee such hazard at intersections.
↑ Under the worst-case scenario, a driver will make decisions alone based upon the "looming motion" of oncoming headlights or silhouette of an anonymous vehicle, which must reach a certain proximity in order to exceed the visual expansion acuity threshold, $\dot{\theta_{t}}$ . Given a vehicle of size $S$ and distance $x$ , the visual angle is: $\theta=2\arctan{\left (\tfrac{S}{2x} \right)}$ . Its derivative with respect to distance is $\tfrac{d\theta}{dx}=\tfrac{-4S}{S^2+4x^2}$ . An approaching vehicle of constant velocity $v$ will decrease the distance at rate $\tfrac{dx}{dt}=-v$ . The time rate of visual expansion is obtained from the rate at which the subtended angle grows with decreased distance, multiplied by the rate at which the distance lessens with time: $\tfrac{d\theta}{dt}=\tfrac{\operatorname{d}\!\theta}{\operatorname{d}\!x}\cdot\tfrac{\operatorname{d}\!x}{\operatorname{d}\!t}$ . It follows that $\frac{4S \cdot v}{S^2+4x^2} \gtrsim \dot{\theta_{t}}$ . Hence, an approaching vehicle's looming motion is not perceivable until $x \lesssim \sqrt{\frac{S \cdot v}{\dot{\theta_{t}}}-\frac{S^2}{4}}$ , where the $<templatestyles src="Sfrac/styles.css" />S2/4$ term is omitted with small-angle approximation. The units of measurement for size, distance, and velocity variables must be of the same system (i.e. multiply by $<templatestyles src="Sfrac/styles.css" />22/15$ to convert MPH to ft/s or $<templatestyles src="Sfrac/styles.css" />5/18$ to convert km/h to m/s or $<templatestyles src="Sfrac/styles.css" />π/180$ to convert deg to requisite rad). Read more about this topic
↑ The overbreadth doctrine is also implicated whereby to avoid the risk of legal consequences for using blind intersections for which there is no fair notice of other traffic bringing a prohibition of its use into effect, persons with no alternative route are dissuaded from the liberty of free movement, expression, and to peacefully assemble. Hence the law's effects are thereby far broader than intended or than the U.S. Constitution permits. Furthermore, as insufficient intersectional sight-distance is often often symptomatic of old, urban high-density neighborhoods, with multiple tenant households saturating narrow street parking,—predominately lower social-economic environments—entire classes of people may be unequally discouraged from even leaving their houses. The through-driver is not adversely affected in this regard, by being compelled to slow down as to be able to stop to avoid collision with entering car or pedestrian as required by law.
↑ In most jurisdictions, judicial notice shall be taken of the total stopping distance, and such notice is therefore logically and substantively taken of the maximum speed permitted to brake within the stopping distance as applied to the ACDA. The latter is merely the inverse function of the former. Furthermore, fundamental mathematical relationships are themselves subject to judicial notice. $V_{ACDA(s)}=\sqrt{\mu^2 g^2 t_{prt}^2+ 2 \mu g d_{ACDA_s} } - \mu g t_{prt}$ For example, using the $\mu=0.7$ and $t_{prt}=1.5$ values that produced Code of Virginia § 46.2-880 Tables of speed and stopping distances, one simply obtains the same velocities that produced the stopping distance in the statute: Metric (SI) – Speed in km/h from distance in meters: $V_{ACDA} \approx \sqrt{1372.3+ 177.8 d_{ACDA} } - 37.0$ US customary – Speed in MPH from distance in feet: $V_{ACDA} \approx \sqrt{529.8+ 20.9 d_{ACDA} } - 23.0$
↑ Safe Speed will be outputted in the same terms as the input units. Entering a distance in feet and an acceleration in terms of feet/s² will produce a safe speed in terms of feet/second. To convert to miles per hour, multiply by $<templatestyles src="Sfrac/styles.css" />22/15$ . Entering distance and acceleration in terms of meters will output a speed in meters per second, which may be converted to kilometers per hour by multiplying by a $<templatestyles src="Sfrac/styles.css" />18/5$ (or 3.6) factor.

