DE4240677A1 - Drop=out detection device for magnetic recording tape - uses recording and playback heads for narrow band signal at fixed relative spacing - Google Patents

Abstract

The detection device uses one or more recording heads (8) for recording a narrow band signal longitudinally along at least one recording track and one or more corresponding playback heads (11) at a constant distance from the recording heads, the detected drop-outs being recorded by a counter. Pref. the track width of the recorded signal corresponds to that of the tested video system the tape transport velocity corresponding to the relative velocity between the video head and the recording tape in the video system, the frequency of the recorded signal lying in the same range as the luminance signal frequency-modulated carrier. USE - Detecting drop-out errors for video tape testing.

Description

The invention relates to a method for testing a Ma gnetbands on dropouts and one to carry out the Ver suitable device according to the preamble of An saying 1.

When magnetically recording data and images errors can occur due to dropouts. You generate at for example with a video recording horizontally over the Streaks on screen. Therefore, magnetic tapes are un indirectly after manufacturing for freedom from defects checked. The cause of such defects can be in a un adequate casting quality of the magnetic tapes (permanent defect) or in the deposition of foreign bodies such as dust or fibers (Dummy flaw) on the belt surface. Around Finding and quantifying errors are ent talking measuring devices such as dropout counters, which enable the manufacturer to take preventive measures or to eliminate these errors.

In particular, the magnetic tape for digital recordings in connection with computer systems or similar, tests and educated to the presence or absence of sol to monitor defects and to be able to guarantee that every magnetic tape reel delivered completely from defects is free or at least a minimum number of possible errors places. It is also important that the result the dropout exam is available as soon as possible, because with not, for example, on the finished product, that has gone through several remaining production stages, one possible  negative result for the quality of the product is determined.

Such devices for dropout measurement are examples as in the documents DE-OS 19 14 512, 19 27 543, 24 13 318, DD 1 35 338, SU 434 477 and JP-N 58-033 154. In DE-OS 29 22 009 a device is described with whose help permanent defects from false defects under can be separated.

Further measuring devices are described in US 4,894 733, in which the magnetic tape is loaded into a cassette is checked for errors, so that only faultless tapes in get the cassette, further in EP 0 358 236, after their teaching reveals surface defects that appear periodically a running band in a longitudinal measurement become. US Pat. No. 4,631,479 discloses errors on a Magnetic tape, which runs through at high speed detect and localize.

In recent years, routine testing of Magnetic tapes on dropouts mainly two devices used, which are characterized in more detail below. The one device consists of a commercially available video recorder, like he did for the various video systems of numerous Manufacturers is offered as well as a dropout counter, such as for example in IEEE Transactions on Consumer Electronics, Vol. CE-26, August 1980, pages 334-337. The color familiar from television is turned into a video recorder bar signal including the gray conductor in the usual for video Oblique recording on the magnetic tape to be tested, which is in a commercially available video cassette while transferred for a specified playing time. After that it will Tape rewound and the frequency mod during playback  gated carrier signal connected to a dropout counter. This can, as in the latter literature reference described in detail, signal drops ("dropouts") from a be agreed to count penetration depth and duration. Usually dropouts are counted that are at least 20 dB deep as well as periods longer than 5 or 10 relationship wise 15 µs and averaged over an interval specified by 1 minute.

Signals with a low penetration depth and shorter duration are therefore not annoying, as a VCR usually, like for example in the manual of film and video technology, Franzis-Verlag, 1983, pages 467-468, for small defects in the magnetic tape a so-called drop out-compensator and there are signal dips that are shorter than 5 µs are such a small part of a television line assume that they are hardly noticed by the viewer.

As can be seen, the arrangement described is enormous costly and time-consuming, because the video tape to be checked only must be spooled into a cassette, and there also Auf Representation and playback represent two separate operations. Furthermore, the process suffers from the basic deficiency tet that when amplifying the relatively broadband Sig nals, which is approximately between 3.2 and 4.8 for half-inch video MHz, the signal-to-noise ratio is relatively low because the noise level is proportional to the square root the bandwidth increases. This can have an impact that some of the dropouts that last longer than 15 µs do not be counted.

