1. A method of producing a digital

1. A method of producing a digital output related to the linear displacement of a reference surface of an object, comprising:
coupling a tape of hard magnetic material with magnetic coded information therein characteristic of the displacement of the reference surface of the object;
juxtaposing a magnetic means with the tape in a flux closed position therewith, so that the magnetic means assumes the coded characteristic of the magnetic coded information of the tape, said magnetic means having two states of magnetization;
pulsing said magnetic means to switch the magnetic means solely from one of the two states of magnetization; and,
reading said magnetic means and providing an output indicative of switching events taking place in the magnetic means.


2. The method as set forth in claim 1, wherein:
said juxtaposing step includes
juxtaposing a second magnetic tape having the same number of tracks as the first-mentioned tape;
said pulsing step includes applying a magnetic field pulse to each said track; and,
said reading step includes encircling said first and second magnetic tapes with a helically wound secondary winding for each said track and recording the output of each of the secondary windings to indicate switching events.


3. The method as set forth in claim 1, wherein:
said juxtaposing step includes juxtaposing a read head to each track of said tape, said read head being of non-linear magnetic material to flux close a zone on said tape containing stored information indicative of the spatial position of the reference surface;
said pulsing step includes applying a primary winding to said read head to pulse said head to change the magnetic characterization thereof, said read head being magnetized by said tape to a near saturated condition just above the knee of the B-H curve; and,
said reading step includes the step of providing a secondary winding to said read head to produce an output when said head is pulsed for demagnetization thereof.


4. The method as set forth in claim 3, wherein said tape is an eight track tape to provide a readout of a spatial resolution of 1/256 of an inch, and including the steps of:
providing a tape unit including a plurality of tracks related to the spatial resolution of the contact surface, said tape being of hard magnetic material;
coding said tracks with stored coded information to provide zones of spatial resolution related to the number of said plurality of tracks; and then,
coupling said tape of hard magnetic material with the coded information therein to the object for displacement therewith.


5. A digital displacement transducer for providing a direct digital output related to the linear displacement of a reference surface of an object, comprising:
tape means including a plurality of tracks, said tape means being coupled with said reference surface for displacement therewith, the number of said plurality of tracks being related to the spatial resolution of said reference surface, said tape means being of hard magnetic material and including stored bits of coded information characteristic of the spatial displacement along said reference surface;
means juxtaposed to said tape means capable of being magnetized in accordance with the stored bits of coded information, said juxtaposed means being formed of magnetic material softer than said tape means;
pulsing means operatively associated with said juxtaposed means to pulse said juxtaposed means to effect a change in said juxtaposed means of the coded bit stored information stored therein which are in a first state to switch solely the coded information in said juxtaposed means to a second state and to leave unswitched the coded bit stored information in said tape means; and,
read out means operatively associated with said juxtaposed means and responsive to the switching of said juxtaposed means to provide a digital read out indicative of the spatial displacement of the reference surface.


6. The transducer as set forth in claim 5, wherein:
said tape means includes a first magnetically coded eight track tape having a spatial resolution of 1/256 of an inch (.about.0.004 inches); and,
said juxtaposed means includes a second eight track tape flux closed with said first eight track tape, said second tape assuming the magnetically coded information of said first tape whereby to store the same magnetic coded information as in said first tape.


7. The transducer as set forth in claim 5, wherein:
said juxtaposed means includes a second tape means flux closed with said first tape means, said second tape means assuming the magnetic characteristics of said first tape means; and
said first and said second tape means each include eight separate tapes, to provide a spatial resolution of 1/256 of an inch.


8. The transducer as set forth in claim 5, wherein:
said pulsing means includes a recording head and a primary winding coupled with said recording head for providing a voltage pulse solely strong enough to switch the coded information in said second tape, but insufficient to switch the coded information in said first tape;
said first and said second tapes forming a composite tape unit; and,
said read out means includes a secondary winding helically wound about said composite tape unit responsive to switching events in said second tape, to provide voltage pulse outputs.


9. The transducer as set forth in claim 5, wherein:
said juxtaposed means includes a read head for each said tracks to read the zone coded information, said read head being of non-linear high permeability material, each said read head assuming the magnetization of its associated track zone, said head being magnetized to a point just above the knee of its B-H curve by said tape;
said pulsing means including a primary input winding coupled with said read head to produce an additional magnetic field in said read head;
said read out means including a secondary winding coupled with said read head responsive to said additional magnetic field to produce an output voltage when said additional magnetic field effectively causes the magnetization of said head to move below said knee and to produce no output voltage when said additional magnetic field causes the magnetization of said head to move about said knee.


10. A digital displacement transducer as set forth in claim 5, wherein said tape means includes:
a magnetically coded tape unit which includes eight separate tape tracks having a spatial zone resolution of 1/256 of an inch (.about.0.004").



Description:
BACKGROUND OF THE INVENTION
This invention relates to a method of measuring d.c. flux and a device therefor.
More particularly, the invention is concerned with a method and a digital displacement transducer apparatus for the measurement of a digital output which is related to the linearly displacement of a reference surface of an object.
A device which provides a digital output related to the displacement of a surface is a digital displacement transducer. It is desired to provide such a transducer to measure spatial displacement of approximately 0.004 inches (1/256 of an inch) of surface. One manner of providing a digital output related to spatial displacement is to provide an eight track magnetic tape or equivalent magnetic sheet and attach the tape to a reference surface of the object. The position of the reference surface could then be ascertained by reading coded information on the magnetic tape. For this purpose a stationary head would be used to read the coded information. In order to read the tape, it would be necessary to use a Hall probe or other equivalent d.c. flux measuring device; it would have to be used in the stationary head. While this technique is useful, it is quite costly. Hall probes are expensive, and they require flux condensing as small d.c. fields must be read.
In order to overcome the aforesaid problems and reduce the costs, the present invention proposes two embodiments to provide for the non-destructive read-out of the coded magnetic tape.
One embodiment is to provide a hard magnetic tape which is coded with magnetic information related to the displacement of a reference surface. A second soft magnetic tape is juxtaposed next to the hard magnetic tape and flux closed therewith. A magnetic field pulse is applied to the composite tape unit to change the magnetic stored information from a one or a positive state to a zero or negative state. The magnetic field has no effect on those already in the negative state. The magnetic field pulse is sufficiently strong to switch the information stored in the soft magnetic tape, but it is insufficient to switch the information stored in the hard magnetic tape. Therefore, the hard magnetic tape retains its coded information.
Another embodiment is to provide a single magnetic tape with coded information contained therein similar to the aforesaid hard magnetic tape. In this embodiment, the single tape also has eight tracks, although eight separate single track tapes can be used. A read head is provided for each track. Each read head includes a primary winding and a secondary winding. Use is made of the magnetic saturation characteristics of the read head to induce a large or small EMF into the secondary winding and provide a digital output.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic representation of one embodiment of the invention which uses two magnetic tapes, one overlying the other, which are adapted for attachment to a reference surface of an object. FIG. 1 also shows a magnetization means in the form of a magnetization head for one of the tapes and a readout coil. While FIG. 1 shows the magnetization means as the head, a single strand wire running perpendicular to the magnetic axis can also be used in place of the magnetization head as the magnetization means to magnetize the one of the tapes.
FIG. 2 shows a schematic representation of an eight track tape which has been magnetically coded with stored