References

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↑ Peri v. L. A. Junction Railway, 22 Cal.2d 111, 22 California Reports, 2nd Series 111 (Supreme Court of California 3 May 1943) (“it does not follow that a railroad company will be permitted to run its trains under all conditions at any rate of speed it may choose. It must regulate its speed with proper regard for the safety of human life and property, especially when running through towns and cities. The character of a crossing, it has been well reasoned, affects the duty of the railroad company toward...travelers upon the public highway, and its trains must pass over dangerous crossings at a less rate of speed proportionate to the danger.”).
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↑ ^5.0 ^5.1 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^6.0 ^6.1 ^6.2 ^6.3 ^6.4 The Batavier, 40 English Reports in Law and Equity 19–27, 25 (Great Britain. Courts.; Great Britain. Parliament. House of Lords.; Great Britain. Privy Council. Judicial Committee July 14, 1854) (“Page 25: At whatever rate she (the steamer) was going, if going at such a rate as made it dangerous to any craft which she ought to have seen, and might have seen, she had no right to go at that rate. ... at all events, she was bound to stop if it was necessary to do so, in order to prevent damage being done ... See more English Reports in Law and Equity”).
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↑ ^18.0 ^18.1 ^18.2 ^18.3 ^18.4 ^18.5 ^18.6 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^19.0 ^19.1 ^19.2 Lua error in package.lua at line 80: module 'strict' not found.
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↑ ^21.0 ^21.1 ^21.2 United States v. Carroll Towing Co., 159 Federal Reporter, Second Series 169, 173 (United States Court of Appeals for the Second Circuit January 9, 1947) (“Since there are occasions when every vessel will break from her moorings, and since, if she does, she becomes a menace to those about her; the owner’s duty, as in other similar situations, to provide against resulting injuries is a function of three variables: (1) The probability that she will break away; (2) the gravity of the resulting injury, if she does; (3) the burden of adequate precautions. Possibly it serves to bring this notion into relief to state it in algebraic terms: if the probability be called P; the injury, L; and the burden, B; liability depends upon whether B is less than L multiplied by P: i. e., whether B > PL. See ruling here”).
↑ ^22.0 ^22.1 ^22.2 ^22.3 Newton v. Stebbins, 51 U.S. 586, 51 United States Reports 586 (Supreme Court of the United States December 1850) (“it may be a matter of convenience that steam vessels should proceed with great rapidity, but the law will not justify them in proceeding with such rapidity if the property and lives of other persons are thereby endangered. ... It is a mistake to suppose that a rigorous enforcement of the necessity of adopting precautionary measures by the persons in charge of steamboats to avoid damage to sailing vessels on our rivers and internal waters will have the effect to produce carelessness and neglect on the part of the persons in charge of the latter. The vast speed and power of the former, and consequent serious damage to the latter in case of a collision, will always be found a sufficient admonition to care and vigilance on their part. A collision usually results in the destruction of the sailing vessel, and not infrequently in the loss of the lives of persons on board.”).
↑ ^23.0 ^23.1 ^23.2 ^23.3 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^24.0 ^24.1 ^24.2 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^25.0 ^25.1 ^25.2 ^25.3 ^25.4 ^25.5 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^26.0 ^26.1 ^26.2 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^27.0 ^27.1 Lua error in package.lua at line 80: module 'strict' not found.
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↑ ^29.0 ^29.1 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^30.0 ^30.1 ^30.2 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^31.0 ^31.1 ^31.2 Connally v. General Construction Co., 269 United States Reports 385, 391 (Supreme Court of the United States January 4, 1926) (“That the terms of a penal statute creating a new offense must be sufficiently explicit to inform those who are subject to it what conduct on their part will render them liable to its penalties is a well recognized requirement, consonant alike with ordinary notions of fair play and the settled rules of law, and a statute which either forbids or requires the doing of an act in terms so vague that men of common intelligence must necessarily guess at its meaning and differ as to its application violates the first essential of due process of law.”).
↑ ^32.0 ^32.1 ^32.2 State of Montana, v. Rudy Stanko, 1998 MT 321, HN 30 (Supreme Court of Montana 23 December 1998) (“...we conclude that that part of § 61-8-303(1), MCA, which makes it a criminal offense to operate a motor vehicle "at a rate of speed ․ greater than is reasonable and proper under the conditions existing at the point of operation" is void for vagueness on its face and in violation of the Due Process Clause of Article II, Section 17, of the Montana Constitution.”).
↑ ^33.0 ^33.1 ^33.2 ^33.3 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^34.0 ^34.1 ^34.2 ^34.3 ^34.4 ^34.5 ^34.6 Reaugh v. Cudahy Packing Co., 189 Cal. 335, 189 Official California Reports 335 (Supreme Court of California July 27, 1922) (“[The basic speed law] is but a reiteration of the rule, in statutory form, which has always been in force without regard to a statutory promulgation to the effect that drivers or operators of vehicles, and more particularly motor vehicles, must be specially watchful in anticipation of the presence of others at places where other vehicles are constantly passing, and where men, women, and children are liable to be crossing, such as corners at the intersections of streets or other similar places or situations where people are likely to fail to observe an approaching automobile.”). See Official Reports Opinions Online
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↑ ^36.0 ^36.1 ^36.2 The Europa, 2 English Reports in Law and Equity 557–564, 564 (Great Britain. Courts.; Great Britain. Parliament. House of Lords.; Great Britain. Privy Council. Judicial Committee June 11, 1850) (“Page: 564 Whether any given rate is dangerous or not must depend upon the circumstances of each individual case, as the state of the weather, locality, and other similar facts. See more English Reports in Law and Equity”).
↑ ^37.0 ^37.1 The Colorado, 91 U.S. 692, 91 United States Reports 692 (Supreme Court of the United States October 1875) (“when steamships are approaching another ship so as to involve risk of collision, they shall slacken their speed or, if necessary, stop and reverse, and the express provision is that every steamship shall, when in a fog, go at a moderate speed.”).
↑ ^38.0 ^38.1 ^38.2 Lauson v. Town of Fond du Lac, 141 Wis. 57, 123 N. W. 629, 25 L. R. A. (N. S.) 40., 141 Wis. 57 (Wisconsin Supreme Court 1909) (“the driver of an automobile, circumstanced as was the driver of the car in which the plaintiff was riding, and operating it under such conditions as he operated his machine on the night of the accident, is not exercising ordinary care if he is driving the car at such a rate of speed that he cannot bring it to a standstill within the distance that he can plainly see objects or obstructions ahead of him”).
↑ ^39.0 ^39.1 Garner v. Maxwell, 360 S.W.2d 64, 360 S.W.2d 64 (Court of Appeals of Tennessee December 20, 1961) (“What is known as the "The assured clear distance rule" arises out of the decision of the Supreme Court in 1914 in the case of West Construction Co. v. White, 130 Tenn. 520, 172 S.W. 301, in which case it was held that the failure of a plaintiff to stop his car within the distance lighted by the headlights of the car, and thus avoid a collision, amounted, as a matter of law, to contributory negligence which barred plaintiff's suit.”).