The video tape evaluator of the American company Recortec. This device is set to a Magnetic tape of any length and standard width  by means of nine recordings distributed across the width of the tape heads, each with a width of 1 mm, in longitu dinal recording a fixed frequency of approx. 200 kHz with a tape speed of approx. 300 cm / s. in the the same operation is the how with nine playback heads signal and the dropouts are counted. This arrangement provides no rele for video conditions vanten measurement results, since both the track width (1 mm against 22.6-49 µm for half-inch video) as well as the recording frequency (200 kHz against 4.5 MHz) not the video practice ent speak. It also has nine fairly wide heads the band-head contact is significantly different from that in han commercially available video recorders. For these reasons, using the device does not have equivalent burglary depths or time periods be determined by dropouts. After all, that also corresponds Belt speed not the relative speed between Video head and video tape in a commercially available video recorder.

The object of the present invention was a Method for testing a magnetic tape, especially one Videotape to create on dropouts which described the avoids disadvantages and a quick, if possible comprehensive send, reliable and affordable dropout measurement to Ma gnet ribbons of any length.

According to the invention, the object was achieved with a method using one or more fixed recording heads a narrowband signal longitudinally to one or more Traces of the moving video tape recorded and in the same Operation by means of one or more fixed re heads that are at a constant distance from the recording heads, dropouts above a certain burglary depth and duration are counted, characterized in that the Track width of the recorded signals that of a commercially available  Lichen video system corresponds to the speed of the Video tape approximately equal to the relative speed between the video head and tape in the relevant video system is, and that the frequency of the recorded narrowband Signals in the range of mod. With the luminance signal gelled carrier preferably in the upper part of the frequency swing of the video system in question.

Further details of the invention emerge from the subclaims Chen, the description and the drawings.

The method according to the invention enables immediately after the casting of the magnetic tape to be tested on the carrier and the subsequent cutting to the desired width (at for example, half-inch, three-quarter inch, etc.) from a roll any length, a so-called pancake, on any Make the magnetic tape a quick reliable measurement to get the dropouts before more expensive ferti levels have been achieved.

The invention will now be explained in more detail with reference to the drawings and that shows

Fig. 1 is a side view of the overall system for the dropout measurement,

Fig. 2 is a side view of a subsystem, namely the two head drums and the deflection roller,

Fig. 3 is a plan of the same subsystem,

Means Fig. 4 and 5 are side view of two working conditions of a test which is interposed between the cutting device and winding.

Fig. 1 shows the principle of a device for dropout measurement. From an unwinding roll ( 1 ), the video tape ( 12 ) to be tested is first passed in a manner known per se through a cleaning section ( 2 ) that removes dust or fibers from the tape, then the tape passes through a vacuum chamber ( 3 ), which acts as a calming section for an even passage of the tape through the recording and playback head arrangement according to the invention ( 4 ), which is shown in detail in FIGS . 2 and 3, and which determines the tape tension. Finally, the tape is wound on the take-up roll ( 6 ). In a preferred embodiment, it runs beforehand over a winding arm ( 5 ), which enables it to be wound up as a flange-less winding, which enables the pancakes to be stacked and transported particularly inexpensively.

In the inventive head assembly according to Fig. 2 and 3, the video tape first passes over the stationary Kopftrom mel (7) on which a plurality or, where applicable sitting in height and at a distance adjustable recording heads (8). After passing the deflection roller ( 9 ), the tape runs over the fixed head drum ( 10 ) on which a number of playback heads ( 11 ) corresponding to the recording heads ( 8 ) are seated, which are also adjustable. The essence of the present invention is now that the track width of the video heads and the write speed correspond to the conditions in the video system to be tested and that the signal recorded and reproduced for dropout measurement fixed frequency approximately in the middle, preferably in the upper part of the frequency stroke of the carrier of the relevant video system frequency-modulated with the luminance signal, as will be explained in more detail below using an example. In this way, as far as the track width, the relative speed tape / head and the concern of the video heads on the tape, the conditions of the video recorder are simulated very well without the after parts of the test for dropouts in the video recorder having to be accepted. namely assembly of the tape in a video cassette and time-consuming measurement. As far as the last criterion is concerned, with the method according to the invention, with two recording and playback heads each, four times the test capacity per unit of time is gained compared to testing in a video recorder: twice the information through two tracks, while in commercial video recorders with two heads only one track is recorded or played back, and then twice the capacity, because recording and playback take place in one operation, while in the video recorder the magnetic tape is rewound after the recording and only then the information is played back. With an arrangement with more than two video heads, the capacity gain is of course even greater. In addition, the method according to the invention can be implemented inexpensively, since it can work with head drums used in commercial video recorders and the video heads that are sensitive to them, which are cheap to buy as mass articles.

