US3885206A

US3885206A - Phase control system for rotary means

Info

Publication number: US3885206A
Application number: US424073A
Authority: US
Inventors: Takeshi Hort
Original assignee: Sony Corp
Current assignee: Sony Corp
Priority date: 1972-12-18
Filing date: 1973-12-12
Publication date: 1975-05-20
Anticipated expiration: 1992-05-20
Also published as: JPS4982883A; CA992137A; NL181700B; BR7309854D0; DE2362976A1; GB1450434A; JPS5328589B2; FR2211138A5; DE2362976B2; NL181700C; NL7317349A; IT1000858B

Abstract

A phase control system for a rotary member is provided which has a device for adjusting the rotation of a rotary member so as to make the rotational speed and rotary phase of the rotary member coincident for a reference frequency signal. The phase control system has a rotational speed control function to lock the rotary phase of the rotary member at the reference frequency signal without especially providing a device which makes the rotational speed of the rotary member coincident with the reference frequency signal.

Description

United States Patent 1 Hort [ 1 PHASE CONTROL SYSTEM FOR ROTARY MEANS [75] Inventor: Takeshi Hort, Chigasaki, Japan [73] Assignee: Sony Corporation, Tokyo, Japan [22] Filed: Dec. 12, 1973 [21] Appl. No.: 424,073

[30] Foreign Application Priority Data Dec. 18, 1972 Japan 47-126865 [52] US. Cl. 318/314; 318/318 [51] Int. Cl. 02p 5/16 [58] Field of Search 318/312, 318, 313, 327,

[56] References Cited UNITED STATES PATENTS 3/1970 Sommer 318/314 11/1967 Larsen 318/314 51 May 20,1975

Catherin 318/314 Heinz 318/327 Primary ExaminerRobert K. Schaefer Assistant Examiner-John .l. Feldhaus Attorney, Agent, or Firm-Lewis H. Eslinger; Alvin Sinderbrand [57] ABSTRACT A phase control system for a rotary member is provided which has a device for adjusting the rotation of a rotary member so as to make the rotational speed and rotary phase of the rotary member coincident for a reference frequency signal. The phase control systern has a rotational speed control function to lock the rotary phase of the rotary member at the reference frequency signal without especially providing a device which makes the rotational speed of the rotary member coincident with the reference frequency signal.

8 Claims, 37 Drawing Figures 6 54 50! w ll tcgrltaLl l SamPl mil [43914172 Wave lien, Y i 3 I l5 l6 PATENTED 2 5 SHEET [20F 4 j -ZB :M QMr w SN 5 (OJ. QM w IIII lllwliiam :lmiiwifi 4 M n r iLliil J liiiiiiii m 0 .I 0 .l 0 I 0 l 0 T 0 E F G H K L E E 2 2 E E E Pi -ZJ SHEET 03B? 4 PMENTED W 2 0 75 :zvh Illl lll ltlialllllwIlliul a m s Q J 5 1 a lwlllfialw l lll lllllllllllll ll 6 3 7 5 7" 5 L I i l w H .l. J K .L T 3 3 3 3 3 PATENTEB HAYZDlSYS SHEET D [1F 4 Pi -4L 1 PHASE CONTROL SYSTEM FOR ROTALY MEANS BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates generally to a phase control system, and more particularly to an improved phase control system for a rotary member.

2. Description of the Prior Art Up to now, there have been proposed various systems in which a means is provided for controlling the rotary phase of a rotary member to adjust the rotary phase or angular phase of the rotary member and to lock the same at a phase signal. Such systems are used for controlling the rotary phase of a rotary head employed in a video tape recorder, by way of example. In the case where the rotary phase of a rotary member such, for example, as a rotary head is controlled, if the control is achieved by a phase control system only or without providing a speed control system, the rotary member can not be locked at a correct rotary phase in its rotation. In other words, in such cases there is a defect that the rotary member is rotated while being locked at the phase signal but with a rotational speed of n times or I/n times (where n is 2, 3, the correct rotational speed. To avoid this, with the prior art system for a rotary member, it is required to provide a rotational speed control means in addition to the phase control system. As a result, the system becomes complicated in construction.