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↑ ^41.0 ^41.1 ^41.2 The Nacoochee v. Moseley, 137 U.S. 330, 137 United States Reports 330 (Supreme Court of the United States December 8, 1890) (“every steam-vessel, when approaching another vessel, so as to involve risk of collision, shall slacken her speed, or, if necessary, stop and reverse; and every steam-vessel shall, when in a fog, go at a moderate speed. ... She was bound, therefore, to observe unusual caution, and to maintain only such a rate of speed as would enable her to come to a standstill, by reversing her engines at full speed, before she should collide with a vessel which she should see through the fog. ... whatever rate a steamer was going, if she was going at such a rate as made it dangerous to any craft which she ought to have seen, and might have seen, she had no right to go at that rate.”).
↑ ^42.0 ^42.1 Curtis v. Hubbel, 42 Ohio App. 520, 182 N. E. 589, 42 Ohio App. 520 (Court of Appeals of Ohio May 31, 1932) (“Statute requiring drivers to maintain speed permitting them to stop within assured clear distance ahead held applicable to both day and night driving ... Motorist unable, because of insufficient headlights, to see pedestrian until within few feet, must be able to stop within such distance, and failure to drive at speed permitting such stopping is negligence per se.”).
↑ ^43.0 ^43.1 Lindquist v. Thierman, 216 Iowa 170, 216 Iowa 170 (Supreme Court of Iowa May 15, 1933) (“it is evident that the words "within the assured clear distance ahead", as used in the statute, signify that the operator of the automobile, when driving at night as well as in the day, shall at all times be able to stop his car within the distance that discernible objects may be seen ahead of it.”).
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↑ ^48.0 ^48.1 Lua error in package.lua at line 80: module 'strict' not found.
↑ ^49.0 ^49.1 ^49.2 Cook v. Miller, 175 Cal. 497, 175 Official California Reports 497 (Supreme Court of California June 19, 1917) (“The cause of plaintiff having no time to avoid the collision was not the speed of the automobile, for it had come practically to a stop at the instant of the collision. It was his own speed that shortened his time. ... A horse can travel at the rate of fifteen miles an hour, and even faster, for a short time. But in the days of exclusively horse-drawn vehicles one who crossed a street at such a place going at fifteen miles an hour would have been considered reckless. There have been city ordinances forbidding a team from crossing a street intersection faster than a walk. ( Stein v. United Railroads, 159 Cal. 371, [113 Pac. 663].) Since our eyes have become somewhat accustomed to greater speed, the recklessness of fifteen miles an hour may not seem so obvious, but the danger is the same. ... A speed which carries a person twenty-two feet in one second of time at a "blind corner," with standing auto trucks projecting twelve feet into the street, obstructing the vision of the intersecting street until the last truck is reached, and with a wagon ahead of him, is not that speed which a person exercising ordinary prudence would choose at such a place, out of due regard for his own safety or that of others. Such speed may not be unusual at the present time, even under similar circumstances. But the person who receives an injury from a collision, while going at that rate under the conditions here existing, should not expect the other person to pay him the damages caused thereby.”).
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↑ ^51.0 ^51.1 ^51.2 ^51.3 ^51.4 ^51.5 Lua error in package.lua at line 80: module 'strict' not found.
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↑ Leyden Street remains unchanged since 1620
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↑ Pennsylvania R. Co. v. Huss, 96 Ind. App. 71, 180 N. E. 919, 96 Indiana Appellate Reports 71 (Court of Appeals of Indiana May 6, 1932) (“it is a violation of the law, and, therefore negligence, to drive an automobile at such speed, in the daytime or night time, that it cannot be stopped within the distance that objects can be seen ahead if proper lights are used”).
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↑ Demerest v. Travelers Insurance Company, 234 La. 1048, 234 La. 1040 (Supreme Court of Louisiana April 21, 1958) (“the jurisprudence of this state is that: "when visibility is materially impaired because of smoke, mist, dust, etc., a motorist should reduce his rate of speed to such extent and keep his car under such control as to reduce to a minimum the possibility of accident from collision; and as an extreme measure of safety, it is his duty, when visibility ahead is not possible or greatly obscured, to stop his car and remain at a standstill until conditions warrant going forward.”).
↑ Carriere v. Aetna Cas. Co., 146 So.2d 451, 146 So.2d 451 (Court of Appeal of Louisiana. Fourth Circuit October 1, 1962) (“The law is settled to the effect that a motorist is held to have seen an object which, by the use of ordinary care and prudence, he should have seen in time to avoid running into it, and that the driver of an automobile is guilty of negligence in driving at a rate of speed greater than that in which he could stop within the range of his vision.”).
↑ Spencer v. Taylor, 219 Mich. 110, 188 N.W. 461 (1922), 219 Mich. 110 (1922).
↑ Gleason v. Lowe, 232 Mich. 300, 232 Mich. 300 (Supreme Court of Michigan October 1, 1925) (“...every man must operate his automobile so that he can stop it within the range of his vision, whether it be daylight or darkness. It makes no difference what may obscure his vision, whether it be a brick wall or the darkness of nightfall. ... He must ... be able to see where he is going, and if his range of vision is 50 feet, if he can see 50 feet ahead of him, he must regulate his speed so that he can stop in a distance of 50 feet; if he can see 20 feet ahead of him, he must regulate his speed so that he can stop within 20 feet, and so on.”).
↑ Ruth v. Vroom, 245 Mich. 88, 222 N. W. 155, 62 A. L. R. 1528, 245 Mich. 88 (Supreme Court of Michigan December 4, 1928) (“It is settled in this State that it is negligence as a matter of law to drive an automobile at night at such speed that it cannot be stopped within the distance that objects can be seen ahead of it; and, if a driver's vision is obscured by the lights of an approaching car, it is his duty to slacken speed and have his car under such control that he can stop immediately if necessary. ... The rule adopted by this court does not raise merely a rebuttable presumption of negligence. It is a rule of safety. ... It is not enough that a driver be able to begin to stop within the range of his vision, or that he use diligence to stop after discerning an object. The rule makes no allowance for delay in action.”).
↑ ^62.0 ^62.1 O’Farrell v. Inzeo, 74 A.D.2d 806 (1st Dept. 1980), 74 A.D.2d 806 (New York Supreme Court, Appellate Division 1980) (“It is negligence as a matter of law to drive a motor vehicle at such a rate of speed that it cannot be stopped in time to avoid an obstruction discernible within the driver's length of vision ahead of him. This rule is known generally as the `assured clear distance ahead' rule * * * In application, the rule constantly changes as the motorist proceeds, and is measured at any moment by the distance between the motorist's vehicle and the limit of his vision ahead, or by the distance between the vehicle and any intermediate discernible static or forward-moving object in the street or highway ahead constituting an obstruction in his path. Such rule requires a motorist in the exercise of due care at all times to see, or to know from having seen, that the road is clear or apparently clear and safe for travel, a sufficient distance ahead to make it apparently safe to advance at the speed employed.”).
