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Publication numberUS2224646 A
Publication typeGrant
Publication dateDec 10, 1940
Filing dateApr 22, 1937
Priority dateApr 22, 1937
Publication numberUS 2224646 A, US 2224646A, US-A-2224646, US2224646 A, US2224646A
InventorsWilliam F Friedman, Vernon E Whitman
Original AssigneeWilliam F Friedman, Vernon E Whitman
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Electric control system for tabulating cards, documents, and the like
US 2224646 A
Abstract  available in
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Claims  available in
Description  (OCR text may contain errors)

Dec. 10, 1940 w. F. FRIEDMAN .ETAL. 2

ELECTRIC QONTROL SYSTEM FOR TABULATING CARDS, DOCUMENTS, AND THE LIKE Filed April 22, 19s? 2 Sheets-Sheet 1.

Dec. 10, 1940. w. F. FRIEDMAN EIIAL 2,224,645

ELECTRIC CONTROL SYSTEM FOR msum'rme CARDS nbquunms, mm THE LIKE Filed April 22,- 1937 2Sheet's-Shet 2 amen Wo f's Patented Dec. 10,1940 r i UNI/TED 1 STATES PATENT OFFICE L ELECTRIC CONTROL SYSTEM FOR .TABU

. LATING CARDS, DOCUMENTS, AND THE William F. Friedman, Washington, D. 0., and 1gerrnon E. Whitman, Bayaide, Long Island,

Application April 22, 937, Serial'No. 138,468

. whims. (c1.2o9-=-111) The present invention relates to a code sysdeal primarily with a code system which cmtem and to an electric control system cooperating ploys regularly recurring variations in light rewith such code system for a variety of purposes. flectivity and with an electric control system The present invention employs a regularly re= which is operable by such variations; it will be curring variation in a physical property of a seunderstood, however, that regularly recurring 5 ries of objects for the purpose of controlling a variations of other physical qualities or propervariety of operations that maybe sought to be ties, such asset forth above, may be employed performed upon the objects. The operation that in the present code system and may also be emmay be controlled by the present system may be ployed to cooperate with the electric control sys- 10 of a wide variety and for the purpose of illustrat tem so as to control the operations which are to 10 ing the invention, we may mention the use of the be performed upon the objects or articles. present code system and electric control system The electric system is designed to scan the for sorting a large variety of' objects. Thus, it code by means of a suitable photoelectric demay be employed for sorting cards bearing items vice or by means of some other device responsive of information, represented by the present code to variations in the particular p p p rty 15 system or for reproducing the information 943- empl y d. and a result of u scanning P- pearing on such cards or for translating such eration, alternating currents of frequencies P information. The present system may also be determined y Such Codes e enerate in the employed for sorting checks or other documents cu t of the scanning device and in the circuits upon which the sort to which each check or associated therewith. The co System f the :0 document or card belongs is represented by a Present invention Permits 0f 8- large number 01 code of the present code system. The present c e 1' markings, each peculiar to itself, and electrical system may also be employed for sorteach having the prop of uc g in the ing or for otherwise operating upon objects whi h electric system a frequency or a set offrequencies 2 are already so constructed that they possess a pec to i e electrical syste which regularly recurring physical quality in accordmay have one or more photoelectric cells or ance with the present code. 1 similar scanning devices, has a plurality of con- Among the physical properties that ma be trol circuits each of which is tuned to a predeemployed in the present code system and in the termined frequency that corresponds o p present electric control system are light refleccific code marking while the frequencies that 30 tivity, light transmissivity, electrical conduc m be induced by o er co e markings are tivity, magnetic permeability, and the dielectric filtered Out 01 attenuated. Each circuit constant. therefore, made to control the operation of a Other objects such as checks, documents, or uit le d vi e, such as a magnet or a relay, or