Since the head drums are permanently installed, this is largely unnecessary mechanical wear of the drum as a result of turning the The signals are not transmitted to and from the video head inductively via rotary transformers, but galvanically and after all, if a video head is worn out, it only needs one Lich the head drum to be rotated 180 ° to the second Put the video head into operation after adjustment. The video tape Evaluator, on the other hand, contains a special one, as described Arrangement of recording and playback heads, as a single manufacturing are much more expensive.  

The use of a fixed frequency signal when recording voltage and playback finally has the advantage that narrow bandy amplifiers can be used that, like everyone Experts know that they are lower in noise than broadband amplifiers, so that the signal-to-noise ratio becomes more favorable, which means that as mentioned at the beginning, also longer-lasting signals (<1 5 µs) be counted reliably. The Fre frequency of the recording signal selected so that it approximately in the middle, preferably in the upper part of the frequency sweep of the carrier frequency-modulated with the luminance signal in video system in question.

The table below is for some of those in question upcoming applications the embodiment of the fiction procedure for checking for dropouts in half-inch, Three-quarter inch and one inch magnetic tapes listed what Track width, writing speed, which because of the fixed standing heads is equal to the belt speed as well Signal frequency in the video system concerned.

This is the application of the inventive method for all systems offered on the market possible.  

table

Embodiments of the method according to the invention in commercially available video systems

The method described above is suitable, inter alia, with a slightly modified structure not only off-line, that is to say after the production of a magnetic tape reel, a so-called pancake, but also on-line, directly after a conventional longitudinal cutting device in which the recording medium is inserted into the required width of use is separated to be used. Corresponding devices are shown schematically in FIGS. 4 and 5. The following difficulties have to be overcome:

• a) the separation speed is not constant
• b) the separated narrow strips lead irregular lateral movements through
• c) the tape tension is higher than in simulated recorder operation and can fluctuate like the separation speed under to be thrown.

To a) and b)

If v _{L is} the separation speed, dv its change in the time interval dt and a the length of the magnetic tape running between the recording head ( 16 ) and the reading head ( 17 ), then the speed change occurring between ( 16 ) and ( 17 ) leads

to a relative frequency change at ( 17 ) from

The frequency change is undesirable because of the sense amplifier narrow band should be performed to a high high distance to reach.

When the running belt ( 12 ) moves laterally at the speed vs, the track offset is between ( 16 ) and ( 17 )

It was assumed that v _L and vs can be regarded as constant over time a / v _L.

The track offset leads to a loss of signal voltage, which interferes with dropout detection and eventually completely prevents.

Both effects are proportional to the distance a, which is therefore kept as small as possible due to the compact design. Preferably a is less than 10 cm. Furthermore, the effect decreases with increasing separation speed v _L.

For the relative speed tape / head already lay the Use of inductive read heads and the limitation of Recording wavelength

set a lower limit vo to a reasonable maximum value; it is under when the separating machine starts up or runs down steps, the measurement is to be suspended. The least too casual speed is of the order of magnitude vo = 1.5 m / sec.  

As already stated, dropout rates are usually measured in video recorders under operating conditions. The measurement interval is usually 1 minute. Drop outs are evaluated if the signal failure time exceeds 5 µs or 15 µs. These times correspond to the following tape lengths in the VHS system 625/50 Standard Play (SP), i.e. with a writing speed v _H = 4.85 m / s

5 µs dropout length L ₅ = 5 µs · 4.85 m / s = 24.25 µm
15 µs dropout length L ₁₅ = 15 µs4.85 m / s = 72.75 4µm.