↑ Morris v. Jenrette Transport Co., 235 N.C. 568 (Supreme Court of North Carolina May 21, 1952) (“It is not enough that the driver of plaintiff's automobile be able to begin to stop within the range of his lights, or that he exercise due diligence after seeing defendants' truck on the highway. He should have so driven that he could and would discover it, perform the manual acts necessary to stop, and bring the automobile to a complete stop within the range of his lights. When blinded by the lights of the oncoming car so that he could not see the required distance ahead, it was the duty of the driver within such distance from the point of blinding to bring his automobile to such control that he could stop immediately, and if he could not then see, he should have stopped. In failing to so drive he was guilty of negligence which patently caused or contributed to the collision with defendants' truck, resulting in injury to plaintiff."...it was his duty to anticipate presence of others, [...] and hazards of the road, such as disabled vehicle, and, in the exercise of due care, to keep his automobile under such control as to be able to stop within the range of his lights”).
↑ ^64.0 ^64.1 Blair v. Goff-Kirby Co., 49 Ohio St.2d 5, 7 (Supreme Court of Ohio December 29, 1976).
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↑ Steele v. Fuller, 104 Vt. 303, 104 Vt. 303 (November 1932) (“Operator of motor vehicle has duty at all times to maintain lookout for persons and property on highway, and to use reasonable care to avoid inflicting injuries on such persons or property. ... Operator of motor vehicle is chargeable with knowledge of objects in highway which are in plain view. ... One who drives automobile along public highway in dark must drive at such speed that automobile can be stopped within range of its headlights. ... Rule that automobile operator may assume that other motorists would not obstruct highway unlawfully, and would show statutory lights if they stopped, applies only in favor of one whose own conduct measures up to that of prudent and careful man in like circumstances.”).
↑ Mann v. Reliable Transit Co., 217 Wis. 465, 259 N. W. 415, 217 Wis. 465 (Wisconsin Supreme Court 1935).
↑ Satterlee v. Orange Glenn School Dist., 29 Cal.2d 581, 29 Official California Reports, 2nd Series 581 (California Supreme Court Jan 31, 1947) (“"proper conduct of a reasonable person under particular situations may become settled by judicial decision or be prescribed by statute or ordinance."”). See California Official Reports: Online Opinions
↑ ^69.0 ^69.1 Wilding v. Norton, 156 Cal.App.2d 374, 156 Official California Appellate Reports, 2nd Series 374 (California Appellate Court December 27, 1957) (“The so-called basic speed law is primarily a regulation of the conduct of the operators of vehicles. They are bound to know the conditions which dictate the speeds at which they can drive with a reasonable degree of safety. They know, or should know, their cars and their own ability to handle them, and especially their ability to come to a stop at different speeds and under different conditions of the surface of the highway. See Official Reports Online”).
↑ Lutz v. Schendel, 175 Cal. App. 2d 140, 175 Official California Appellate Reports, 2nd Series 140 (California Appellate Court Nov 6, 1959) (“"It is the duty of the driver of a motor vehicle using the public highways to be vigilant at all times and to keep the vehicle under such control that to avoid a collision he can stop as quickly as might be required of him by eventualities that would be anticipated by an ordinarily prudent driver in like position."”). See California Official Reports: Online Opinions
↑ ^71.0 ^71.1 Falasco v. Hulen, 6 Cal. App. 2d 224, 6 Official California Appellate Reports, 2nd Series 224 (California Appellate Court April 17, 1935) (“"Driving between 60 and 65 miles an hour over the brow of a hill, where one's view is obstructed and one cannot see what is on the opposite side of the hill for a sufficient distance to control the speed of his car, is an act showing a reckless disregard of the safety of others; and in said action, under the evidence, the jury was entitled to conclude either that defendant was driving at such a reckless rate of speed that he could not control the car, or that he was driving at such a high rate of speed that he did not perceive that the highway ahead of him afforded an unobstructed passage." (CA Reports Official Headnote #[9])”). See California Official Reports: Online Opinions
↑ ^72.0 ^72.1 Cannon v. Kemper, 23 Cal. App. 2d 239, 23 Official California Appellate Reports, 2nd Series 239 (California Appellate Court October 21, 1937). Driver traveling at 35 MPH when rain limited visibility to 25 feet held negligent when 65 feet were required to stop car on wet road. See California Official Reports: Online Opinions
↑ ^73.0 ^73.1 Bove v. Beckman, 236 Cal. App. 2d 555, 236 Official California Appellate Reports, 2nd Series 555 (California Appellate Court Aug 16, 1965) (“"A person driving an automobile at 65 miles an hour on a highway on a dark night with his lights on low beam affording a forward vision of only about 100 feet was driving at a negligent and excessive speed which was inconsistent with any right of way that he might otherwise have had." (CA Reports Official Headnote #[8])”). See California Official Reports: Online Opinions
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↑ ^76.0 ^76.1 Reinders v. Olsen, 60 Cal. App. 764, 60 California Appellate Reports 764 (California Appellate Court February 13, 1923) (“the fact of knowledge on the part of plaintiff relating to the "custom" or, rather, practice, of automobile drivers ... no such practice could be binding on plaintiff so as to excuse defendant from violating the statute in that regard, provided that such act was the proximate cause of the accident. See Official Reports Opinions”).
↑ ^77.0 ^77.1 Peri v. L. A. Junction Railway, 22 Cal.2d 111, 22 Official California Reports, Second Series 111 (Supreme Court of California 3 May 1943) (“Today it is a matter of common knowledge that automobiles are driven at night on our great, wide, straight highways at speeds which do not allow adequate time or space in which to stop for unusual objects such as freight trains completely obstructing the highway unless some warning of the possible or probable presence thereof is given, especially where, as in the case of such trains, the bodies of the cars are apt to be above the direct beams of the automobile lights which the law requires to be projected below 42 inches at 75 feet from the vehicle. Recognizing this, our counties and state highway department place conspicuous warnings of all variations from the normal road. Drivers of ordinary prudence have grown to rely on the presence of such warnings. See Official Reports Opinions Online”).
↑ ^78.0 ^78.1 Herbert v. Southern Pac. Co., 121 Cal. 227, 121 Official California Reports 227 (Supreme Court of California June 20, 1898) (“the cases arising from injuries suffered at railroad crossings have been so numerous, and upon certain points there has been such absolute accord, that what will constitute ordinary care in such a case had been precisely defined, and, if any element is wanting, the courts will hold as matter of law that the plaintiff has been guilty of negligence. And, when injury results which might have been avoided by the use of proper care, ... the amount of care, as well as the nature of it, has been settled.”).
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↑ Torrez v. Willett, 366 Mich. 465, 366 Mich. 465 (Supreme Court of Michigan May 18, 1962) (“Hereafter any motor boat, launch, or other water craft operated on the inland waters of this State or the waters connected with the Great Lakes. No such motor boat shall be operated on any of said waters in a reckless manner or at an excessive rate of speed so as to endanger the life or property of any person in or on said waters, having due regard to the presence of other boats, bathers or objects in or on such waters and of any other conditions then existing, and no person shall operate such motor boat on said waters at a rate of speed greater than will permit him to bring it to a stop within the assured clear distance ahead."”).
