Com. v. Whynaught

• Decision Date: 03 January 1979
• Citation: 377 Mass. 14,384 N.E.2d 1212
• Parties: COMMONWEALTH v. Kathleen WHYNAUGHT.
• Court: United States State Supreme Judicial Court of Massachusetts Supreme Court

Page 1212

384 N.E.2d 1212

377 Mass. 14

COMMONWEALTH v. Kathleen WHYNAUGHT.

Supreme Judicial Court of Massachusetts, Middlesex.

Argued Oct. 2, 1978.

Decided Jan. 3, 1979.

Michael J. McHugh, Legal Asst. to the Dist. Atty., Cambridge, for the Commonwealth.

Aram K. Berberian, Cranston, R. I., for defendant.

Before HENNESSEY, C. J., and QUIRICO, BRAUCHER, WILKINS and LIACOS, JJ.

HENNESSEY, Chief Justice.

The defendant, Kathleen Whynaught, was convicted of speeding pursuant to G.L. c. 90, § 17, after a jury-waived trial in the First District Court of Southern Middlesex. Appealing her conviction, she argues that the trial judge erroneously admitted readings taken from an untested radar speed measuring device and that the prosecution had a statutory burden, which it failed to meet, to prove excessive operation over a one-quarter mile course. We overrule the defendant's exceptions.

The facts are not in dispute. On August 19, 1976, State Trooper Michael Salzman, the detection half of a two person traffic control unit, was operating a radar device on Route 495 near Hopkinton. Observing readings from the radar unit, Trooper Salzman determined that an automobile was travelling seventy-five miles an hour on a highway posted for fifty-five. He so notified State Trooper John Brunnetta, the apprehending half of the unit, who stopped the defendant's vehicle and issued a citation.

At trial, Trooper Salzman testified that the radar unit he employed was made by the Dacatur Company and was tested for accuracy by means of an internal calibration mechanism. The testing procedure, he explained, involved the selection of two specific settings, one at thirty miles an hour and another at sixty miles an hour; if the unit when turned to those settings read out the correct number on a screen, it was accepted to be accurate. This procedure, he said, was followed approximately every hour on the date of the offense, including once forty-five minutes prior to his clocking the defendant. In addition to his own testing, Trooper Salzman stated that the instrument had been calibrated on different occasions by a radio engineer, although no specific dates were indicated.

The prosecution also offered the testimony of Trooper Brunnetta, who estimated that, on the basis of his independent observation of the defendant's vehicle, its speed was approximately seventy-five miles an hour. The officer testified that there was a clear area for visual observation, explaining "you could see the cars back easy."

1. Admissibility of Radar Evidence.

Ever since the appearance of the automobile impelled lawmakers to enact laws to restrict its speed, law enforcement officers have experimented with various types of speed detection devices, seeking reliable methods by which to measure vehicular velocity. From the beginning, objective means of speed determination have been thought desirable, because opinion evidence, while admissible, may tend to leave doubts in the minds of judges and jurors. E. C. Fisher & R. H. Reeder, Vehicle Traffic Law 143-144 (1974). Indeed, commencing with the acceptance of stopwatch evidence in Great Britain, see Gorham v. Brice, 18 T.L.R. 424 (K.B.Div.1902), law enforcement officials and courts have increasingly depended on scientific devices as a means of enforcing speeding laws, and, in turn, preventing traffic accidents. See McCormick, Evidence § 210 (2d ed. 1972).

In 1910 this court had occasion to consider the admissibility in a speeding case of evidence derived from a "Photo-Speed-Recorder." Commonwealth v. Buxton, 205 Mass. 49, 91 N.E. 128 (1910). The instrument challenged in that case determined an automobile's rate of speed through the use of a series of rapid sequence pictures and a chronometer; by comparing the photographs to measure the distance travelled, and then dividing by time, a motor vehicle's velocity could be easily calculated. In the belief that it would be beneficial to have objective proof from a "machine whose action (was) dependent upon the uniform working of the laws of nature," we held "Photo-Speed-Recorder" evidence admissible in speeding prosecutions. Id. at 53, 91 N.E. at 129.

