Full opinion text
SWEENEY, Chief Judge. This is an action for infringement of U. S. Patents No. 2,104,949 (hereinafter referred to as ’949) and No. 2,199,227 (hereinafter referred to as ’227) brought by the plaintiff Alvin M. Marks as owner, and the plaintiff Depix Corporation as exclusive assignee of said patents. By counterclaim the defendant Polaroid Corporation charges the plaintiffs with infringement of three patents owned by it, and with infringement of its registered trademark “Polaroid”. A further charge of infringement of Reissue Patent No. 23,297 has been waived by the defendant during the trial, but this patent remains before this Court on the question of validity as requested in a prayer for declaratory relief filed by the plaintiffs. In answer to the charges of patent infringement the parties have advanced the usual defenses of invalidity and non-infringement together with certain other defenses to be passed upon later in this opinion. The plaintiffs’ reply further denies infringement of the defendant’s trademark “Polaroid” and asserts that this trademark is invalid because it is a descriptive and generic word which indicates the type of product and not its source or origin. Subject Matter and History The subject matter of all of the patents in suit relates to synthetic light polarizers and the process for their manufacture. Polarization is a common 'phenomenon which occurs in the world of nature through certain natural media, e. g., the sunlight reflected from a lake or ocean is, to a great extent, polarized due to the absorption by the water of certain light vibrations of an incident beam of light and its transmission of certain other vibrations of the same beam. This same phenomenon may be simulated by man through the use of artificial devices of the type which concern us here. Polarization is in essence the act or process of affecting light so as to cause the light vi-, brations to assume a definite form. When the human eye looks at an object transverse to the line of sight there are set up light vibrations in every direction. When the light is polarized the vibrations in all directions except one are eliminated by the absorption component of the polarizer. The remaining light vibrations are transmitted along the transmission axis of the polarizer and come through clear and unobscured to-the eye of the viewer. The phenomenon of Polarization has been known for more than one hundred and fifty years. However, until the development in the early part of this century of inexpensive synthetic polarizers, science has been limited to certain natural polarizers such as the Nicols prism, which costs approximately $1,000 a square inch and tourmaline, which costs $10 for two pieces, each %¿th of an inch in size. Attempts to manufacture synthetic polarizing crystals were made in 1853 by an English scientist named Herapath. He made minute fragile crystals of iodoquinine sulfate, which have come to be known as herapathites after their discoverer. Despite optimistic appraisals by Professor 'Herapath for the future of his discovery in the field of synthetic light polarizers, it does not appear that crystals made in accordance with his teachings ever became commercially successful. In the late 1920’s two precocious young scientists, Marks, a plaintiff in this action, and Dr. Land, President of Polaroid Corporation and patentee of three of the patents in suit, entered almost simultaneously into the field of synthetic light polarizers due to an interest each had in television. Independently and unknown to each other they consulted the same authority, Dr. Herapath, and attempted to develop large area synthetic polarizers in accordance with his teachings. Both experienced failure and struck out on new paths of their own. Marks, however, continued to follow the broad outlines of Herapath’s teachings in the sense that his conception of the ideal polarizer was one consisting essentially of a single continuous crystal grown out of solution. After much experimentation he finally achieved the result desired by a process which consisted of suspending glass plates in a solution of- the crystalline material over a relatively long period of time during which the solvent gradually evaporated, lowering the liquid level of the tank and causing the crystalline material to be thrown out of the solution and deposited on the surface of the glass supports. The relative motion between the liquid and the surface of the supports produced a surface tension which caused a specific alignment of the crystalline material. As we shall see later, alignment or orientation of the molecules of the substance is essential to procure a crystal effect. This process eventually ripened into the first Marks patent in issue in this suit. Dr. Land, on the other hand, became convinced from his duplications of Hera-path’s work that no process involving the growth of large crystals would be satisfactory since any such process would be too time consuming. At about this time it occurred to him that a large synthetic polarizer sufficiently inexpensive in price ought ideally to be a plastic; a large plastic sheet like celluloid in great rolls. Instead of growing large crystals of herapathite and depositing them on a glass support, he conceived of the idea of making extremely small herapathites and embedding them in a plastic carrier. These submicroscopic needles or crystals were oriented to substantial parallelism by extruding the plastic containing the needles through small apertures. The mechanical stress thus produced causes the needles to orient themselves just-as logs going downstream travel along butt end first. Patent applications covering this Land process and product were filed in 1929. Subsequently, Land demonstrated his “J sheet”, as the invention is called, to a Physics Colloquium at Harvard University in 1932, and in 1933 used it as a polarizer in connection with a stereoscopic system which he brought to Hollywood to demonstrate three-dimensional movies to Warner Brothers Laboratories. The basic patent on the J sheet is not in issue in this case. However, it is of interest in tracing the development of the art. Also it serves to cast doubt upon the plaintiff’s contention that Marks was the first person ever to make and sell a synthetic polarizer. It appears that after Marks had sufficiently developed his polarizer, his brother organized a company, known as Polarized Products Company, to exploit his product commercially. The Marks polarizing plates were first sold on the market in November of 1934 at prices of $16 per square inch and $1 for a plate ^4" x yy in size. These prices were later sharply reduced with the development by Marks in 1935 of the second patent in suit, called the intensification process. This patent discloses a method for speeding up the process of Marks’ previous patent, then taking the crystalline deposit, which due to the increased speed is discontinuous or punctuated with holes or voids, and intensifying it by subjecting the crystalline field to a supersaturated solution of the crystalline material. In this manner an additional crystal deposit is thrown out of solution which fills up the voids and evens off the pre-existing crystalline deposit. By this method production was speeded up about 90 times and the cost reduced by 99%. Patent applications covering the intensification process were filed in 1937. In the meantime, the first Polaroid Corporation had been organized in 1935 