It is necessary that the speed of the rotary member set by the rotational speed control system must be as correct as possible. Otherwise, the rotary member is locked at a speed higher than the correct rotary speed by 2 times or lower than the latter by one-half. As a result of this, it requires much time before the rotary member is locked at the correct speed. By way of example, when a video tape is reproduced by a video tape recorder, the tracking of the rotary head for the signal tracks recorded on the video tape can be hardly done completely.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an improved phase control system for a rotary member free from the drawbacks encountered in the prior art.

It is another object of the present invention to provide a phase control system for a rotary member which makes it possible to quickly achieve coincidence.

It is a further object of the invention to provide a phase control system for a rotary member by which a rotary member can be rotated with phase-locked condition to a reference synchronizing signal without the provision of a rotational speed control system for rotating the rotary member at a reference rotational speed.

The additional and other objects, features and advantages of the invention will become apparent from the following description taken in conjunction with the accompanying drawing.

BRIEF DESCRIPTION OF THE DRAWING FIG. 1 is a systematic diagram showing an example of the phase control system for a rotary member according to the present invention; and

FIGS. 2A to 2L, 3A to 3L and 4A to 4L, inclusive, are waveform diagrams used for explanation of the example shown in FIG. I.

DESCRIPTION OF THE PREFERRED EMBODIMENT With reference to the drawing an embodiment of the present invention will be hereinafter described.

In FIG. 1, reference numeral 9 indicates a motor, for example, a DC motor with a rotary shaft 9a. Though not shown, a rotary shaft of, for example, a rotary head ofa video tape recorder is directly connected to the rotary shaft 90, or the rotary shaft 9a itself serves as a tape transporting capstan. Further, a hub portion for supporting a video tape (not shown) is mounted on the free end of rotary shaft and hence the rotary shaft 9a serves as a sheet rotative shaft for the video tape recorder. A rotary disc 10 is attached to the rotary shaft 9a integral therewith which has provided thereon a bar magnet 11 for indicating the phase angle of the rotary shaft 9a when it is rotated. A first pulse generator and a second pulse generator 12b are provided which detect the bar magnet 11 and pick up the rotational speed and angular position of rotary shaft 9a when it is rotated. Well-known magnetic heads can be employed as the

pulse generators

12a and 12b in the illustrated embodiment, by way of example, but it may be possible that various detecting means other than magnetic heads are employed as the pulse generator. In this alternative embodiments, it is of course necessary that other elements be used instead of the bar magnet 11 in association with the employed detecting means.

In the embodiment depicted in FIG. I, the first and

second pulse generators

12a and 12b are arranged on a chassis (not shown) such that they may oppose the bar magnet 11 on the diameter of the disc 10 symmetrical with respect to the rotary shaft 90 or the

pulse generators

12a and 12b are mounted with an angular separation of l80.

In FIG. 1, reference numeral 1 indicates an input terminal to which a synchronizing signal such as a vertical synchronizing signal separated from a television signal is applied. The synchronizing signal applied to the input terminal 1 is fed to a time-delay circuit 2 the output signal or time-delayed signal from which is applied to a gate signal generator 3. Monostable multivibrators, for example, can be used as the time-delay circuit 2 and gate signal generator 3, respectively. In this case, if necessary, the time interval within which the multivibrators are maintained in unstable state is made to be variable manually, the construction of which is well known and hence its description is omitted. Accordingly, the delay-time by the time-delay circuit 2 and the pulse width of the gate pulse derived from the gate signal generator 3 can be both adjusted manually. A first NAND-circuit 4 is provided with a pair of imput terminals one of which is supplied with the output signal or the gate pulse from the gate pulse generator 3. A second NAND-circuit 5 is also provided with a pair of input terminals one of which is supplied with the output signal from the first NAND-circuit 4. A signal integrating circuit such, for example, as a Miller integrator 6 is supplied, at its input terminal, with the output signal of the second NAND-circuit 5 and a sampling-hold gate circuit 7 is supplied, at its input terminal, with the output signal from the Miller integrator 6. The output signal of the sampling-hold gate circuit 7 is fed through a power amplifier such as a DC amplifier 8 to the motor 9. Thus, the motor 9 is controlled in its rotational speed or rotational phase in accordance with the DC level of the output signal from the DC amplifier 8. The integrator circuit 6, the sampling-hold gate circuit 7, the amplifier 8 and so on form a servo circuit.