5 tabulating cards, or packages, or the wrappers the like. an the r. hereinafter called the therefor, which do not already possess aregularcontrol relay y be made to control the p- 1y recurring variation in any one of these properation of any typ f mechanism desired. and erties may have such variation imparted to them to perform any desired p T the by a variety of means. For example, a. relarelays associated with these circuits may be tively long and narrow zone on a surface of each mad t control t operation of a s rt n mech- 40 of such cards, documents, or the like may be imani m o th a large n mber of objects, such as printed with series of markings which will imchecks or other documents, record cards, or the part to said zone a periodic variation in the rel or p ka e may be passed over the scanflectivity to such zone. It will be appreciated ning devices, be scanned thereby, and then sortthat this variation in reflectivity can be imed into groups, classes, or sorts. 45 parted to the surface of the document in a num- When the present code system is employed for her of ways. The variation may be secured by r or n a n t bula lng cards, the same printing or engraving with ordinary or special Photoelectric yst m may be employed to coninks of any desired color, or even with the use. of trol the operation of a r n mechanism-winch inks ordinarily invisible to the human eye, Or, will sort the cards in groups or sorts correspond- 50 the color of the document may be left un-' ing to one or more items of information appearchanged, and the mattness or gloss of the suring on the card in code form. If desired, the face varied by calendering or other processes well same cards may be passed through the photoknown in the paper making industry. electric'system and the relays associated there- -The remainder of the present specification will with may control the operation of a printing 5 mechanism which serves to translate one or more items of information appearing on thesecards in coded form. The same system may also be employed, if desired, for operating a reproducing will be described in greater detail in a later portion of the present specification. The basic principle underlying the several forms of the printed code resides in provi ng upon a surface of the check, document, card, wrapper, or package, or any other article, an elongated and relatively narrow zone bearing printed marks thereon which are so distributed that alternate relatively light and relatively dark spaces are obtained, these being arranged in accordance with a predetermined frequency or frequencies for each coder When such a zone is scanned by a photoelectric device, the current induced in the photoelectric device and in; the circuits associated therewith will vary in. accordance with such markings and generate an alternating current having frequency components characteristic of such markings. With av given. code marking, therefore, the control relay or relays which are specifically responsive to the frequency or frequencies included by such marking .will be put into operative condition and the same will then set into operation the mechanism under its control, whether it be a sorting, a printing, or reproducing mechanism, or the like.

A clearer and more detailed understanding of the present invention may be had from the accompanying drawing andthe following specification, which illustrates several embodiments of the present invention but does not serve to limit the scope of the invention. I

In the drawing- Fig. 1 illustrates several code systems;

Fig. 2 is a schematic showing of the control system;

Fig. 3 shows Fig. 4 shows another form of the electric sysone form of the electric system;

' tem.

Fig. 5 constitutes a diagrammatic illustration of a sorting apparatus that may be employed herein and operated by the present electrical system.

The several types of code markings illustrating the praent code system are shown in Fig. 1 of the drawing. One form of code marking comprises a 'series of spaced printed bars or stripes, applied preferably near one edge of the'document or card or the like It, as shown in Fig. 1a. The unprinted or light spaces I! will reflect incident light, whereas thedark or printed stripes or bars II will absorb incident light. In the code shown in Fig. 1a the light spaces l2 are all of the same width and the printed bars it are all of the same width. The basic or fundamental periodicity of this marking is determined by the sum of these two dimensions and by the rate of scanning; i. e., the velocity with which the documentv is caused to pass the photocell. The sum ofthe I two dimensions just referred to is equal tothe distance between the centers of adjacent black, or white bars. are obtained by varying the fundamental frequency by varying the sum of these two dimensions, and this may be done either by varyingthe width of the printed bar while maintaining the width of the light space I 2 constant or vice versa Other codes in the same system 2,224,04 7 v e V .or by varying. both the width of the light space I! and of the printed bar It. While for many purposa the code system as just described will yield a sumcient numberof frequencies, substantially the same system may be employed to yield a still greater number of frequencies by providing an additional variation in which the sum of the width of adjacent light anddark spaces l2 and i4 is maintained constant but in which the ratio of the width of the light space with relation to the dark space is varied. Such markings or codes will all yield the same fundamental frequency but the harmonic content of one suchv code differs from the harmonic content of another such code by reason of the fact that the amplitudes of harmonic frequencies depend upon this ratio. Moreover, with a given ratio one or more of the harmonic frequencies drop out, while with another ratio, another harmonic frequency or another group of harmonic frequencies drop out. These zero amplitude harmonics may be employed to cooperate with a fundamental frequency for the control of a desired operation. The code system shown in Fig. 1a may, therefore, for some purposes rely for differentiation merely upon the fundamental frequency, and for this purpose will merely employs; system of codes in which the sum of thewidtlr'of adjacent light and dark spaces vary from one code to the next;