with Dr. Land as its president, and production of the J sheet was carried on. Two years later the present corporate defendant was organized with Land continuing as president and director of research. Subsequently Land began experimenting on a different type of polarizer employing cellophane and a direct dye or stain. Rolls of cellophane were swelled, stretched, and run through an iodine bath. Difficulty was encountered, however, with this process because the iodine was fugitive and would not stay in the cellophane sheet. Land experimented with different kinds of plastics and finally hit upon the complex of iodine with polyvinyl butyral. Immediately he shifted from polyvinyl butyral to polyvinyl alcohol and developed his “H sheet” which is made by taking a large roll of polyvinyl alcohol, heating and stretching it to orient the molecules, then affixing it to an unstretched backing of cellulose acetate, and floating the supported film of polyvinyl alcohol upon the surface of a bath containing a solution of iodine. A fourth step is employed in which the sheet is run through a bath of boric acid, which stabilizes the film and drives out excess iodine. The Polaroid Corporation first began to sell its “H sheet” in 1940 and since that time it has effectively supplanted the “J sheet” type of polarizer. Patent applications embodying the new ■Land products and processes were filed in October 1938 and May 1939, and eventually resulted in issuance of the three patents alleged in the defendant’s counterclaim to have been infringed by the plaintiffs here. Throughout the years Marks continued to manufacture and sell synthetic polarizers and to this end in conjunction with his brother and others caused several different business entities to be organized, including Polarized Products Company, Polarized Products Corporation, Pola-lite Company, Polalite Corporation, Depix Corporation, and Marks Polarized Corporation. The defendant here had previous litigation with at least one of these companies and its licensee. One action in Delaware against Polarized Products Corporation and Noma Electric Corporation was discontinued upon the companies ceasing to sell the product. In 1945 Polaroid brought another suit against Polarized Products Corporation and Noma Electric in the Southern District of New York alleging that the manufacture and sale of polarized sunglasses by them constituted an infringement of one of Polaroid’s patents also in suit in this case. Previous to this time Polarized Products Corporation had shifted from producing polarizers of the large herapathite crystals grown on glass and began to manufacture polarizers of butyral silicate on a plastic support. The litigation terminated in a consent decree in 1947 holding Polaroid’s patent valid and infringed. However, a year before the entry of the decree Marks had taken steps to separate himself from Polarized Products. He had resigned as a member of the Board of Directors, had terminated his license to the corporation, had sold out his stock interest in it and had left its employ. He refused to consent to the entry of the decree insofar as the question of infringement was concerned. If doubts remain as to whether Marks should be held bound by the consent decree, this Court will not act upon them. Since this case has gone to a hearing on the merits it is not going to be decided on the thin ground of prior foreclosures, but will be treated independently of previous litigation. After the entry of the consent, decree and injunction, Polarized Products Corporation went into bankruptcy and sold its assets at a bankruptcy sale where Marks bought up part of the manufacturing equipment and whatever polarizing material was offered for sale. Thereafter he repaired and reconstructed the equipment and installed it in the cellar of his home in Whitestone, Long Island, where within six or eight months he started operations again on a very modest scale. This business was carried on under the name of Polalite Corporation, a family corporation with Marks, his brother, and his mother as the only stockholders. From the fall of 1948 until late in 1952 a polyvinyl butyral silicate polarizer was produced by Marks or Polalite Corporation at the premises in Whitestone. The defendant here claims that these past activities of Marks or of some company completely dominated and controlled by him and his brother constituted infringements of claims 1, 2, 3, 4, 5, 6, 17, 18, 19, 20, 22, and 24 of Patent No. 2,328,219 (hereinafter referred to as ’219) and claims 11, 17, and 18 of Patent No. 2,-454,515 (hereinafter referred to as ’515). As no evidence was introduced to show that either Marks or Depix is at the present time manufacturing polarizers of this type, any such infringement as is alleged to exist in this part of the defendant’s counterclaim must be treated as consummated in the period 1948 to 1952. Approximately two years ago a great impact was made upon the movie-going public with the showing of the first feature length 3-D movie , “Bwana Devil”. As a result, a very large demand was created within the motion picture industry for 3-D viewers, and the business of supplying them to the theatres became big business. The Polaroid Corporation had been making 3-D viewers for as far back as 1939 when it supplied four and a half million to the World’s Fairs at New York and San Francisco, and f«j»r other projects in and around New York City at science museums, but when the 3-D pictures caught on with the public a great pressure was put upon Polaroid by various of the Hollywood fraternity to secure exclusive or other rights for distribútion. Polaroid had already licensed Natural Vision Corporation as its exclusive distributor for a set period and refused all other overtures. Depix Corporation, one of the plaintiffs here, was incorporated in February, 1953 by Marks, his brother, and their mother, and licensed to produce polarizers under the Marks patents. It appears that within a few months after the institution of this action, Marks resigned as president of Depix and the stock in that company, which the Marks family owned indirectly through ownership of the stock of another corporation, was sold out. In the meantime Marks and his family have organized another corporation known as Marks Polarized Corporation. At the present time Depix retains its corporate existence but it has discontinued manufacturing polarizing materials under license from Marks. Findings of Fact Marks patent 2,104,949 — granted January 11, 1938, on an application filed March 22,1933, relates to crystalline formations formed on supporting mediums and to the process for producing the same. The process disclosed consists essentially in depositing from solution on the surface of a transparent support a thin film of a crystalline material contained in the solution. The apparatus referred to as suitable for carrying out the process includes a tank and several supporting mediums which are mounted in the tank and arranged parallel with a uniform distance between them. The tank is filled with a solution of iodoquinine sulphate (for example) to a depth greatly in excess of the vertical dimensions of the deposit to be obtained on the supports. The supports are lowered into the solution perpendicular to the liquid level in the tank and then the liquid level of the solution is slowly moved with respect to the surfaces of the glass plates in such a way that it lowers with respect to the plates. In the