First and second square-wave signal generators l and 16 are provided. The input terminal of first squarewave signal generator is connected to the first pulse generator 12a, while the input terminal of second square-wave signal generator 16 is connected to the output terminal of first square-wave signal generator 15. A first sampling circuit 17 is provided with a pair of input terminals which are supplied with the output signal from the second square-wave signal generator 16 and that of the second pulse generator 12b, respectively, to produce an AND-output signal. A second sampling circuit 18 is also provided with a pair of input terminals which are supplied with the output signal of the first square-wave signal generator 15 and that of the second pulse generator 12b to produce an AND output signal.

In fact, the both sampling circuits l7 and 18 are formed of a circuit in which the output signal from the square-wave generator is sampled with the output pulse from the pulse generator 12b, and a circuit in which the sampled output signals are stored. A sampling-hold gate circuit such as a latching circuit and so on can be used as the above circuit. A typical example of a smaplinghold gate circuit which can comprise the sampling circuits 17 and 18 is the sample and hold amplifier, Model A400, manufactured by Digital Equipment Corporation, Maynard, Massachusetts. Alternatively, the sampling circuits each may comprise a latching circuit such as a general-purpose .I-K flip-flop circuit, such as Model M207 manufactured by Digital Equipment Corporation. The output terminal of the first sampling circuit 17 is connected to the remaining input terminal of the first NAND circuit 4, while the output terminal of second sampling circuit 18 is connected to the remaining input terminal of the second NAND-circuit 5. A mixer 13 is provided which is supplied with, at its input terminals, the output pulses from the first and

second pulse generators

12a and 12b to produce a composite signal which is applied to the gate signal input terminal of the sampling-hold gate circuit 7 through an amplifier 14, if necessary.

With the above construction, if the motor 9 is rotated at a speed of r.p.s. during a normal state, by way of example, the first and

second pulse generators

12a and 12b produce pulses of 30l-lz corresponding to the first and second rotary positions, respectively. Further, if the vertical synchronizing signal contained in the tele vision signal is used as the synchronizing signal mentioned above, so that its frequency is 60l-Iz. The output signal from the mixer 13, which combines the first and second rotary position signals from the first and

second pulse generators

12a and 12b, is a pulse signal of (SUI-I2 when the motor 9 is rotated at the normal speed.

A description will be now given to the operation of the phase control system illustrated in FIG. 1 with reference to FIGS. 2 to 4.

Through FIGS. 2A, 3A and 4A, symbols S represent the vertical synchronizing input synchronizing signal; through FIGS. 28, 3B and 4B symbols S represent the output signal from the time-delay circuit 2; through FIGS. 2C, 3C and 4C S the output signal from the gate signal generating circuit 3; through FIGS. 2D, 3D and 4D, the output signal from the second NAND-circuit 5; through FIGS. 2E, and 4E, S the output signal 4 from the integrating circuit 6; through FIGS. 2F, 3F and 4F, S the first rotary position signal from the first pulse generator 12a; through FIGS. 26, 3G and 4G, S the second rotary position signal from the second pulse generator 12b; through FIGS. 2H, 3H and 4H, S; the output signal from the first square-wave signal generator 15; through FIGS. 21, SI and rI, S the output signal from the second square-wave signal generator 16; through FIGS. 2], 31 and 4], S the output signal from the second sampling circuit 18 through FIGS. 2K, 3K and 4K, S the output signal from the first sampling circuit l7; and through 2L, 3L and 4L, 8,, the output signal from the sampling-hold gate circuit 7, respectively.

As shown in FIGS. 2C to 4C, the output signal S derived from the gate signal generator 3 is delayed in phase from the vertical synchronizing signal S by r, and has the time duration of 1' The phase delay 1', and time duration 7 determine the phase difference between the synchronizing signal S and the pulses S and S obtained from the

pulse generators

12a and 12b.