and for other purposes where a larger number of frequencies is desired for the purpose of controlling a greater variation in the operation of sorting, printing, or reproducing mechanisms, both the fundamental and selected harmonic frequencies are utilized, and in such casesthe codes differ from each other either in the sum of the widths of the adjacent light and dark spaces or in the ratio of 'the adjacent light and dark spaces or in the ratio or the adjacent light and dark spaces, or in both respects.

As an illustration of the above mentioned dependence of harmonic content upon the ratio of light to dark area widths, the following examples are stated without proof. (The proof involves a branch of higher mathematics known as "Fourier analysis and is omitted in the interest of simplification.) If the width of the dark band equals that of the light one, all even harmonics have zero amplitude. This means that if the document having such markings was passed over a photocell (covered by a table with a slit to in Fig. 2 narrow with respect to the dimensions of the markings) at the rate of 100 black bars per second, that a voltage .would be generated in the outputof the photocell having 100, 300, 500, and 700 cycle components. The frequencies of 200,

400, and 600 cycles would have practically no voltage. Furthermore, if the sensitivity of the system was such that the amplitude of the 100 cycle component was 4 volts, then the 300 cycle amplitude would be approximately 1.3 volts, and the 500 cycle component 0.8 volt. If, on the other hand, the dark bar had been 50% wider than the light one, the voltages at the various frequencies would have been as follows: 4.0 volts of 100 cycles; 1.2 volts of 200 cycles; 0.8 volt of 300 cycles, 1.0 volt of 400 cycles, and 0.8 volt of 500 cycles. The distinctions between the two examples are obvious: it is the purpose of the electrical elements in the system to allow such distinctions to cause different operations to be performed on the corresponding documents. It is obvious from the above analysis that ,code markings may be resolved into their spectra and that these spectra contain characteristic elements in addition to the fundamental frequency .termined by the distance between the peaks of a pair of adjacent dark spaces or light spaces which distance is varied from code to code.

Fig. 1c shows another check or card or other document or package employing variable density type of marking. Inthis case the frequency is determined by the distance between the points 24 and 26 which are adjacent lines of maximum density, the printing upon the space between these p n s be ming less and less dense until the point 28, half way between 24 and 26, is reached, where there may not be any marking at all, and constitutes the point of maximum reflectivity.

While, as shown here, these markings are disposed at or near the edge of the document, it will be understood that such markings may be disposed along any suitable line, provided that in each case, the code zone contains a sufiicient number of cycles. The number of cycles required depends upon the refinements of the systerm. In general, it may be said that for practical operation a minimum of ten cycles is de- 'sirable.

Fig. 1d shows a check, card, or similar article 30 bearing two code zones 32 and 34. Each of these zones may be of any of the types shown in Fig. la, Fig. lb, or 'Fig. 10. These two zones differ from each other, however, in the fundamental frequency, and they cooperate with each other and with the photoelectric system in order to determine the nature of the operation of the controlled sorting, tabulating, printing, or reproducing mechanism.

In the case of tabulating cards, each of which carries several items of information, each item of information will be represented thereon by a columnar zone bearing the imprinted code marking thereon, and these zones may be adjacent to each other.

Fig. 1e shows a portion of a tabulating card ll having the columnar zones l3, some of which bear the markings l5 representing in coded form the desired items of information.

When multiple code zones exist, as shown in Figs. 1d and 1e, the information contained therein can be secured from all zones simultaneously by simultaneous scanning with the required number of scanning systems; or, a single scanning system maybe employed, and the different zones scanned successively.

While in the preferred form of the invention as thus far described. the code zone is designed to reflect incident light from a constant source of light onto a photoelectric cell or similar sensitive device, it will be understood that the same invention may be employed in connection with transparent or translucent articles, and the present code will vary the amount of light transmitted therethrough.