example used by the patentee to illustrate his invention, the evaporation which naturally occurs in the system produces a satisfactory lowering of the liquid level, although under certain other conditions of operation other means for producing such a movement between the two mediums are claimed by the patentee. As the liquid level lowers, the crystalline layer is deposited out of solution onto the surface of the glass plates. This takes place at the meniscus or point of contact between the plate and the solution where the solution is drawn upwards to a considerable extent due to the surface tension between the glass and the crystalline layer. The liquid in the meniscus is under tension in a vertical direction which acts to align the solution molecules in such a way that the iodoquinine ■ sulfate molecules, in crystallizing out of the solution, are definitely oriented so as to form effectively or actually a single crystal in contradistinction to a number of haphazard crystals. Working at atmosphere pressure and with a temperature between 18°C and 27°C, a lowering of 69 millimeters is produced in forty-five days. The following seven factors are listed by the patentee as important in obtaining desirable results: (1) The surface tension between the solution, the atmosphere above the solution and the supporting medium. (2) The size, geometry, groups and immobility of the solvent molecule. (3) The solubility of the crystalline substance dissolved in the solvent. (4) The vapor pressure of the solvent and the partial vapor pressure of the solvent above the solution. (5) The temperature of the system. (6) The ratio of the evaporating surface area to the area of diffusion at the place where the liquid surface is bent upwardly. (7) The rate of diffusion of the crystalline substance from the liquid surface downwardly into the less concentrated body of the liquid. The patent mentions other crystalline material suitable in the process and describes in some detail the effect upon the process of modifications in the concentrations of solutions, in solvents, in temperatures, in withdrawal rates of supports, and in atmospheric conditions. The resulting product is described as a unitary crystalline structure or layer deposited on the surface of the glass plates which in effect comprises a single crystal. The crystal is firmly attached to or mechanically interlocked with the glass surface without the use of any intermediate binding medium. The article is further described as a transparent isotropic plate, coated with a layer of substance capable of plane polarizing light in the same direction over the entire plate. The size of the crystalline coated surface is claimed in the specification to depend only on the size of the supporting surface, which within reasonable limits may be of any size. Of the prior art references cited against this patent by the defendant, reliance is placed mainly upon a Belgian patent to Zimmern granted in 1924, an Austrian patent to Zimmern granted in 1928, two articles by Zimmern in Comptes Rendus, May 8, 1926 and May 17, 1926, and the alleged prior public use or prior invention in this country by Professor Mason and Dr. McClellan at Cornell University and their associates, Robert A. Smith and Louis W. Chubb, Jr., at Mahwak, New Jersey. None of these references were considered by the Patent Office. The Zimmern patents, which are substantially identical, claim a process for the production of a polarizing surface which is simultaneously transparent, of large extent, and with elements which are all oriented essentially the same way. In accordance with the process as specified, a concentrated solution of quinine bisulfate is first prepared and poured into a vat. A vessel containing five grams of metallic iodine is placed near the vat with a heating device added in order to accelerate the evaporation of the iodine. The entire arrangement is then covered by means of a bell jar. The iodine vapors escape from the vessel and react with the solution, giving rise to the formation at the surface of the solution, of a film of herapathite of greater or lesser extension or of several films being more or less adjacent to each other. The films are then removed from the vat by raising upward a sheet of glass which has previously been placed in the bottom of the vat and to which the film then adheres. However, the films thus obtained are not very highly developed and in order to obtain better results, the patent teaches the adoption of several alternate arrangements in addition. Included among these is the use of a very deep> and very narrow vat provided with an orifice in its bottom so that the solution will flow very slowly (in at least several hours) through it in such a manner that, under the action of the capillary forces to which the herapathite film is being subjected it will come to adhere either to the walls of the vat or preferably to glass plates placed against the walls which can be removed easily. The patent also discloses use of an entire series of removable glass plates spaced so as to form a series of very narrow vertical spaces like in an electric storage battery. In the May 17 Comptes Rendus article, Zimmern teaches that the crystallization takes place in the concave meniscus which wets the glass. He also discloses there that a temperature of almost 30°C is employed. The two patents specify that iodine in the form of a solution in alcohol or ether may be substituted for metallic iodine. The nature of the product obtained is gleaned from these descriptions in the Zimmern references: “* * * Plates * * * covered with well aligned herapathite extending over the major portion of their surfaces * * “ * * * A thin layer consisting of herapathite crystals, the orientation of which is the same throughout or at least shows no noticeable deviation.” “Regular strands of herapathite, transparent and of uniform orientation, which reach a size of about five millimeters on a side.” In the above references it is seen that Zimmern employs a vertical support or supports positioned in a deep tank; that he depends upon the principles of surface tension and relative motion between support and liquid level; that he precipitates crystalline growth at the meniscus formed between the surface of the liquid and the supports. Consequently none of these things are original with Marks. Further, Zimmern employs the same basic chemicals as Marks in the same manner with the exception that Marks uses concentrated solution of iodoquinine sulfate throughout whereas Zimmern starts with a concentrated solution of quinine sulfate which is reacted with iodine vapor to form a solution of iodoquinine sulfate. Both Zimmern and Marks operate at substantially the same temperatures. The means disclosed by Marks to produce the relative motion between the supports and the liquid is evaporation. Zimmern produces this effect by running the solution off slowly through an orifice in the bottom of the tank. However, Marks distinctly recites in the patent that he is not limited to evaporation to bring about the desired relative motion but other means may also be used. The ’949 patent discloses that by using evaporation to lower the liquid level, a lowering of sixty-nine millimeters was produced in forty-five days. However, it is specified that this time element is by way of example and is not intended as a limitation. The fact that Zimmern employs iodine in the vapor phase to react with the quinine bisulfate