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↑ ^104.0 ^104.1 ^104.2 ^104.3 Baltimore & Ohio R. Co. v. Goodman, 275 U.S. 66, 275 United States Reports 66 (Supreme Court of the United States October 31, 1927) (“In an action for negligence, the question of due care is not left to the jury when resolved by a clear standard of conduct which should be laid down by the courts ... If, at the last moment, [he] found himself in an emergency, it was his own fault that he did not reduce his speed earlier or come to a stop.”).
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↑ ^121.0 ^121.1 ^121.2 Lua error in package.lua at line 80: module 'strict' not found.
↑ Van Praag v. Gale, 107 Cal 438 (Supreme Court of California June 6, 1895) (“As a general proposition cases of negligence (to which those of contributory negligence form no exception) present a mixed question of law and fact, in which it devolves upon the court to say, as matter of law, what is or amounts to negligence, and upon the jury to say as matter of fact, whether or not in the particular case the facts in proof warrant the imputation of negligence. The court furnishes the standard; the jury adjusts the facts, and pronounces them as up to or falling short of the requirements of the standard.”).
↑ Doyle v. Eschen, 5 Cal.App 55 (California Court of Appeal February 21, 1907) (“usually the consideration of negligence, including "contributory negligence," involves "a mixed question of law and fact, in which it devolves upon the court, to say, as a matter of law, what is or amounts to negligence, and upon the jury to say as matter of fact whether or not in the particular case the facts in proof warrant the imputation of negligence. The court furnishes the standard; the jury adjusts the facts and pronounces them as up to or falling short of the requirements of the standard. When, however, the facts are clearly settled, and the course which common prudence dictates can be readily discerned, the court should decide the case as matter of law.”).
↑ Malinson v. Black, 83 Cal.App.2d 375, 377-378 (California Court of Appeal January 27, 1948) (“Respondent testified that he came to a complete stop at the boulevard stop sign, surveyed the highway, saw that no cars were approaching from the right, and that the nearest car, presumably appellant's, approaching from the left, was at a distance of approximately 80 yards north of the intersection. Having concluded that he had plenty of time to safely cross the intersection, he proceeded in, looking straight ahead. ... we cannot declare such conduct to be negligence as a matter of law.”).
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↑ ^128.0 ^128.1 United States v. National City Lines, Inc., et al, 186 F.2d 562 (United States Court of Appeals for the Seventh Circuit January 3, 1951) (“On April 9, 1947, nine corporations and seven individuals, constituting officers and directors of certain of the corporate defendants, were indicted on two counts, the second of which charged them with conspiring to monopolize certain portions of interstate commerce...the conspiracy to monopolize had consisted of a continuing agreement and concert of action upon the part of defendants under which the supplier defendants, Firestone, Standard, Phillips, General Motors and Mack, would furnish capital to defendants National, American and Pacific, and the latter companies would purchase and cause their operating companies to purchase from the supplier companies substantially all their requirements of tires, tubes and petroleum products; the capital made available by the supplier defendants would be utilized by National and Pacific, to purchase control of or financial interest in local public transportation systems, located in various states, when the securing of such control and interest would further the sale of and create an additional market for the products of the supplier defendants to the exclusion of products competitive therewith...as National and Pacific acquired local transportation systems in the other sections of the country, those markets would be allocated to and preempted by a company selling petroleum products in such sections...”).
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↑ United States v. National City Lines, 334 US 573 (Supreme Court of the United States June 7, 1948).
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↑ Hatzakorzian v. Rucker-Fuller Desk Co., 197 Cal. 82, 197 Official California Reports 82 (Supreme Court of California September 21, 1925) (“"Under the circumstances of the present case -- the narrowness of the unpaved portion of the highway, the darkness of the night and the blinding of Kennell by the glare of the lights reflected from the headlights of the approaching machine -- the highway over which Kennell was traveling was beset by danger of an extraordinary character from the time his vision became so obscured as to make it impossible for him to see plainly the road before him to the time that he struck the deceased. Thus the ordinary care with which Kennell was charged in driving his car over the highway required such an amount of such care as was commensurate with the exactions of the extraordinary dangerous circumstances under which he was then operating his car. The respective rights and duties of drivers of automobiles and other vehicles and of pedestrians have repeatedly been by the courts of this state clearly pointed out.."”).
↑ ^140.0 ^140.1 ^140.2 ^140.3 Riggs v. Gasser Motors, 22 Cal. App. 2d 636, 22 Official California Appellate Reports, 2nd Series 636 (California Court of Appeal September 25, 1937) (“"It is common knowledge that intersecting streets in cities present a continuing hazard, the degree of hazard depending upon the extent of the use of the intersecting streets and the surrounding circumstances or conditions of each intersection. Under such circumstances the basic law...is always governing."”). See Official Reports Opinions Online
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↑ ^142.0 ^142.1 Allin v. Snavely, 100 Cal. App. 2d 411, 100 Official California Appellate Reports, 2nd Series 411 (California Court of Appeal November 14, 1950) (“"A driver by insisting on his lawful right of way may violate the basic speed law as provided by Veh. Code, § 22350, and thus become guilty of negligence."(CA Reports Headnote #[2])”).
↑ ^143.0 ^143.1 ^143.2 Leeper v. Nelson, 139 Cal. App. 2d 65, 139 Official California Appellate Reports, 2nd Series 65 (California Court of Appeal Feb 6, 1956) (“"The operator of an automobile is bound to anticipate that he may meet persons or vehicles at any point of the street, and he must in order to avoid a charge of negligence, keep a proper lookout for them and keep his machine under such control as will enable him to avoid a collision with another automobile driven with care and caution as a reasonably prudent person would do under similar conditions."”). See Huetter v. Andrews, 91 Cal. App. 2d 142, Berlin v. Violett, 129 Cal.App. 337, Reaugh v. Cudahy Packing Co., 189 Cal. 335, and Official Reports Opinions Online
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↑ ^149.0 ^149.1 ^149.2 ^149.3 Grasso v. Cunial, 106 Cal. App. 2d 294, 106 California Official Reports, 2nd Series 294 (California Court of Appeal August 27, 1951) (“Nor is a plaintiff required to yield the right of way to one a considerable distance away whose duty it is to slow down in crossing an intersection. See Official Reports Opinions Online”).
↑ ^150.0 ^150.1 ^150.2 Whitelaw v. McGilliard,179 Cal. 349, 179 Official California Reports 349 (Supreme Court of California December 4, 1918) (“The rule regarding right of way does not impose upon the person crossing the street the duty of assuming that the other will continue across an intersecting street without slowing down, as required by law. See Official Reports Opinions Online”).
↑ ^151.0 ^151.1 ^151.2 ^151.3 Page v. Mazzei, 213 Cal. 644, 213 Official California Reports 644 (Supreme Court of California 21 September 1931) (“Where a car has actually entered an intersection before the other approaches it, the driver of the first car has the right to assume that he will be given the right of way and be permitted to pass through the intersection without danger of collision. He has a right to assume that the driver of the other car will obey the law, slow down, and yield the right of way, if slowing down be necessary to prevent a collision. ( Keyes v. Hawley, 100 Cal. App. 53, 60 [279 Pac. 674].) Nor is a plaintiff required to yield the right of way to one a considerable distance away whose duty it is to slow down in crossing an intersection. See Official Reports Opinions Online”).