By way of example, when the system of the present invention is employed in a video tape recorder which uses a rotary magnetic head, the recording position of the synchronizing signal S in the signal recording track on a video tape is determined by the above phase difference.

Time periods 1 and "r, of the output signals S and S from the square-wave generators l5 and 16 are determined, in this embodiment, as follows: When the motor 9 is rotated at the correct rotational speed, for example, at the rotational speed of 30 r.p.s., the time periods r, and r, are selected such that the square-wave signal 5,, from the generator 16 may coincide in generating time with the angle phase pulse 8 In the invention, the first and second square-wave generators l5 and 16 are formed of monostable multivibrators, respectively, so that the monostable multivibrators are respectively adjusted and hence their time intervals, within which the monostable multivibrators are in unstable state, are controlled to make the width or time duration of their output pulses variable and consequently to set the time periods 7 and r suitably.

As shown in FIGS. 2 to 4, the square-wave signal S, falls from 1 to 0 at the first rotary position signal S rises up from 0 to I after the time period of 1' and falls again from I to O at the next first rotary position signal S which is repeated. The square-wave signal S rises up from O to I when the signal S rises up; falls from I to 0 after the time period of T and rises up from O to I when the signal S rises up next, which is repeated.

The operation will be now described for the case where the motor 9 is rotated phase lock at the synchronizing signal correctly with as shown in FIG. 2.

In this case, the pulse S obtained from the pulse generator 12b, shown in FIG. 2G, coincides in time interval with the square-wave pulse S shown in FIG. 21, which is in I state, so that the output signal S from the first sampling circuit 17 is held in 1 state as shown in FIG. 2K. Accordingly, the pulse S from the gate signal generator 3, shown in FIG. 2C, is reversed in phase by the first NAND-circuit 4 and then fed to one input terminal of the second NAND-circuit 5. While, the first square-wave generator 15 produces as its output terminal the square-wave pulse S, which becomes 0 at the time when the pulse S is generated as shown in FIG.

2F. and returns to 1 after the time period 7 or at the time before the pulse S is generated, as shown in FIG. 2H. Accordingly, the second sampling circuit 18 produces the signal S which is held in l continuously, as shown in FIG. 2]. As a result. the second NAND-circuit 5 produces the signal S which is same as that S in waveform and phase, as shown in FIG. 2D. The signal 5;, is fed to the integrator 6 in which the signal 5;; is integrated at its interval and inverted in phase. Thus. the integrator 6 produces the trapezoidal-wave signal S. which has the ramp portion as shown in FIG. 2E. The trapezoidal-wave signal is fed to the sampling-hold gate circuit 7 and is sampled with the pulses S. and S at its ramp interval. As a result, the signal S which is varied in amplitude in response to the difference between the pulses S S and the synchronizing signal S as shown in FIG. 2L. is obtained from the samplinghold gate circuit 7.

The amplitude of the sampling-hold signal 8,, becomes high as the phase of signals S and S is intended to be delayed with respect to the signal S and becomes low as the phase of signals S and S is intended to lead. Accordingly. after the signal S is amplified by the amplifier 8. if desired. it is applied to the motor 9 to rotate the rotary shaft 9a of motor 9 always at the phase lock condition with the signal S If the load to the rotary shaft 9a of the motor 9 is removed. the rotational speed of motor 9 increases exceeding the possible phase lock condition. The operation of the system according to this invention in such a state will be now described with reference to FIG. 3.

In FIG. 3, the signals S. and S to S are obtained from the positions of the system same as those described in connection with FIG. 2.

As the rotational speed of the motor 9 is increased, as mentioned above. the signal S from the second pulse generator 12b is advanced in phase with respect to both the square-wave signals S and S from the square-wave generators l5 and 16. As a result, the sig nals S and S... from the sampling circuits l8 and 17 fall to O abruptly as shown in FIGS. SJ and 3K, respectively and hence the signal S applied to the integrator 6 becomes 1. as shown in FIG. 3D. The signal S is integrated thereby and its phase is reversed from 1 to O therein. Accordingly, even if the output signal S; from the integrator 6 is sampled and held in the samplinghold gate circuit 7. the output signal S from the sampling-hold gate circuit 7 is still 0. as shown in FIG. 3L. Thus. no current is applied to the motor 9. In practice. however, there is no need to make the current flowing through the motor 9 completely Zero, but a small amount of current could flow through the motor 9. As a result. the rotational speed of the motor 9 is lowered abruptly and hence the motor 9 returns to the rotation state described in connection with FIG. 2.