in solution rather than introducing liquid iodine into the solution at the start does not constitute an essential difference, especially when it is remembered that Zimmern discloses the substitution of one for the other in his two patents. A comparison of the processes disclosed in the Zimmern references and this Marks’ patent convinces me that the latter discloses no important step which is not also contained in the former and that as a result the two are substantially the same. For the above reasons I find and rule that the process disclosed in the Zimmern references constitutes a complete anticipation of the process claims in the ’949 patent, and that the latter are invalid for want of novelty. It is my opinion that the product-claims of ’949 are also invalid over the product described in the same Zimmern references. Marks describes his product as a unitary crystalline structure which in effect comprises a single crystal. Zimmern on the other hand describes his product as a thin layer of herapathite crystals extending over the major portion of the surface of the support in which the orientation is the same throughout or at least shows no noticeable deviation. From these descriptions it would appear that Marks’ polarizing surface is made up of a single unitary crystal whereas Zimmern’s layer is composed of a plurality of single unitary crystals of the magnitude of five millimeters on a side which are oriented to substantial parallelism. On examination of early Marks’ polarizers introduced in evidence (as Defendant’s exhibit C 15 and Plaintiff’s exhibit 57) we discover what Marks’ concept of single crystallinity is as applied to his product. It appears to mean substantially uniform orientation of crystalline growth as distinguished from a structure made up of crystalline deposits in which the individual elements are arranged in a haphazard fashion. The exhibits introduced show that Marks did not achieve perfect orientation, but a product in which certain vertical areas or strips were slightly out of alignment with the crystalline mass, or in other words, a product in which the orientation axis shifted very slightly from area to area. Zimmern’s product is composed of a system of small crystalline patches or skins covering the entire plate and arranged substantially parallel with such deviation as exists not being pronounced. While I am of the opinion that the two products disclosed are not identical, still I think that whatever difference exists is a difference of degree and not of kind and that although Marks’ product may be conceded to be a better polarizer than Zimmern’s, it does not amount to invention over the latter reference. Consequently I find that the product claims of Patent No. 2,104,949 as well as the process claims of that patent are invalid. The alleged prior public use of Mason, McClellan, Smith and Chubb, cited by the defendant as invalidating the Marks’ '949 patent, commenced in the early part of 1930 after Professor Mason and his young assistant, McClellan, has been hired by Smith to attempt to duplicate and improve Zimmern’s work. This development work, together with the processes employed, the materials used, and the results obtained at the various stages of progress of the work, are all set out in depositions of Mason and McClellan and in correspondence between Mason and Smith submitted by the defendants as exhibits in connection with the depositions. It appears that Smith’s purpose in retaining the scientists at Cornell University was the ultimate utilization by him and his associates of any process developed there by Mason and McClellan in the commercial production of large area polarizers adopted to eliminate glare from automobile headlights. The work of Mason and McClellan in the laboratory at Ithaca continued for approximately two years and after they had produced films of a character claimed by Mason to be usable for microscopic work, for headlight work and presumably for other things, it was eventually transferred to Mr. Smith’s home at Mahwak, New Jersey, where Mr. Smith and Mr. Chubb carried on without the further assistance of Mason and McClellan. Without going into detail as to the day to day experiments and developments of Professor Mason and his assistant, I am convinced from a careful scrutiny of the evidence on this phase of the case, that at least as early as January, 1931, (which is more than two years before the Marks’ application was filed) the process employed by Mason and McClellan and the product resulting therefrom are sufficiently similar to the Marks’ process and product of patent ’949 as to constitute anticipations of the latter. In reaching this conclusion, I am also mindful of certain differences which exist, i. e. in the process as practiced by Mason and McClellan greater withdrawal speeds were used; additional mechanical means for orienting the crystals were employed in the form of scratches and gaps provided on the glass plates; alcohol was often eliminated from the solution and acetic acid and water used alone as solvents; iodine was used in the vapor phase as in Zimmern rather than being added to the original solution in its liquid form. In regard to the speed of withdrawal, Mason testified in his deposition that a wide range of speeds was tried but that he and McClellan were always striving for greater speed without sacrifice of quality [because] “we had in mind always that this must always be commercial and that a very slow method of growth, although ideal from the crystallographic theory, would not be economic if we could not turn out quantities of film in a commercially feasible time * * # >> It is my opinion that what is claimed by Marks in his patent is certainly implicit in this earlier process which included these additional or diverse steps and when considered from this point of view, the enumerated differences do not destroy the effect of the prior public use as anticipation. Nor does the fact that a product made in accordance with this earlier process was never sold or commercially successful change this result. Smith v. Hall, 301 U.S. 216, 233, 57 S.Ct. 711, 81 L.Ed. 1049. The plaintiffs further seek to avoid the effect of the prior use by asserting that the process as practiced by Mason and McClellan at Ithaca, and subsequently by Smith and Chubb, Jr., at Mahwak, was a secret process and hence does not constitute a “public use”. However, the plaintiffs offered no affirmative evidence in support of this contention to show that positive measures to assure secrecy were taken by the interested parties such as forbidding strangers or outsiders access to the premises where the process was practiced, enjoining one another, co-workers or subordinates to secrecy, keeping important equipment, data and working premises under lock, etc. On the other hand, I find from the evidence that there was a constant going back and forth of the other men in the Microscopy Department, in and out of the laboratory at Cornell, during which many discussions were carried on about the problems involved. One who alleges a secret use should offer evidence to sustain it. E. W. Bliss Co. v. Southern Can Co., D.C., 251 F. 903. The plaintiffs have failed to do this in the face of testimony which seems adequate in my eyes to show a prior public use of the process under consideration. For the above reasons I find that Marks’ Patent No. 2,104,949 is invalid on the additional ground of prior public use of the patent more than two