Diamond v. Diehr

Diamond v. Diehr

Argued October 14, 1980
Decided March 3, 1981
Full case name Diamond, Commissioner of Patents and Trademarks v. Diehr, et al.
Citations

450 U.S. 175 (more)

101 S. Ct. 1048; 67 L. Ed. 2d 155; 1981 U.S. LEXIS 73; 49 U.S.L.W. 4194; 209 U.S.P.Q. (BNA) 1
Prior history Certiorari granted [445 U.S. 926]
Holding
A machine controlled by a computer program was patentable.
Court membership
Case opinions
Majority Rehnquist, joined by Burger, Stewart, White, Powell
Dissent Stevens, joined by Brennan, Marshall, Blackmun
Laws applied
35 U.S.C. § 101

Diamond v. Diehr, 450 U.S. 175 (1981), was a United States Supreme Court decision which held that controlling the execution of a physical process, by running a computer program did not preclude patentability of the invention as a whole. The high court reiterated its earlier holdings that mathematical formulas in the abstract could not be patented, but it held that the mere presence of a software element did not make an otherwise patent-eligible machine or process patent ineligible. Diehr was the third member of a trilogy of Supreme Court decisions on the patent-eligibility of computer software related inventions.[1]

Background

The problem and its solution

The inventors, respondents, filed a patent application for a "[process] for molding raw, uncured synthetic rubber into cured precision products." The process of curing synthetic rubber depends on a number of factors including time, temperature and thickness of the mold. Using the Arrhenius equation

 k = A e^{{-E_a}/{RT}}
which may be restated as ln(v) = CZ + x

it is possible to calculate when to open the press and to remove the cured, molded rubber. The problem was that there was, at the time the invention was made, no disclosed way to obtain an accurate measure of the temperature without opening the press.

The invention solved this problem by using embedded thermocouples to constantly check the temperature, and then feeding the measured values into a computer. The computer then used the Arrhenius equation to calculate when sufficient energy had been absorbed so that the molding machine should open the press.

The claims

Independent claim 1 of the allowed patent is representative. It provides:

1. A method of operating a rubber-molding press for precision molded compounds with the aid of a digital computer, comprising:

ln(v)=CZ+x
where v is the total required cure time,

Proceedings before Office and CCPA

The patent examiner rejected this invention as unpatentable subject matter under 35 U.S.C. 101. He argued that the steps performed by the computer were unpatentable as a computer program under Gottschalk v. Benson, 409 U.S. 63 (1972). The Board of Patent Appeals and Interferences of the USPTO affirmed the rejection. The Court of Customs and Patent Appeals (CCPA), the predecessor to the current Court of Appeals for the Federal Circuit, reversed, noting that an otherwise patentable invention did not become unpatentable simply because a computer was involved.

The U.S. Supreme Court granted the petition for certiorari by the Commissioner of Patents and Trademarks to resolve this question.

The Supreme Court's opinion

The Court repeated its earlier holding that mathematical formulas in the abstract are not eligible for patent protection. But it also held that a physical machine or process which makes use of a mathematical algorithm is different from an invention which claims the algorithm, as such, in the abstract. Thus, if the invention as a whole meets the requirements of patentabilitythat is, it involves "transforming or reducing an article to a different state or thing"it is patent-eligible, even if it includes a software component.

The CCPA's reversal of the patent rejection was affirmed. But the Court carefully avoided overruling Benson or Flook. It did criticize the analytic methodology of Flook, however, by challenging its use of analytic dissection, which the Flook Court based on Neilson v. Harford. The Diehr Court said, without citation of any supporting authority, that under section 101 the invention had to be considered as a whole.[3]

The patent

The patent that issued after the decision was U.S.Pat. No. 4,344,142, "Direct digital control of rubber molding presses." The patent includes 11 method claims, three of which are independent. All method claims relate to molding of physical articles. The only diagrams in the patent are flowcharts. There are no diagrams of machinery. As the dissenting opinion in Diehr noted, the patent specification "teaches nothing about the chemistry of the synthetic rubber-curing process, nothing about the raw materials to be used in curing synthetic rubber, nothing about the equipment to be used in the process, and nothing about the significance or effect of any process variable such as temperature, curing time, particular compositions of material, or mold configurations."[4]

Subsequent developments

For many years, it was believed that Diehr effectively overruled Flook, despite the majority opinion's avoiding any such statement.[5]

In 2012, in Mayo v. Prometheus, the unanimous opinion of the Supreme Court interpreted Diehr so as to harmonize it with Flook. The Court "found the overall process patent eligible because of the way the additional steps of the process [besides the equation] integrated the equation into the process as a whole."[6] The Court "nowhere suggested that all these steps, or at least the combination of those steps, were in context obvious, already in use, or purely conventional."[7] "These other steps apparently added to the formula something that in terms of patent law’s objectives had significance—they transformed the process into an inventive application of the formula."[8]

The Court interpreted Diehr slightly differently in Alice v. CLS Bank, another unanimous opinion, but without taking issue with the Mayo interpretation. The Alice Court said:

In Diehr, by contrast [with Flook], we held that a computer-implemented process for curing rubber was patent eligible, but not because it involved a computer. The claim employed a "well-known" mathematical equation, but it used that equation in a process designed to solve a technological problem in "conventional industry practice." The invention in Diehr used a "thermocouple" to record constant temperature measurements inside the rubber mold — something "the industry ha[d] not been able to obtain." The temperature measurements were then fed into a computer, which repeatedly recalculated the remaining cure time by using the mathematical equation. These additional steps, we recently explained, "transformed the process into an inventive application of the formula." Mayo, supra, at ___, 132 S.Ct., at 1299. In other words, the claims in Diehr were patent eligible because they improved an existing technological process, not because they were implemented on a computer.[9]

These two opinions state the current Supreme Court interpretation of what the Diehr case holds.

See also

References

The citations in this Article are written in Bluebook
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  1. The other two cases were Gottschalk v. Benson, 409 U.S. 63 (1972), and Parker v. Flook, 437 U.S. 584 (1978). The Supreme Court's most recent decisions on patent eligibility of software-related inventions are Bilski v. Kappos and Alice v. CLS Bank, both of which are cases concerning business methods.
  2. https://www.law.cornell.edu/supremecourt/text/450/175#fn1
  3. Section 103, which concerns obviousness, states that the obviousness or non-obviousness of what is claimed to be an invention must be determined by considering whether "the differences between the subject matter sought to be patented and the prior art are such that the subject matter as a whole would have been obvious at the time the invention was made." (Emphasis supplied.) No comparable language is found in section 101, which has retained substantially the same form since the first patent act in 1790.
  4. 450 U.S. at 206.
  5. See dissenting opinion of Justice Stevens in Diehr, 450 U.S. at 209-215 (contending that fact patterns are indistinguishable).
  6. Mayo, 132 S. Ct. at _.
  7. Mayo, 132 S. Ct. at _.
  8. Mayo, 132 S. Ct. at _.
  9. 132 S. Ct. at 2358 (citations omitted).

External links

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