The case where the motor 9 is rotated at a speed lower than the predetermined servo rotational speed. as in the starting of the rotation of motor 9, will be described with reference to FIG. 4.

In this case. the time period from the generation of pulse 5 to that of pulse S becomes longer than the time period (T3 in.) as shown in FIG. 4. Accordingly, the signal 5 from the second pulse generator 12b becomes coincident with the square-wave signal S from the generator 15 in timing and hence the signals S and S from the sampling circuits l8 and 17 become I and O as shown in FIGS. 4[ and 4K. respectively. Thus, the

integrator 6 is supplied, at its input terminal, with the signal of 0 which is integrated and reversed from 0 to l thereby and thereafter applied to the sampling-hold gate circuit 7. The signal S from the integrator 6 is sampled with the signals S and S Thus. the sam pling-hold gate circuit 7 produces the signal S with a constant voltage +E, as shown in FIG. 4L. The signal S with the constant voltage +E is amplified by the amplifier 8 and then fed to the motor 9. The voltage +E is much higher than a voltage corresponding to that of a signal within the normal phase range. so that the rotational speed of the motor 9 increases abruptly and arrives at the speed described in connection with FIG. 2. Thus, even if the rotational speed of motor 9 is rotated at a speed lower than a speed within the predetermined control range, the voltage supplied to the motor 9 is changed to the fixed voltage and hence the motor 9 is abruptly brought to the predetermined phase control range.

With the phase control system of the invention described above. even if the rotational speed of the rotary member is much different from the predetermined one, it is quickly brought to the phase control range to achieve positive phase control.

In the above embodiment the motor 9 is a DC motor. but the present invention can be applied to a nonsynchronous AC motor such, for example, as an eddy current motor, and to a synchronous motor. In the case of using the synchronous motor, the output signal from the samplinghold gate circuit 7 is applied to a variable frequency oscillator and the output of the latter is am plified suitably and then applied to the synchronous motor.

Further, in the above embodiment the servo control is applied to the motor. but the present invention can be equally applied to the case where the rotary shaft is not directly coupled to the motor 9, but rotated by the motor through a slip means such as a belt at a speed higher than a reference speed, and a braking means such as a dynamic braking means is provided for the rotary shaft. which braking means is controlled by the output signal from the amplifier 8.

Although the illustrative embodiment of the invention has been described in detail herein with reference to the accompanying drawings. it is to be understood that the invention need not be limited to the precise embodiment. and that various changes and modifications may be effected therein by one skilled in the art without departing from the scope or spirit of the invention as defined in the appended claims.

I claim as my invention:

1. A phase control system for a rotary member comprising:

referenee signal generating means for generating a reference signal representing a predetermined rotary phase relationship for said rotary member; position signal generating means disposed to sense when said rotary member rotates to predetermined angular positions and to generate first and second position signals in response thereto;

square-wave signal generating means for generating a square-wave signal which has a predetermined phase relation with respect to the first position sig nal generated by said position signal generating means;

comparator means for comparing the second position signal generated by said position signal generating means with the square-wave signal, said comparator means exhibiting a first condition when the second position signal is in phase leading relationship with respect to said square-wave signal, a second condition when the second position signal is in phase lagging relationship with respect to said square-wave signal. and a third condition when the second position signal is in a predetermined phase range with respect to said square-wave signal; and

control signal generating means for generating a control signal to control the rotation of said rotary member in accordance with the phase relationship between said reference signal and at least one of said first and second position signals and further in accordance with the condition exhibited by said comparator means.

2. A phase control system according to claim 1 further comprising braking means for controlling the rotation of said rotary member, said braking means being controlled by said control signal generated by said control signal generating means.