years before the application for 2,104,949 was filed. Marks patent 2,199,227 — granted April 30, 1940, on an application filed June 11, 1937, relates to a method for coating a supporting structure with a crystalline substance and may be considered as an improvement on Marks’ earlier patent. It involves two steps. The first step relates to the depositing of an initial crystalline coating on the support at speeds greatly exceeding those employed in the first patent. This initial layer or crystalline field, as it is described, is incomplete or imperfect in the sense that it is punctuated with voids or little holes in which the crystalline material is absent. It may appear in three different forms, i. e. as an “island structure” in which open areas for the most part join each other; or as a “semi-meshed structure” where joined open areas and joined crystal areas exists; or as an “open-meshed structure” where the crystalline structure forms a lattice in which the open areas for the most part do not join. The apparatus described as suitable for depositing the initial layer is much more detailed than that outlined in the earlier Marks patent. It provides for a small tank which contains the crystalline solution suspended by a pontoon device on top of liquid within a larger tank. A rack of glass plates is suspended within the solution as before, but in the present patent the relative movement between the supports and the liquid surface is accomplished both by evaporation and by running out the liquid in the larger tank through a valve in its bottom. The specification explains how, by varying certain contributing factors, any one of the three types of crystal fields may be obtained. Further, it shows how, by relating certain factors, polarizers may be produced with their polarizing axes at different angles with respect to the plane of the solution surface. To obtain a crystalline coating of substantially uniform optical orientation, the process is so controlled and the constituents used are so selected as to cause one particular alignment with respect to the solution surface to dominate over all recessive alignments. As an aid to this result, a vibrator is provided in the apparatus which produces a vibratory motion between the solution surface and the plates. Once the desired crystal field has been deposited, then the second step of the process, called intensification, is employed. This consists in flowing over the crystal field a supersaturated solution of the same crystalline substance which is allowed to remain on the plate for a short time and then is run off. By this treatment new crystalline material is thrown out of solution which fills in the open areas or voids of the pre-existing crystal field and causes it to grow. Inasmuch as the optical orientation of the crystal field is substantially uniform throughout, the crystalline structure grown from the intensification step is also substantially optically uniform. The intensification .procedure may be repeated two or three times in order to thicken the coating. Claim 9 of patent 2,199,227, alleged to be infringed by the defendant, reads: “9. The method of completing a crystalline coating in the form of interlocking crystal areas and open areas, the crystals of which have substantially uniform optical orientation, comprising applying to the coating a supersaturated solution of the crystalline substance to cause the crystals to grow from the solute of the solution to complete the crystalline coating and form a substantially unitary crystalline structure of the same orientation as said original coating”. It is to be noted that what is claimed here is only the method of intensification. The first reference cited by the defendant as anticipating claim 9 is an article written by Dr. Herapath in 1883 in Philosophical Magazine, Volume 6, 4th Series, pages 346-381. After describing his process for isolating and mounting crystals of herapathite upon a glass support, Herapath discloses the use of additional quantities of iodine in three different connections. In the first disclosure he employs it added to a little cold distilled water to wash off any excess mother liquid and to prevent the crystals of herapathite from redissolving. In the second instance he teaches placing the dried crystals under a cupping glass, having a watch-glass with a few drops of tincture of iodine in it. “This”, he says, “gives a decidedly black tone to the field; and if the crystals were before too thin to obstruct all the light, and thus give a red or purplish violet tint, its power of polarization will be very materially improved by following the above simple directions.” In the final instance Herapath provides for saturating with iodine the cement, i. e. Canada balsam, used to secure a covering plate to the mount. The iodine is used here in order to prevent the Canada balsam from attacking the crystals and dissolving out the iodine. I find that this Herapath reference does not anticipate the intensification process as described in the Marks patent. Herapath’s additional applications of iodine are in the vapor or liquid phase uncombined with the ingredients of the previously deposited crystal as in the Marks disclosure. Also the former uses subsequent iodine treatments either to protect and preserve- the crystal or to increase its polarizing properties. Marks, on the other hand, employs his intensification process for additional purposes, among which are to speed up the output of his product and to fatten up or increase the thickness and continuity of the pre-existing crystalline structure. The prior public use or prior invention of Mason, McClellan, Smith and Chubb cited earlier against the first Marks patent, is also relied upon by the defendant as anticipating the ’227 patent. From a consideration of the evidence introduced to support this reference, it is evident that a process referred to., as “intensification” by these scientists was employed by them commencing early in their work and continuing throughout the course of its development. Numerous references to an intensification step are contained in the correspondence between Mason and Smith. Physical exhibits of intensified deposits of crystals made by Mason and McClellan in 1931 and 1932 were introduced in evidence as defendant’s Exhibits D 30, D 37, D 38 and D 39. Mason employed the procedure of building up the thickness of the layer of crystal by depositing additional crystalline material on it from solution which then increased the thickness of the portions that were too thin and gave them, as well as the originally thick portions, an adequate polarizing effect and adequate cut-off. This process of rendering the film more uniform in thickness depended on having crystalline material substantially covering the glass plate on all portions. Chubb used the intensification process in the summer of 1932 when he came to work for Smith at Mahwak, New Jersey. According to him there were a number of ways in which the intensification was performed including dissolving herapathite compound itself in warm alcohol, so that the solution was supersaturated, and then coating the first layer either by spraying or flowing on the additional crystalline material. A consideration of this evidence convinces me that the intensification process, as claimed by Marks in Patent No. 2,199,227, was not new with Marks and that as a result claim 9 of the patent is invalid for want of novelty. Claim 11, also alleged to be