The track length of the 1-minute interval is L _min

60 s4.85 m / s = 291 m.

The tape transport speed v _L = v _{H was} selected for the test devices in their first-mentioned embodiment, so that - apart from the track width - recorder conditions exist. On the other hand, if the tape speed v _L deviates from the recorder writing speed v _H , the geometrical remains Comparability of both measurement methods is obtained if the interval duration and dropout duration are multiplied by the factor v _H / v _L. The same track lengths and the same signal dropout lengths are then assessed in both cases.

In the dropout counter according to the invention, measurement intervals and dropout windows are derived from the same control crystal. With v _L = v _H , the geometric comparability can then be achieved by changing the quartz frequency from f _Q to f _Q · v _L / v _H.

This is shown schematically in the following block diagram see:  

Starting from a clock frequency of 200 kHz (which in turn is usually obtained from a quartz frequency in the MHz range by division), fixed interval dividers 1/3 and 1 / (4 · 10 ⁶ ) make the interval durations 5 µs and 15 µs for the dropout window and 1 min for the measurement interval. These are the measurement conditions of the recorder measurement with the writing speed v _H.

The same conditions apply to a longitudinal recording with the belt speed v _L = v _H. A signal downtime of T ₅ = 5 µs corresponds to a track interruption of the length

L ₅ = T ₅ · v _L = 1 / f _Q · v _L

and become accordingly

L ₁₅ T = ₁₅ · v _L = 3 / f _Q · v _L
L _1min = T _1min · v _L = 12 x 10 ⁶ / f _Q · v _L.

At f _Q = 200 kHz, the tape lengths calculated for recorder ratios result for v _L = v _H = 4.85 m / s.

Dropouts are then evaluated when the signal voltage over the distance L ₅ or L ₁₅ falls below the predetermined minimum value. The dropout rates are the number of such dips on a band section of length L _1min .

It makes sense to maintain this geometric assignment based on recorder ratios even if v _L ≠ v _H for a longitudinal recording.

If v _L ≠ v _H = constant, it is sufficient to replace the clock frequency f _Q by the fixed frequency f _Q * = f _Q · v _L / v _H. For v _L <v _H signal dips and measuring intervals now take longer:

T ₅ = 1 / f _Q * = 1 / f _Q * v _H / v _L
T ₁₅ = 3 / f _Q * = 3 / f _Q * v _H / v _L
T _1min = 12 · 10 ⁶ / f _Q * = 12 · 10 ⁶ / f _Q · v _H / v _L.

The associated tape lengths are retained:

L ₅ = 1 / f _Q * v _L = 1 / f _Q v _H / v _L v _L = 1 / f _Q v _H
L ₁₅ = 3 / f _Q * v _L = 3 / f _Q v _H / v _L v _L = 3 / f _Q v _H
L _1min = 12 · 10 ⁶ / f _Q * v _L = 12 · 10 ⁶ / f _Q v _H / v _L v _L = 12 · 10 ⁶ / f _Q v _H.

This is also the case if the signal dips and measuring intervals last less for v _L <v _H than for recorder conditions.

The procedure is similar for a test device which is coupled online to the cutting device and for which v _L ≠ const. is if the clock frequency f _Q * is derived via a (not shown) tachometer driven by the transport rollers of the cutting machine. Its frequency is necessarily proportional to v _L and thus also proportional to f _Q · v _L / v _H , since f _Q = 200 kHz and v _H = 4.85 m / s are constant.

To c) belt tension

While the magnetic tape with a Belt tension of approx. 50 cN runs, cutting devices work usually with belt tension between 100 and 150 cN. At same geometric relationships of the ribbon-head system higher head grinding values are therefore obtained. Vice versa The high belt tension enables the wrapping to be reduced supply. The head grinding values will then be smaller.