The electric system and its manner of cooperation with the documents bearing the codes are schematically illustrated in Fig. 2. The document or other coded article 36 is passed over the scanning platform 38 which is provided with a slot 40. Light from the source." is directed upon the slot and is reflected from the document passing thereover onto the scanning device, diagrammatically represented by the photoelectric cell 44. The cell is electrically connected in any suitable manner to a plurality of control circuits, each comprising an amplifier 48, a frequency selector or filter 48, and a control relay 50. The

actuation or energization of the control relay 50' then serves to control the operation of any desired mechanism as set forth herelnabove. The frequency selectors or filter circuits 48 in each control circuitis adjusted to a! preselected frequency, differing from the frequency of the remaining selectors or filters in the system.

It will now be understood that with a prederelay or combination of control relays will be energized and the desired operation determined by the code markings on the document will be performed. ,As a specific example of the action of such a'system, let us consider the electrical differentiation between checks which have been so marked that they are to be sorted into groups EA, EB, DA, and DB. In accordance with any practical embodiment of this invention, all checks will be assumed to be scanned at a constant'rate, irrespective of the markings they may have. In our specific example it-will be assumed that checks EA and EB have been marked with coding bars whose distances between centers ls equal in the two cases, giving rise therefore to equal fundamental frequencies when scanned, and that these spacings are such that this fundamental frequency will be 100 cycles lneach case. 100 cycles mayftherefore, be said to be characteristic of all checks which are to be filed or sorted under the letter E. All checks for sorting under D, however, will be given a code marking which will have av fundamental of 110 cycles, whether the checks are intended for sub-sort A or sub-sort B. The differentia- .tion between the sub-sorts A and B either in case E or in .case D will be made on the basis of the I harmonic content of the markings. Let it be further assumed that allchecks intended for sub-sort A- are marked with bars in which the width of the dark bar is always equal to that of the light one. In accordance with the analysis of this case given in a paragraph above, the amplitude of all even harmonics will be zero. Checks intended forsub-sort B may be given markings in which the dark bar is 50% wider will be referred to as the master relays of sort E and D respectively. Any check which passes the scanning mechanism so as to generate a voltage or current with a 100 cycle component,will energize the E master relay and be directed toward primary sort E, irrespective of the higher sequently be passed on to sub-sort A harmonic contents. Whether the check willsub- B will be determined by the harmonic conten of the voltage generated in the scanning circuit as-will be illustrated below. Two of the four necessary relays have been mentioned; the others are tuned to 200 and 220 cycles and are associated with the 100 and 110 cycle master relays, respectively.

These additional relays will be recognized as be-- ing tuned to the second harmonics of master relays E and D. Let us assume now that check EA passes the scann lng mechanism; master re- .lay E is energized because of the 100 cycle voltage present; there is, however, no 200 cycle component available to actuate the relay tuned to this harmonic; the check will, therefore, pass on to a place corresponding to that combination. If, on the other hand, check EB had passed, a voltage of 200 cycles would have been present in addition to the 100 cycle one. and the check will pass on to a place corresponding to the combined action of master relay E and sub-relay B. -A similar analysis will show how the relay energizing is unique for each of the check markings considered. Mechanisms by which these different relay actions-may bemade to actuate corresponding sorting operations are well known in the art and constitute no part of the present invention. Suffice it to say that the essentials for distinguishing between checks EA, EB, DA, and DB have been derived above, and they may, therefore, be sorted into classifications EA, EB, DA, or DB, as the case may be.

The length of the slot 40 should preferably be equal to the width of the markings. The slot should, however, be as narrow as is consistent with sufficient light reaching the photocell.

Fig: 3 shows the detail of one electric system that may be employed herein, it being understood, however, that such circuits may be varied as desired so long as it embodies a photoelectric device and a suitable number of control circuits, each containing amplifying means, frequency selecting means, and a control relay, as shown in Fig. 2. a In Fig. 3, the variable current induced tubes from the battery 46. Each of these circuits comprises suitable amplifying devices and suitable filteiing or frequency selecting devices, and a control relay. If desired, any type of rectifying device may be interposed between the control relay and the remainder of the circuit.