infringed by the defendant, reads as follows: “11. The method of coating a supporting surface with an optically continuous crystalline coating of a substantially uniform optical orientation, comprising first crystallizing on the supporting surface a crystal field of an island, semi-mesh or open-mesh structure in which the crystalline structure is of substantially uniform optical orientation, and applying to the supporting surface thus coated a super-saturated solution of the crystalline substance to cause the crystal field to grow from the solute of the solution to complete the coating to form a substantially unitary crystalline structure having the same optical orientation as said original coating.” This claim involves two steps; a first step in which a basic crystal field of one of the types specified is deposited; and a second step in which the crystalline structure is completed by intensification. Granted that there is nothing new in the intensification process considered by itself, still this step in combination with a new or different preliminary step may amount to invention. I do not read the ’227 patent as urged by the defendant, that the only invention possibly contained therein relates to the intensification process. A simple reading of the twenty claims shows that Marks claims as invention additional features either in combination with or apart from intensification. Considering the invention disclosed in this patent in its broadest aspect, it appears to contain several novel features. For instance, means are disclosed for producing a crystalline field undercoating of the several different types enumerated which is of a substantially uniform optical orientation. Further the disclosures show how to control the alignment of this coating so that it may assume various angles with respect to the solution surface and block out any recessive alignments tending to form. The advantages of first depositing one layer of the types specified and then superimposing another layer on top of it are: such plates can be produced more rapidly; the alignment of the desired crystalline structure is easier to control; and desired uniformity is more easily obtained since factors tending to cause misalignment are rendered less effective. In addition to the' above new disclosures in the patent, other improvements in the earlier Marks process include the provision of additional means for lowering the liquid level in the solution tank intended to act simultaneously with the lowering caused by evaporation, greatly accelerated withdrawal times, and the provision of a vibrating motion between the solution surface and plates which aids in obtaining the desired uniform alignment. These several innovations employed in the first phase of the improved Marks process when combined with the second phase or intensification step amount to invention. Claim 11 of the patent is directed to this combination of two steps, one new and the other old. Its wording is not a comprehensive statement of the entire process involved in the first step, however it does particularize in describing it to the extent that it requires the first deposit to be “a crystal field of an island, semi-mesh or open-mesh structure”. This is sufficient to remove claim 11 from the work done by Mason, McClellan, Smith and Chubb. None of the other cited references anticipate this claim. For the above reasons I find that claim 11 of patent 2,199,227 is valid. Even though we were to find all the Marks patent claims valid, the complaint must nevertheless be dismissed on the ground that the defendant has not infringed the plaintiffs’ patents. The defendant manufactures its H sheet, the alleged infringing device, by heating a sheet of polyvinyl alcohol which it purchases in rolls; stretching the heated sheet to orient its molecules; backing the stretched sheet to a sheet of cellulose acetate which acts as a support for the polyvinyl alcohol sheet; floating the backed sheet upon a solution of iodine with the stretched polyvinyl alcohol in contact with the solution so as to stain the polyvinyl alcohol with iodine; and finally running the stained sheet through a boric acid bath to stabilize it. The two claims of patent '949 alleged to be infringed by H sheet, claims 5 and 16, are method and product claims respectively. Claim 5 is directed to “the method of depositing a crystalline structure on a supporting surface which comprises dissolving the crystalline substance in a liquid medium, at least partially immersing said supporting surface in said liquid medium, causing said substance to be crystallized from said medium and:to be deposited on said surface with a regulated orientation, and simultaneously relatively so moving said liquid medium and supporting surface in such manner as not to break the character of the crystalline structure deposited”. Claim 16 calls for “a light polarizing device comprising a transparent supporting medium having a surface coated with a crystalline substance having the inherent characteristic of polarizing ordinary incident light, said coating comprising a substantially continuous crystalline layer directly crystallized on the surface from solution and forming effectively a single crystal of substantially uniform optical orientation”. Marks claims that the defendant’s process and product read directly on these claims in these respects: the support is the cellulose acetate backing; the immersing of the support takes place when the sheet is run over the iodine bath at which time the crystalline substance, i. e. iodine, is crystallized from the liquid medium and deposited on the cellulose acetate with a regulated orientation, and the relative motion between support and solution takes place, with the result that a crystalline coating of the kind described by Marks is found in the defendant’s H sheet deposited on the type of support claimed by Marks. The plaintiffs seek to read claims 9 and 11 of the second patent (set forth above) on the defendant’s process by the following reasoning: when the backed film of polyvinyl alcohol is floated over the solution of iodine, the iodine penetrates the pores of the polyvinyl alcohol, and reaches to the surface of the cellulose acetate layer where some of it crystallizes out in the form of an island structure, the remainder of the iodine being present in the interstices surrounding the islands in the form of dissolved unoriented iodine, at this stage the first step of the process has been completed: in the intensification step which follows the iodine not yet crystallized is driven in and completes the crystalline coating. This takes place in the boric acid bath where as the boric acid enters the structure, it causes the solution of iodine present in the interstices to become supersaturated with respect to the island structure which results in additional crystals being deposited to fill the voids and complete the crystalline coating. The testimony and evidence offered to refute the charge of infringement points out several critical differences between the products and processes of the parties and in many important respects contradicts the testimony of Mr. Marks, the principal witness offered by the plaintiff to establish the charge of infringement. From a consideration of all the evidence on the question of infringement, I make the following findings:' - 1. The iodine in H sheet is present in a non-crystalline form, being an absorption complex in which molecular oriented polyvinyl alcohol is complexed with iodine. This finding is supported by X-ray diffraction patterns of defendant’s product, which the defendant’s expert, Dr. Mark, testified failed to show the type of X-ray finding typical of crystalline iodine. 