Since our decision in Buxton, we have not been called on to decide the admissibility of evidence derived from more sophisticated speed detection devices. Other jurisdictions, however, have considered such questions and have had no difficulty in sanctioning, for evidence purposes, the use of the speedometer, Spokane v. Knight, 96 Wash. 403, 165 P. 105 (1917). State v. Tarquinio, 3 Conn.Cir. 566, 221 A.2d 595 (1966), or other electrical or mechanical recording instruments, see Webster Groves v. Quick, 323 S.W.2d 386 (Mo.App.1959); People v. Pett, 13 Misc.2d 975, 178 N.Y.S.2d 550 (1958). The speed detection instrument most heavily relied on, and the one in most common use, is the radar speedmeter. ¹ The application of radar to traffic control has been encouraged by the fact that those courts which have considered the issue have almost uniformly taken judicial notice of radar's underlying scientific principles and of the general capability of the speedmeter to measure speed accurately. See, e. g., State v. Dantonio, 18 N.J. 570, 115 A.2d 35 (1955); People v. Magri, 3 N.Y.2d 562, 170 N.Y.S.2d 335, 147 N.E.2d 728 (1958); Evernight v. Little Rock, 230 Ark. 695, 326 S.W.2d 796 (1959); State v. Tomanelli, 153 Conn. 365 216 A.2d 625 (1966); East Cleveland v. Ferell, 168 Ohio St. 298, 154 N.E.2d 630 (1958); United States v. Dreos, 156 F.Supp. 200 (D.Md.1957) (applying Maryland law).

Although the defendant does not challenge the validity of radar principles or their application to determining speed, we think it appropriate to state here our judicial notice of the radar speedmeter as an accurate and reliable means of measuring velocity. As we said in Commonwealth v. Fatalo, 346 Mass. 266, 269, 191 N.E.2d 479, 481 (1963), and have repeated more recently in Commonwealth v. Lykus, 367 Mass. 191, 196, 327 N.E.2d 671 (1975): "Judicial acceptance of a scientific theory or instrument can occur only when it follows a general acceptance by the community of scientists involved. When supported by substantial authority establishing scientific reliability, this court has not hesitated to accept the benefits of science." See also Commonwealth v. Vitello, --- Mass. ---, ---. ^A 381 N.E.2d 582 (1978). In light of society's widespread use of radar devices, in forms ranging from air-traffic control monitors to homing radars on guided missiles, see Skolnick, Introduction to Radar Systems 14-18 (1962), and considering other courts' acceptance of radar, we view the scientific basis of radar as indisputable. ²

The more substantial question in cases where radar results are offered regards the accuracy of the particular speedmeter at the time the speed measurement was made. While there has been some suggestion to the contrary, ³ most courts have agreed that the admission of radar evidence is conditioned on a demonstration to the court of the accuracy of the radar apparatus. See, e. g., State v. Gerdes, 291 Minn. 353, 191 N.W.2d 428 (1971); State v. Finkle, 128 N.J.Super. 199, 207, 319 A.2d 733 (App.Div.), aff'd 66 N.J. 139, 329 A.2d 65 (1974), cert. denied, 423 U.S. 836, 96 S.Ct. 61, 46 L.Ed.2d 54 (1975); People v. Perlman, 89 Misc.2d 973, 392 N.Y.S.2d 985 (N.Y.Dist.Ct.1977); Royals v. Commonwealth, 198 Va. 876, 96 S.E.2d 812 (1957). See also Latin, Tannehill & White, Remote Sensing Evidence and Environmental Law, 64 Calif.L.Rev. 1300, 1413-1414 (1976). There has been a divergence in views however, on the issue as to what tests are sufficient to prove accuracy. In this respect, some courts have found adequate foundations in various combinations of the following three means of testing radar speedmeters: (1) a "run through," in which another police car closes on the site, holding a given speedometer reading; (2) use of calibrated tuning forks, intended to produce frequencies which will cause the machine, if accurate, to read particular speeds; and (3) use of a signal generator within the machine for the same purpose. See McCormick, Supra. ⁴

It is our opinion that some foundation requirement pertaining to the accuracy of the particular radar instrument is appropriate in order to ensure that the persuasive force of scientific results is not improperly triggered. At present, however, we do not insist that this foundation be based exclusively on any one or two of the three principal tests or that testing occur with any given frequency. Instead, in any case where the issue is raised by the defendant, we leave it to the discretion of the trial judge to determine when a sufficient showing of the particular radar instrument's accuracy has been made. See Commonwealth v. Buxton,205 Mass. 49, 52, 91 N.E. 128 (1910); Guinan v. Famous Players-Lasky Corp.,267 Mass. 501, 521-522, 167 N.E. 235 (1929). We assume that judges will closely examine the nature of all testing procedures and that they will be guided in their admission decisions by the quality of the tests performed, rather than by their quantity. See People v. Perlman, supra, 89 Misc.2d at 978, 392 N.Y.S.2d 985. At the same time, we expect that the testing requirements judges impose will not be so onerous as to make use of radar devices a practical impossibility. ⁵ For example, the "run through" test referred to, Supra, is a simple procedure in which the test automobile's speedometer and the radar unit are mutually corroborative, although neither device may have been tested by more sophisticated methods.

In the instant case, the record indicates that the judge, over the defendant's objection, required no foundation whatsoever regarding the radar unit's accuracy. In direct examination, however, Trooper Salzman testified that the radar unit in question had been the subject of repeated testing by means of its internal calibration mechanism. Yet, the testimony of Trooper Salzman fails to provide any basis for...