As a comparison of FIGS. 4 and 5 shows, the wrap is reduced with a high band tension in that one of the two halves ( 19 , 20 ) of the testing device ( 14 , 14 ') is changed so that the two heads ( 16 , 17 ) only touch the band ( 12 ) coming from the cutting device (not shown) in the direction of the arrow tangentially ( FIG. 4), while, conversely, the wrap angle is increased with a lower band tension ( FIG. 5). For example, this can be done in that both the recording head ( 16 ) and the playback head ( 17 ) can be displaced perpendicular to the plane of the tape. Conversely, the rollers ( 18 , 18 ', 18 '') pressing on the back of the belt can also be displaced perpendicular to the belt running plane.

The magnetic tape runs over the deflection rollers ( 13 , 15 ), which are located in front of or behind the test device ( 14 , 14 ') and then via a pressure arm ( 5 ') on the winding roller ( 6 ), where it is wound up into a pancake . In this way, a fully tested pancake is available without further intermediate stages.

The pressure arm ( 5 ') can be designed as described in the German application file number P 42 03 310 of the applicant.

The signal recorded on the magnetic tape can then deleted from a (not shown) erase head Alternatively, the pancake can be rolled up then from one known from the prior art Quenching choke, published for example in the DE-GM 90 03 286, DE-OS 40 24 378 and DE-OS 37 08 540 and the DE 37 36 024 from the applicant.

In summary, the main advantages with the inventive method according to the particularly preferred Dropout measuring device can be achieved, called:

• a) The measuring device is integrated in the cutting machine and uses the tape transport necessary for the separation.
• b) It works with the smallest possible distance between opening Speech and read head to avoid interference caused by unequal moderate belt run and fluctuating time band to keep settlements small.
• c) It also suppresses the evaluation of measuring sections low separation speed.

Claims (4)

1. Device for determining dropouts in band-shaped flexible magnetic storage media ( 12 ) of any length, consisting of an unwinding roll ( 1 ) for the pancake, optionally a double-sided cleaning section ( 2 ) for eliminating apparent defects, if necessary a calming device acted upon by vacuum ( 3 ) to achieve a constant band tension, an arrangement ( 4 ) of two consecutive fixed head drums ( 7 , 10 ), between which there is a deflection roller ( 9 ) and a reel ( 6 ) for the pancake and a dropout counter , which is connected in a suitable manner with the signal reproducing heads, characterized in that the first head drum ( 7 ) has one or more height and distance adjustable recording heads ( 8 ) for speaking a signal and the second head drum ( 10 ) one same number of equally adjustable playback heads ( 11 ) for playback the same n signals. 2. Device according to claim 1, characterized in that the path length of the magnetic tape ( 12 ) between the recording and playback head is at most 10 cm. 3. A method for determining defects (dropouts) in tape-shaped flexible magnetizable storage media, especially in video tapes of any length with a device according to claims 1-2, wherein by means of egg nes or more fixed recording heads ( 8 ) a narrowband signal longitudinally on one or more Traces of the moving video tape recorded and in the same operation by means of one or more fixed playback heads ( 11 ), which are at a constant distance from the recording heads, dropouts are counted from a certain depth and duration, characterized in that the track width of the recorded signals of the video system to be tested speaks that the speed of the video tape is approximately equal to the relative speed v _H between the video head and tape in the video system to be tested, and that the frequency of the recorded narrowband signal in the range of the Lumi Nanzsignal frequency modulated carrier, preferably in the upper part of the frequency stroke of the video system in question. 4. A method for determining defects (dropouts) in tape-shaped flexible magnetizable storage media, in particular in video tapes of any length with a device according to claims 1-2, wherein by means of egg nes or more fixed recording heads ( 16 ) a narrowband signal longitudinally on one or more Traces of the moving video tape recorded and in the same process by means of one or more fixed playback heads ( 17 ), which are at a constant distance from the recording heads, dropouts are counted from a certain depth and duration, characterized in that the track width of the recorded Signals of the video system to be checked corresponds to the fact that the frequency of the recorded narrow-band signal lies in the area of the carrier frequency-modulated with the luminance signal, preferably in the upper part of the frequency swing of the video system in question, and that the dropout measurement is online nac h the longitudinal cutting of the magnetic track in video tapes with the width of use of the video system, with the separation speed v _L , the dropout length and the track length of the test section are multiplied by the factor v _H / v _L to determine the standardized dropout number.