2. Nothing is deposited from solution on to the cellulose acetate support at any stage of the H Sheet process, as no iodine ever penetrates to the cellulose acetate backing. The iodine is absorbed by the outer layer of polyvinyl alcohol which it penetrates to about 25% to 30%, leaving the remaining portion of the polyvinyl alcohol free from any iodine. 3. The iodine employed in the process of H sheet is a dilute solution, not a concentrated or supersaturated solution. 4. The defendant’s process does not produce at any stage of the manufacture of H sheet a crystal field of any of the types specified in claims 9 and 11 .of ’227, but to the contrary “H Sheet” appears as a homogenous mass under a microscope which .does not resemble any of the microphotographs appearing in the second Marks patent. These several ways in which the process and product of defendant fail to read upon the claims in litigation are crucial and form a sufficient basis for a holding of non-infringement. However, in the view I take of the processes and products of the litigants, these distinguishing characteristics are not the sole basis for my finding of non-infringement', since I am convinced that in a larger sense a reading of the claims of plaintiffs’ patents to cover H Sheet and the process for its manufacture is unrealistic. In order for the plaintiffs to assert infringement here, they are practically forced to take inconsistent positions in that they must alternately urge a narrow construction of the claims sued upon in order to avoid anticipation by such similar devices and methods as Zimmern and Mason and McClellan, and a broad construction in order to claim infringement by such diverse products and processes as those of the defendant. The fact that the claims of the Marks patents might be phrased in terms broad enough to cover many features of defendant’s process and product does not in itself establish infringement. The claims are to be read in connection with the specifications, and a patentee’s broadest claim can be no broader than his actual invention, Kemart Corp. v. Printing Arts Research Laboratories, 9 Cir., 201 F.2d 624, 629. Viewed in this light the plaintiffs and the defendant reach different results by quite different means. This is seen, for instance, from the fact that the defendant produces its polarizers in sheets one thousand feet long and three feet wide at the rate .of twenty feet per minute, whereas following the first Marks patent polarizing areas just- a fraction of this size are produced only with the lapse .of a considerable time. Further, the continuous commercial process of the defendant in which large rolls of the polarizing sheet are run first through a hot oven, then' stretched, bonded to a backing sheet, and floating on an iodine bath and finally stabilized in a boric acid bath, is broadly divergent from a process in which crystals are carefully grown on a dipped support or supports through the use of natural crystallographic forces and then, as in the case of the second patent, are intensified by a subsequent pouring on of the same material in supersaturated form. Similarities do exist, though due in large part to the broad wording of the claims of the patents. In any case, the differences are more considerable than the similarities. Consequently I hold that patents ’949 and ’227 are not infringed by the accused process and product of the defendant. Conclusions of Law I conclude and rule that claims 5 and 16 of Patent No. 2,104,949 and claim 9 of Patent No. 2,199,227 are invalid for anticipation or lack of invention ; that claim 11 of Patent No. 2,199,-227 is valid; that if claims 5 and 16 of the first patent and claim 9 of the second patent are held to be valid, still the complaint must be dismissed on the ground that none of the claims of the plaintiffs’ patents have been infringed by the defendant. Validity of the Defendant’s Patents In its counterclaim the defendant charges plaintiffs with infringement of three patents to Dr. Land, No. 2,454,515 (hereinafter referred, to as ’5.15), issued November 23, 1948, on an application filed October 29,1938; No. 2,328,219 (hereinafter referred to as' ’219), issued August 31, 1943, on an application divided from the application filed October 29, 1938 during the pendency of an interference in which the original application was involved; and No. 2,237,567 (hereinafter referred to as ’567), issued April 8, 1941, on an application filed May 4, 1939. The specifications' of patents ’515 and • ’219 are substantially identical, the difference being that the parent, i. :e.' ’5.15, is generic, claiming as the material to be used transparent, linear, high polymers such as a cellulose compound, as for instance cellulose . acetate. or ethyl cellulose, or regenerated cellulose or a vinyl' compound, .such as a'.plasticized vinyl acetal resin, whereas the material claimed in ’219 is more specific, being limited to the transparent vinyl compounds, with some claims further limited to a vinyl acetal resin or to polyvinyl butyral. Both patents are directed to a product which is a new and improved light-polarizer, and to the process of manufacturing the same which comprises rendering the plastic rubber-elastic, stretching it while in that state substantially to the limit of extension of its rubber-elastic state, then holding it in the stretched, extended position or setting it so that the deformation set up in the sheet is retained. At some stage of the process, either before or after it has been stretched, the plastic sheet is dyed, either by a direct cotton dye or a suitable mordant dye, or by iodine or bomine or a metal, such as mercury, silver, gold, copper, etc. The specifications recite certain tests for determining whether products fall within the scope of the invention, such as degree of tensile strength, directions of monochroism within the sheet, presence or lack of polarized light interference and transmission percentages of the sheet for both components of an incident beam of light. The specifications teach that in every case the plastic should be rendered rubber-elastic. This last term is defined as an elastic condition closely similar to the elasticity possessed by vulcanized rubber, in which state the plastic may be stretched or extended an appreciable amount without permanent distortion or alteration in the structure of the sheet so that when the stress or strain is relieved, the sheet tends to return to its original form and shape. The plastic may already be in the rubber-elastic state when purchased (as in the case of Vinal which contains a plasticizer) or may be rendered rubber-elastic either by heating or by adding a swelling agent, sucli as'sodium hydroxide. It is further specified that the extension of. the treated sheet should be substantially to the limit of its rubber-elasT •tic stretch. “Generally speaking this means that the sheet should be extended substantially to, but just below, the point where it ruptures.” “However,” the specifications add, “this is not a completely satisfactory test, for in many cases the plastic sheet will not rupture even if extended beyond the limit of its rubber-elastic state.” Three product claims and one process claim of the ’515 patent