↑ Fitts v. Marquis, 127 Me. 75, 127 Maine Reporter 75 (Supreme Judicial Court of Maine March 15, 1928) (“If a situation indicate collision, the driver, who can do so by the exercise of ordinary care, should avoid doing injury, though this involve that he waive his right of way. The supreme rule of the road is the rule of mutual forbearance.”).
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↑ ^154.0 ^154.1 ^154.2 Malinson v. Black, 83 Cal. App. 2d 377, 83 Official California Appellate Reports, Second Series 377 (California Appellate Court January 27, 1948) (“It is apparent that plaintiff misjudged the speed of the truck and was mistaken as to his ability to cross Anaheim Street in front of it with safety. However, every mistake of judgment is not negligence, for mistakes are made even in the exercise of ordinary care. See Official Reports Online.”).
↑ ^155.0 ^155.1 ^155.2 Nevis v. Pacific Gas & Electric Co., 43 Cal.2d 626, 43 Official California Reports, Second Series 626 (Supreme Court of California November 9, 1954) (“Nonnegligent ignorance of the facts which bring a regulation into operation will support a finding that violation thereof is civilly excusable. See Official Reports Online”).
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↑ ^169.0 ^169.1 Fox v. City and County of San Francisco, 47 Cal.App.3d 164, 47 Official California Appellate Reports, 3rd Series 164 (California Appellate Court April 14, 1975) (“drivers with mental disabilities are required to exercise the ordinary care required of an adult without such disability. See Official Reports Online.”).
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↑ State of Montana v. Rudy Stanko (Supreme Court of Montana 23 December 1998) (“the road was narrow, there were hills and curves which presented some degree of obstruction to the view ahead, and there was an occasional frost heave on the surface of the road. A reasonable speed under these circumstances would require a calculation of sight distances and stopping distances for the particular vehicle. ...The arresting officer described in detail the roadway where Stanko was operating his vehicle at 85 miles per hour. The roadway was very narrow with no shoulders. There were frost heaves on the road which caused the officer's vehicle to bounce. The highway had steep hills, sharp curves, and multiple no-passing zones. There were numerous ranch and field access roads in the area which ranchers use for bringing hay to their cattle. The officer testified that at 85 miles per hour, there was no way for Stanko to stop in the event there had been an obstruction on the road beyond the crest of a hill. In the officer's judgment, driving a vehicle at the speed of 85 miles per hour on the stretch of road in question posed a danger to the rest of the driving public.”). Text
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↑ Cordova v. Ford, 46 Cal. App. 2d 180, 46 California Appellate Reports, Second Series 180 (California Appellate Court 7 November 1966) (“"All courts are agreed that the mere fact of a collision of two automobiles gives rise to no inference of negligence against either driver in an action brought by the other. ...When a vehicle operated by A collides with a vehicle operated by B, there are four possibilities. A alone was negligent; B alone was negligent; both were negligent; or neither. Of these four only the first will result in liability of A to B. The bare fact of a collision affords no basis on which to conclude that it is the preponderant probability. The odds are against it."”). See Official Reports Opinions Online
↑ Chowdhury v. City of Los Angeles, 38 Cal.App.4th 1187, 38 Official California Appellate Reports, 4th Series 1187 (California Appellate Court September 5, 1995) (“"A public entity does not create a dangerous condition on its property ‘merely because of the failure to provide regulatory traffic control signals, stop signs, yield right-of-way signs, or speed restriction signs . . . .’ (§ 830.4.) If, on the other hand, the government installs traffic signals and invites the public to justifiably rely on them, liability will attach if the signals malfunction, confusing or misleading motorists, and causing an accident to occur. See Official Reports Opinions Online”).
↑ Self v. State Farm Mutual Automobile Insurance Co., 183 So. 2d 68, 183 So.2d 68 (Court of Appeal of Louisiana, Third Circuit February 15, 1966) (“The law imposes upon a following motorist a duty to exercise great care, sometimes referred to as extraordinary care. ... As a rule, when a following vehicle collides with the rear of the lead car, the following driver is considered to be at fault.”).
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↑ Healthcare at Home Limited v. The Common Services Agency, [2014] UKSC 49 (Supreme Court of the United Kingdom 30 July 2014) (“It follows from the nature of the reasonable man, as a means of describing a standard applied by the court, that it would be misconceived for a party to seek to lead evidence from actual passengers [i.e. "the right-thinking member of society," "the officious bystander," "the reasonable parent," "the reasonable landlord," "the fair-minded and informed observer,"...] on the Clapham omnibus as to how they would have acted in a given situation or what they would have foreseen, in order to establish how the reasonable man would have acted or what he would have foreseen. Even if the party offered to prove that his witnesses were reasonable men, the evidence would be beside the point. The behaviour of the reasonable man is not established by the evidence of witnesses, but by the application of a legal standard by the court. The court may require to be informed by evidence of circumstances which bear on its application of the standard of the reasonable man in any particular case; but it is then for the court to determine the outcome, in those circumstances, of applying that impersonal standard.”). Text
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v t e Traffic law and safety
Rules of the road	All-way stop Assured Clear Distance Ahead Australian Road Rules Boulevard rule Green Cross Code Move over law New Zealand Road Code Overtaking Right- and left-hand traffic Right-of-way Right turn on red School bus traffic stop laws Traffic code Vienna Convention on Road Traffic
Road user guides	Driver's manual The Highway Code The Highway Code (Malta) Road Users' Code Rules of the Road (Ireland)
Enforcement	Breathalyzer Camera Enforcement Red light Highway patrol/State police Parking enforcement Road traffic control Traffic court Traffic guard Traffic stop Traffic ticket Warning
Speed limit	Advisory speed limit Assured Clear Distance Ahead National Maximum Speed Law School zone Speed limit enforcement Speed limits by country Category: Speed limits by country
Moving violations	Driving under the influence Canada United States Distracted driving Mobile phones and driving Texting while driving Reckless driving Street racing Tailgating Vehicular homicide Wrong-way driving
Driver licensing	Commercial driver's license European driving licence Graduated driver licensing Inter-American Driving Permit International Driving Permit Learner's permit Point system Driving licences by country List of countries by minimum driving age
Traffic violations reciprocity	Commercial Driver's License Information System Driver License Agreement Driver License Compact Non-Resident Violator Compact
Parking	Alternate-side parking Decriminalised parking enforcement Disabled parking permit Double parking Parking chair Parking violation Wheel clamp
Car safety	Seat belt laws Click It or Ticket Clunk Click Every Trip
Road safety	Tachograph Digital tachograph Drivers' working hours (Europe) Epilepsy and driving Hours of service (US) 'How's my driving?' sign Old age and driving Sleep deprived driving Slow moving vehicle

HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
7	23	4	2
8	26	15	9
9	30	26	16
10	33	37	23
11	36	48	30
12	39	59	37
13	43	70	44
14	46	82	51
15	49	93	58
16	52	104	65
17	56	115	71
18	59	126	78
19	62	137	85
20	66	148	92
21	69	159	99
22	72	171	106
23	75	182	113
24	79	193	120
25	82	204	127

HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
20	66	0	0
21	69	3	2
22	72	7	4
23	75	11	7
24	79	14	9
25	82	18	11
26	85	22	14
27	89	26	16
28	92	29	18
29	95	33	20
30	98	37	23
31	102	40	25
32	105	44	27
33	108	48	30
34	112	51	32
35	115	55	34
36	118	59	37
37	121	62	39
38	125	66	41
39	128	70	43
40	131	74	46
41	135	77	48
42	138	81	50
43	141	85	53
44	144	88	55
45	148	92	57
46	151	96	59
47	154	99	62
48	157	103	64
49	161	107	66
50	164	110	69

Speed [km/h]	Speed [mph]	Following distance [meters]	Following distance [feet]
0	0	0	0
5	3	3	9
10	6	6	18
15	9	8	27
20	12	11	36
25	16	14	46
30	19	17	55
35	22	19	64
40	25	22	73
45	28	25	82
50	31	28	91
55	34	31	100
60	37	33	109
65	40	36	118
70	43	39	128
75	47	42	137
80	50	44	146
85	53	47	155
90	56	50	164
95	59	53	173
100	62	56	182
105	65	58	191
110	68	61	200
115	71	64	210
120	75	67	219
125	78	69	228
130	81	72	237
135	84	75	246
140	87	78	255
145	90	81	264
150	93	83	273