3. A phase control system according to claim 1 in which said rotary member is rotated by a motor, said motor being controlled in phase by the control signal generated by said control signal generating means.

4. A phase control system according to claim 1 wherein said square-wave signal generating means comprises first monostable multivibrator means responsive to the first position signal for producing a first square-wave signal having a frequency equal to the frequency of the first position signal and having a first predetermined pulse width; and second monostable multivibrator means responsive to said first square-wave signal for producing a second square-wave signal having a frequency equal to the frequency of the first position signal and having a second predetermined pulse width.

5. A phase control system in accordance with claim 4 wherein said comparator means comprises first sampling means responsive to said first square-wave signal and the second position signal for producing a first output signal when said second position signal coincides with said first predetermined pulse witdth and for producing a second output signal when said second position signal does not coincide with said first predetermined pulse width; and second sampling means rcspon sive to said second square-wave signal and the second position signal for producing a third output signal when said second position signal coincides with said second predetermined pulse width and for producing a fourth output signal when said second position signal does not coincide with said second predetermined pulse width.

6. A phase control system according to claim 5 wherein said control signal generating means comprises coincidence means responsive to said reference signal and said first, second, third and fourth output signals to generate a periodic signal having a frequency equal to the frequency of said reference signal when said second and third output signals coincide, a first level signal when said first and fourth output signals coincide, and a second level signal when said second and fourth output signals coincide; and further sampling means cou pled to said coincidence means and said position signal generating means for sampling the signals generated by said coincidence means with said first and second position signals.

7. A phase control system according to claim 6 wherein said control signal generating means further comprises integrating means coupled to said coincidence means for producing a signal proportional to the time integral of said signals generated by said coincidence means, the signal produced by said integrating means having a limiting value; and wherein said further sampling means comprises a sample-and-hold circuit coupled to said integrating means for sampling the signal produced by said integrating means at sample times established by said first and second position signals and for storing the sampled signal between successive sampling times.

8. A phase control system according to claim 7 wherein said position signal generating means comprises first and second magnetic pick-up means spaced apart by a predetermined angular amount and positioned proximate the rotary member for sensing the passage of a magnetic element carried by the rotary member as said rotary member rotates.

l l l

Claims

1. A phase control system for a rotary member comprising: reference signal generating means for generating a reference signal representing a predetermined rotary phase relationship for said rotary member; position signal generating means disposed to sense when said rotary member rotates to predetermined angular positions and to generate first and second position signals in response thereto; square-wave signal generating means for generating a square-wave signal which has a predetermined phase relation with respect to the first position signal generated by said position signal generating means; comparator means for comparing the second position signal generated by said position signal generating means with the square-wave signal, said comparator means exhibiting a first condition when the second position signal is in phase leading relationship with respect to said square-wave signal, a second condition when the second position signal is in phase lagging relationship with respect to said square-wave signal, and a third condition when the second position signal is in a predetermined phase range with respect to said square-wave signal; and control signal generating means for generating a control signal to control the rotation of said rotary member in accordance with the phase relationship between said reference signal and at least one of said first and second position signals and further in accordance with the condition exhibited by said comparator means.

5. A phase control system in accordance with claim 4 wherein said comparator means comprises first sampling means responsive to said first square-wave signal and the second position signal for producing a first output signal when said second position signal coincides with said first predetermined pulse witdth and for producing a second output signal when said second position signal does not coincide with said first predetermined pulse width; and second sampling means responsive to said second square-wave signal and the second position signal for producing a third output signal when said second position signal coincides with said second predetermined pulse width and for producing a fourth output signal when said second position signal does not coincide with said second predetermined pulse width.

6. A phase control system according to claim 5 wherein said control signal generating means comprises coincidence means responsive to said reference signal and said first, second, third and fourth output signals to generate a periodic signal having a frequency equal to the frequency of said reference signal when said second and third output signals coincide, a first level signal when said first and fourth output signals coincide, and a second level signal when said second and fourth output signals coincide; and further sampling means coupled to said coincidence means and said position signal generating means for sampling the signals generated by said coincidence means with said first and second position signals.