are alleged to be infringed by the plaintiffs. These four claims define the material to be used as a transparent, linear, high molecular weight organic plastic or as a light-transmitting high molecular weight synthetic linear polymer. Claim 11 calls for forming a uniform thin layer of the plastic, applying a force to it while heated in such direction as to align the molecules of the plastic in parallelism and at some stage of the process incorporating a dichroic dye within the layer. Claim 12 calls for a plane polarizing film which has been extended under stress in the solid unoriented state with the polarizing substance contained in the solid polymer, to a state of permanent high linear extension and molecular orientation of the polymer and of the polarizing substance in the direction of the stress. Claim 17 calls for a product in which the molecules of the plastic and the dye are oriented to substantial parallelism and in which the polarizing sheet has been so highly extended in the rubber-elastic state that the directions of monochroism within the sheet make with each other an angle greater than 160°. Claim 18 calls for the product of claim 17 in which the dichroic dye comprises iodine. The defendant charges the plaintiffs with infringement of claims 1 to 6, 17, 18,19, 20, 22 and 24 of patent ’219. Claims 1 through 6 call for a light polarizer comprising a sheet of a transparent vinyl compound which has its molecules substantially oriented and a dichroic substance incorporated therewith. These claims further distinguish from one another in calling for an angle of monochroism within the sheet greater than 165°; a dichroic ratio in excess of 9; an absorption percentage of 98 of one component of incident light; a dichroic substance comprising an element; and a dichroic substance comprising iodine. Claims 17, 18 and 19 are directed specifically to polyvinyl butyral with further specification in relation to the dichroic substance used and the angle of monochroism. Claims 20, 22 and 24 call either for the process of making a light polarizer by extending a rubbery-elastic sheet of the plastic until the molecules are substantially oriented or for a product in which the plastic is under internal linear strain so that it will contract parallel to a predetermined direction if the strain is released or for such a product in which the dichroic substance is iodine. Patent No. 2,737,567 which is a continuation in part of the ’515 patent, is directed specifically to polyvinyl alcohol as the plastic material to be used in the production of polarizers. According to the process disclosed, a cast sheet of polyvinyl alcohol is heated to a temperature at which it can be extended by stretching, but without flowing. A suitable temperature is one in the neighborhood of 130°C. The sheet is then stretched until its molecules are in substantially oriented alignment. The degree of stretch may be varied widely, i. e. from two and one-half to eight times the length of the sheet, with the understanding that in general the greater the stretch, the more efficient the polarizer produced by following the invention. There is nowhere in this patent the limitation that the sheet be stretched in the rubber-elastic state or that the stretch be to the limit of extension of that state. The stretched sheet is then stained with a solution of a polarizing polyiodide, the stain preferably being applied in the form of a water solution. The dye may be applied to the sheet in any of a number of ways. It may be sprayed on the sheet, or the sheet may be passed through the solution, or it may be incorporated with the solution of polyvinyl alcohol prior to the casting of the film. Suitable plasticizers, such as glycerine may be employed with the polyvinyl alcohol in forming the sheet. The specifications point out that ten per cent by weight of such plasticizers has not proved excessive. The product produced by the invention is described as a substantially uniaxial polarizer, consisting of a sorption complex of iodine on solid polyvinyl alcohol which shows a transmission of ordinary light exceeding 40% and a percentage polarization of 99.98%. Of the several claims of this patent sued upon by the defendant, the broadest seems to be claim 1 which calls for “a light polarizer consisting of a sorption complex of a dichroic stain on molecularly oriented solid polyvinyl alcohol.” Claim 2 adds the features that the polarizer be a uniaxial sheet and that the dichroic- sorption complex be a substantial absorber for light vibrating parallel to its axis and a non-absorber for light vibrating perpendicularly to its axis. Claim 5 differs only slightly from claim 1. Claims 7 and 8 are specific in calling for a dichroic stain comprising iodine and a water soluble dichroic stain respectively. Claim 9 calls for lamination to a transparent supporting sheet. Claim 18' is a process claim calling for essentially the same steps outlined in the description of the invention above. Reissue Patent No. 23,297, which is before us only on the question of validity, is directed to a new and improved light-polarizing material. In essence it teaches subjecting the product of patent 2,-737,567 to a further step in order to improve its stability against heat and moisture. This is done by treating the molecularly oriented, iodine-stained sheet of polyvinyl alcohol with a boron compound, preferably a concentrated solution of boric acid. The result of this process is to convert a minute layer adjacent to the surface of the sheet into the reaction product of polyvinyl alcohol and the reagent used in the solution, i. e. the boric compound. The properties of the product indicate that it is a cross-linked ester of polyvinyl alcohol, more specifically designated as polyvinyl orthoborate. This layer is highly unreactive to heat and other forces affecting the stability of the iodine stain within the sheet. It is resistant to water and water vapor and also appears to seal the iodine in the body of the sheet in the same way that it seals out moisture. In the earlier part of this opinion, two different types of polarizers were discussed: the suspension type and the Marks crystalline deposit type. The polarizers of the three Land patents in issue constitute yet a different type of polarizer: one in which various plastics are dyed or stained to form a complex which acts as an efficient light polarizer. However, Land was not the first broadly to teach the art the manufacture of this kind of polarizer. The prior art references cited by plaintiffs show that Ambronn and Fry, Preston, and Kasemann had taught staining or dying plastics to make polarizers prior to the date of Land’s applications. Further, many of the same materials and dyes used by Land are employed in these same references. For instance, both Preston and Ambronn & Fry disclose the use of cellophane in their articles. The Kasemann patent discloses in addition to cellophane, cellulose esters and particularly cellulose acetate. All these materials belong to the class claimed in the first Land patent, i. e. the transparent linear high polymers. The Ambronn & Fry reference teaches dying with elements the same as in Land, including the reduction of a salt of a metal to the metal itself, and mentions all of the elements mentioned by Land as suitable for use in producing dichroism. Staining with direct cotton dyes and iodine is also suggested. Land’s predecessors in the field also disclosed stretching or