Speed [KM/H]	Speed [MPH]	Detection Distance [m]	Detection Distance [ft]	Time to Collision [s]
	5		38
	10		54
	15		66
	20		77
	25		86
	30		94
	35		101
	40		108
	45		115
	50		121
	55		127
	60		133
	65		138
	70		143
	75		148
	80		153

HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
7	23	4	2
8	26	15	9
9	30	26	16
10	33	37	23
11	36	48	30
12	39	59	37
13	43	70	44
14	46	82	51
15	49	93	58
16	52	104	65
17	56	115	71
18	59	126	78
19	62	137	85
20	66	148	92
21	69	159	99
22	72	171	106
23	75	182	113
24	79	193	120
25	82	204	127

HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
20	66	0	0
21	69	3	2
22	72	7	4
23	75	11	7
24	79	14	9
25	82	18	11
26	85	22	14
27	89	26	16
28	92	29	18
29	95	33	20
30	98	37	23
31	102	40	25
32	105	44	27
33	108	48	30
34	112	51	32
35	115	55	34
36	118	59	37
37	121	62	39
38	125	66	41
39	128	70	43
40	131	74	46
41	135	77	48
42	138	81	50
43	141	85	53
44	144	88	55
45	148	92	57
46	151	96	59
47	154	99	62
48	157	103	64
49	161	107	66
50	164	110	69

Speed [km/h]	Speed [mph]	Following distance [meters]	Following distance [feet]
0	0	0	0
5	3	3	9
10	6	6	18
15	9	8	27
20	12	11	36
25	16	14	46
30	19	17	55
35	22	19	64
40	25	22	73
45	28	25	82
50	31	28	91
55	34	31	100
60	37	33	109
65	40	36	118
70	43	39	128
75	47	42	137
80	50	44	146
85	53	47	155
90	56	50	164
95	59	53	173
100	62	56	182
105	65	58	191
110	68	61	200
115	71	64	210
120	75	67	219
125	78	69	228
130	81	72	237
135	84	75	246
140	87	78	255
145	90	81	264
150	93	83	273

Speed [KM/H]	Speed [MPH]	Detection Distance [m]	Detection Distance [ft]	Time to Collision [s]
	5		38
	10		54
	15		66
	20		77
	25		86
	30		94
	35		101
	40		108
	45		115
	50		121
	55		127
	60		133
	65		138
	70		143
	75		148
	80		153

Assured Clear Distance Ahead

Contents

ACDA as common law rule or statute

Origins

Present

Universal Standard of Care

Determining the ACDA

Static ACDA

Forward "line-of-sight" distance

Intersections

ACDA as a function of horizontal sight distance

Dynamic "following" distance

Measurement

Discretion

Seconds of distance to stop rule

ACDA Rule specific case generalized to the Basic Speed Law

ACDA: forward line-of-sight

ACDA: horizontal line-of-sight

ACDA: intersectional setback

ACDA: following distance

Critical speed

Surface control

Safe speed

Relationship of posted speed limits to the explicitness of driver care standard

Famous tragedies

"Assurance" beyond proximate edge of clear visibility as transference of liability

Derivations

Case 1: Safe speed as a function of forward line-of-sight

Case 2: Safe speed as a function of horizontal line-of-sight

Case 3: Safe speed as a function of intersectional setback

Case 4: Safe speed as a function of following distance

Case 5: Safe speed as a function of critical speed

Seconds of distance to stop rule

Tables of reference constants and safe speeds

Reference Constants

Table of perception-reaction times

Table of tire-roadway friction coefficients

Table of acceleration values

Table of intercept values

Table of tire speed ratings

Safe Speeds

Table of ACDA: forward line-of-sight

Table of ACDA: horizontal line-of-sight

Table of ACDA: intersectional setback

Table of following distances

Table of critical speeds

Table of detection thresholds

See also

Notes

References

Further reading: tertiary sources

ACDA related law reviews

Other printed resources

Web resources

Navigation menu

Search

HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
7	23	4	2
8	26	15	9
9	30	26	16
10	33	37	23
11	36	48	30
12	39	59	37
13	43	70	44
14	46	82	51
15	49	93	58
16	52	104	65
17	56	115	71
18	59	126	78
19	62	137	85
20	66	148	92
21	69	159	99
22	72	171	106
23	75	182	113
24	79	193	120
25	82	204	127

HSD [meters]	HSD [feet]	Safe speed [km/h]	Safe speed [mph]
20	66	0	0
21	69	3	2
22	72	7	4
23	75	11	7
24	79	14	9
25	82	18	11
26	85	22	14
27	89	26	16
28	92	29	18
29	95	33	20
30	98	37	23
31	102	40	25
32	105	44	27
33	108	48	30
34	112	51	32
35	115	55	34
36	118	59	37
37	121	62	39
38	125	66	41
39	128	70	43
40	131	74	46
41	135	77	48
42	138	81	50
43	141	85	53
44	144	88	55
45	148	92	57
46	151	96	59
47	154	99	62
48	157	103	64
49	161	107	66
50	164	110	69

Speed [km/h]	Speed [mph]	Following distance [meters]	Following distance [feet]
0	0	0	0
5	3	3	9
10	6	6	18
15	9	8	27
20	12	11	36
25	16	14	46
30	19	17	55
35	22	19	64
40	25	22	73
45	28	25	82
50	31	28	91
55	34	31	100
60	37	33	109
65	40	36	118
70	43	39	128
75	47	42	137
80	50	44	146
85	53	47	155
90	56	50	164
95	59	53	173
100	62	56	182
105	65	58	191
110	68	61	200
115	71	64	210
120	75	67	219
125	78	69	228
130	81	72	237
135	84	75	246
140	87	78	255
145	90	81	264
150	93	83	273

Speed [KM/H]	Speed [MPH]	Detection Distance [m]	Detection Distance [ft]	Time to Collision [s]
	5		38
	10		54
	15		66
	20		77
	25		86
	30		94
	35		101
	40		108
	45		115
	50		121
	55		127
	60		133
	65		138
	70		143
	75		148
	80		153