More particularly, the circuit shown at the top of Fig. 3 which is illustrative of the remaining circuits, comprises multi-electrode tubes 50 and- 54 and interposed between them are the tuned coupling circuits C L C L, C, tuned.

to a predetermined frequency corresponding to the fundamental frequency of a selected code. The rectifier is illustrated by the two electrode tube 56, it being understood that this is merely illustrative of any suitable rectifier, it being further understood that A. C. relays may be employed .and the rectifier may then be omitted. The control relay is indicated at J which is actuated in response to the frequency determined by its circuit and by making or breaking contact 58, it serves to control the nature of the oper- Darticular relay ation of the printing, sorting, or reproducing mechanism with which the system is employed. An additional tuned circuit C, L 0 L, C is also interposed between tube 54 and the rectifier It. The cathodes K of all'tubes are shown as grounded and suitable operating points on the tube characteristics batteries B", B", etc, The tubes together with the coupling system act as amplifiers. The coupling condensers 0 0"", should be chosen so that the tuned circuits will be coupled slightly less than transfer of energy (amplification) with'the maximum sharpness at the tuned circuits. With the coupling system shown in Fig. 3, no inductive coupling is intended between the coils. It will be understood. however, that any other suitable type of tuned coupling may be employed.

What has Just been said regarding the control circuit beginning with tube 50 which is tuned to a frequency fl is equally applicable to the remaining control circuits which are indicated by tubes 50, 50', etc., except that the circuits following tube 50 are tuned to 12, etc. Relays J J, etc., constitute the control relays, each responsive to a preselected frequency.

To further illustrate the action of the device considered so far, let us assume that the relays J are normally open. This is the condition when the voltage drop across R R, etc., is zero, which condition will automatically be met when the light entering it is not varying, as when no bars are passing slot 40 in Fig. 1. Suppose, now, that a check or other document I 0 is caused to pass the slot at such arate that the light is varied from maximum to minimum back to maximum (one complete cycle) fl times per second. This will cause a voltage of frequency II to be impressed on the grids of tubes 50, W 50, etc. This voltage will be further amplified as it passes through the tuned circuits and tubes tuned to its frequency, and a rectified voltage appearing across R will cause J to close its contact 58, thus starting the chain of mechanical events which will cause the check or other document to be deposited ln the selected receptacle or to'have other operations performed.

The voltage of frequency fl appearing on the grids of tubes 50 Ill, etc., will be attenuated so as to be substantially zero upon reaching R, etc., and, therefore, relays J, etc., will remain open.

Fig. 3 also illustrates the manner in which a similar electric control system operates when codes differing from each other in their harmonic content are employed. In this case the first control circuit of the control relay J is tuned to the fundamental frequency, while the remaining control circuits are each tuned to a selected harmonic frequency. The relay J is a master relay and the other relays are auxiliary relays. The operation sought to be performed is then controlled by thecooperation of a master relay and one or more auxiliary relays. If desired the auxiliary relays may be such that they function only when deenergized. The number of control .circuits as shown in Fig. 3 may be multiplied are insured by the grid bias sources 66 and 68, the two code zones being individually scanned by the photocells I and 12. The electrical system associated with each cell is .the same as that shown in Figs. 2 and 3. Each article, document, or the like, now energizes a selected control relay J in one system and a selected control relay M in the second system. These two relays may now control th operation of the sorting, printing, or the like in a manner peculiar to their combination.

The two code zones shown in document 14 in Fig. 4 may be disposed successively if desired so that the relays operated thereby come into successive operation, and thus when this is employed for sorting into a large number of sorts the first relay may direct th travel of the document into a predetermined direction common to a group of sorts, and the second relay will direct the document or card into the selected sort.

Fig. 5 is a diagrammatic showing of a sorting mechanism such as that shown in patent numbered 2,020,925 and which may be employed herein in cooperation with the present electrical system. The platform 38 is shown extended and is provided'with pivotal gates Ill secured to the heads of rotating pins I42. The lower end of each pin I42 may be rotated by links Ill which in turn are operated by electro-magnets. Thus .when the .corresponding electro-magnet is ener-' gized the corresponding 1 gate is deflected as shown at 9 thereby deflecting and directin the card or article 30 into the channel defined by the guides I41. posed between and below the guides I", the compartments having trap doors which are also operated by electro-magnets under the control of the control relays. I

Having thus described\ our invention, we claim:

1. Apparatus classes, comprising a support for moving documents, photo-electric scanning devices operating in response to imprinted code markings on said documents to generate persistent electrical impulses having frequency characteristics corresponding to said markings; the documents belonging to one class bearing code markings which "cooperate with said scanning devices to give rise to persistent electrical impulses having one frequency characteristic distinguishing said class from some classes and another frequency characteristic distinguishing said class from the remaining classes; a pluralityof tuned circuits connected to said scanning devices, each circuit being tuned to a different frequency characteristic,

55 and means operable by such circuits to direct Compartments 'I II are dis-- for sorting documents intooperation.

2. Apparatus for sorting documents into classes, comprising a support for moving documents, photo-electric scanning devices operating in response to imprinted code markings on said documents to generate persistent electrical impulses having frequency characteristics corresponding to said markings; the documents belonging to one class bearing code markings which cooperate with said scanning devices to give rise to persistent electrical impulses having one frequency characteristic distinguishing. said class from some classes and another frequency characteristic distinguishing said class from the remaining classes; a plurality of tuned circuits, each circuit being tuned to a different frequency characteristic and means selectively operable by a selective pair of such circuits to direct the documents belonging to each class in a path distinctive to each class.

3. Apparatus of the class described comprising scanning mechanism responsive to recurrent impulses having variable frequency characteristics, means for passing before said scanning means tabulating cards or the like having code markings thereon and causing said scanning mechanism to generate persistent electrical impulses having various frequency spectra; the tabulating cards belonging to one class bearing code markings which give rise to a spectrum characteristic of said class and different from the spectra produced by the code markings borne by the tabulating cards belonging to other classes; and

means responsive to the Joint operation of a plurality of spectrum components of a selected spectrum for performing a selected machine operation.

4. Apparatus ofthe class described comprising a support for moving tabulating cards or the like, photo-electric scanning devices operating in response to imprinted code markings. on said cards to generate persistent electrical impulses having frequency characteristics corresponding to said markings, the cards belonging to onevnauon E.'WHI'IMAN.

Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US2427383 *Jul 29, 1941Sep 16, 1947IbmStatistical machine controlled by magnetic, frequency coded records
US2552156 *Mar 17, 1947May 8, 1951De France HenriNumbers reading device
US2612994 *Oct 20, 1949Oct 7, 1952Norman J WoodlandClassifying apparatus and method
US2618386 *Jan 10, 1950Nov 18, 1952IbmRecord card sorting device
US2704634 *Jul 2, 1949Mar 22, 1955 Rauch
US2712898 *Jul 16, 1951Jul 12, 1955Bull Sa MachinesArrangement for analysis and comparison of recordings
US2731621 *Apr 1, 1952Jan 17, 1956C G S Lab IncCounterfeit detector
US2754496 *Apr 23, 1951Jul 10, 1956James S DuffIdentification coder and decoder
US2774821 *May 6, 1952Dec 18, 1956Bell Telephone Labor IncCard translator
US2870429 *Mar 27, 1951Jan 20, 1959Gen Precision Lab IncAutomatic program control system
US2872590 *Nov 12, 1954Feb 3, 1959Wilkata Codes IncPhotoelectric scanning device
US2880328 *Nov 23, 1954Mar 31, 1959American Can CoApparatus for detecting containers having mismatched parts
US2896763 *Jul 23, 1954Jul 28, 1959Lehigh IncVending machine
US2923921 *Jun 23, 1954Feb 2, 1960 Shapin
US2925586 *Jun 9, 1953Feb 16, 1960Moise Levy MauriceMethod of, and apparatus for, electronically interpreting a pattern code
US2932392 *Feb 23, 1954Apr 12, 1960Alan FosterApparatus for determining the denomination and/or genuineness of paper money and thelike
US2936112 *Apr 16, 1954May 10, 1960IbmRecord sensing mechanism
US2936886 *Oct 5, 1954May 17, 1960Reed Res IncStamp sensing letter sorter
US2941717 *Dec 31, 1952Jun 21, 1960Self Winding Clock Company IncAutomatic classifying system
US2982952 *Jun 28, 1955May 2, 1961Zenith Radio CorpSubscription television
US2997417 *Mar 30, 1955Aug 22, 1961Gerhard DirksMethod of preparing record carrier
US3003631 *Oct 8, 1956Oct 10, 1961Bernard L StockMeans for detecting the presence of contents in envelopes
US3035380 *May 24, 1957May 22, 1962William B LeavensMethod for inspecting cartons
US3037695 *Apr 29, 1958Jun 5, 1962IbmRecord bearing instrumentalities
US3038607 *Jun 20, 1958Jun 12, 1962Pitney Bowes IncArticle marking and orienting
US3152256 *Nov 21, 1958Oct 6, 1964Gen Atronics CorpPhotosensitive code identifying means and method
US3276253 *Nov 20, 1963Oct 4, 1966Eastman Kodak CoFilm aperture tester
US3282210 *Apr 10, 1963Nov 1, 1966Weig Morris OCertified check coded for rejection in sorting machine
US3325632 *Jul 12, 1961Jun 13, 1967Sylvania Electric ProdData storage techniques
US3359405 *Nov 3, 1964Dec 19, 1967Svenska Dataregister AbData record and sensing means therefor
US3402299 *Jun 18, 1965Sep 17, 1968Telefunken PatentMethod and apparatus for scanning
US3458688 *Aug 9, 1965Jul 29, 1969IbmDocument line position identification for line marking and document indexing apparatus
US3573436 *Oct 8, 1968Apr 6, 1971Pitney Bowes AlpexMethod and apparatus for reading tickets, and ticket for use therewith
US3798458 *Oct 30, 1972Mar 19, 1974IbmOptical scanner including an aperture design for non-synchronous detection of bar codes
US4510383 *Aug 31, 1982Apr 9, 1985Boehringer Mannheim GmbhDevice for the optical identification of a coding on a diagnostic test strip
US4752675 *Dec 23, 1985Jun 21, 1988Zetmeir Karl DMethod of collecting response data from direct mail advertising
US4786891 *Apr 8, 1986Nov 22, 1988Yokogawa Electric CorporationAbsolute encoder for linear or angular position measurements
US5110134 *Mar 1, 1991May 5, 1992No Peek 21Card mark sensor and methods for blackjack
US5219172 *Oct 9, 1991Jun 15, 1993No Peek 21Playing card marks and card mark sensor for blackjack
US5224712 *Apr 10, 1992Jul 6, 1993No Peek 21Card mark sensor and methods for blackjack
US5266784 *Feb 16, 1990Nov 30, 1993Intermark CorporationPromotional scanning and validating device
US5364106 *Nov 4, 1992Nov 15, 1994No Peek 21Card mark sensor and methods for blackjack
US5827165 *Oct 10, 1996Oct 27, 1998Windmoller & HolscherDevice for pulling open continuously cross-conveyed tube sections for the purpose of forming bottoms in the manufacture of sacks
US6517472 *Oct 4, 1999Feb 11, 2003Starlinger & Co. Gesellschaft M.B.H.Device for separating material webs lying on top of each other
DE976426C *Dec 7, 1951Sep 5, 1963Siemens AgVerfahren zum entzerrenden UEbertragen von aus Schritten einheitlicher zeitlicher Laenge zusammengesetzten telegrafischen Impulsreihen, z. B. Fernschreibzeichen
DE977005C *Dec 7, 1951Oct 29, 1964Siemens AgVerfahren zum entzerrenden UEbertragen von aus Schritten einheitlicher zeitlicher Laenge zusammengesetzten telegrafischen Impulsreihen, z. B. Fernschreibzeichen
DE1151965B *Jul 8, 1953Jul 25, 1963Ulrich Knick Dipl IngBuchhaltungsmaschine
Classifications
U.S. Classification209/583, 209/657, 235/462.25, 340/5.1, 235/494, 235/454, 250/555, 234/75, 235/492
Cooperative ClassificationB07C5/3412