Abstract:
Apparatus is disclosed for converting input step and direction commands from an external control source into stator winding drive current signals for a permanent magnet stepper motor. A translator circuit, having inputs coupled to the external control, generates sequential stator winding pulse enabling signals for transmission to a chopper-controlled power drive circuit. The chopper control features the sharing of a single chopper power switch by pairs of stator windings. The power drive circuit provides a winding current path to a reverse voltage supply upon initiation of winding current turn-off to enhance switching speed. A dual level current reference is generated in a current regulator circuit and compared with instantaneous stator winding currents to control the conduction states of the chopper power switches. Dual reference levels are established for idle versus accelerating or decelerating motor states, respectively. The translator circuit includes means for inhibiting chopper power switch conduction independently of the current regulator reference level comparison whenever the translator is switching drive current among stator windings, thereby decreasing power dissipation due to transients.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This invention is related to U.S. Ser. No. 938,432 entitled CONTROLLER FOR TOOL COMPENSATION SYSTEM by Murray, having the same filing date and assignee as the present invention. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention generally pertains to apparatus for supplying electrical energy to synchronous stepper motors. More specifically, the invention relates to a chopper controlled drive circuit for a permanent magnet step motor. 
     2. Description of the Prior Art 
     The step motor is a synchronous machine designed to rotate its rotor a predetermined amount in response to each electrical pulse, or step command, received by its drive circuit. The rotation is effected by delivering appropriate drive currents in response to received step commands to sequentially energize selected stator windings of the motor to force the axis of the air gap between rotor and stator poles into alignment. The portion of the motor drive furnishing the proper drive current switching sequence among the stator windings is commonly referred to as the translator section. 
     A known prior art approach utilizes two windings on each stator section of equal turns but of opposite winding sense (e.g., so-called &#34;bifilar&#34; windings) to effect reversal of magnetic flux in stator pole pieces without the need for two separate voltage sources of opposite polarity. 
     Further details of step motor types and typical prior art approaches to providing current drives thereto are found in a series of technical papers available from the Superior Electric Company, Bristol, Conn. 06010. 
     In a typical bifilar wound, permanent magnet rotor step motor, two bifilar wound coils (four coils total) are alternatively switched to provide stepping action. It is a further known technique to attempt to optimize step motor performance by furnishing a substantially constant current to stator windings in the course of energizing the motor. One such known approach is the so-called chopper driver. The typical chopper driver for a step motor utilizes a current sensor at the stator windings whose output is compared to a reference level. When stator current exceeds the reference level the chopper operates to interrupt the stator current supply until coil current decays to a level just below the reference, at which time the stator winding current source is reactivated. 
     Prior chopper controlled drive arrangements have raised problems of motor heating and heating of drive components due to relatively high chop rates, slow commutating action due to inductive loading during stator winding phase switching, and transient current spikes causing excessive power dissipation when switching between phases. 
     SUMMARY OF THE INVENTION 
     It is therefore an object of this invention to overcome prior art deficiencies of drive circuits for step motors in an economically feasible manner. 
     Specifically, it is an object of this invention to provide a drive arrangement for a permanent magnet step motor that utilizes a relatively low chopper operating frequency and generates negligible heat from undesirable switching transients, while enabling fast motor acceleration and reliable motor operation at relatively high stepping speeds. 
     Apparatus is disclosed for converting stepper motor input step and direction commands from an external control source into properly sequenced stator winding drive current signals whose amplitudes are regulated by a chopping action controlled by a dual level current reference control means. A translator circuit portion of the apparatus includes means for inhibiting chopper power switch conduction independently of the current reference control means whenever switching of drive current between stator windings is initiated, thereby eliminating harmful transients. 
     It is a feature of this invention that stator phase winding pairs economically share a common chopper transistor. 
     It is a further feature of this invention that a relatively low chop rate results from the inherent design of the motor drive apparatus, producing relatively low heat dissipation in the chopper power switching devices. 
     Yet another feature of the invention is the provision of an additional current path to a reverse potential of higher magnitude during the phase current commutation interval thereby allowing fast commutation between stator phases during stepper motor translation. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     These and other objects and features of the invention will become apparent upon a reading of a description of a preferred embodiment taken in conjunction with the drawing in which: 
     FIG. 1 is a functional block diagram of a stepper motor drive system arranged in accordance with the principles of the invention; 
     FIG. 2 is a more detailed schematic of the circuitry of power drive means 100 of FIG. 1; 
     FIG. 3 is a more detailed schematic of the circuitry of current reference control means 120 of FIG. 1; and 
     FIG. 4 is a more detailed schematic of the circuitry of translator 110 of FIG. 1. 
    
    
     DETAILED DESCRIPTION 
     Referring to FIG. 1, there is shown a block diagram of a stepper motor drive designed in accordance with the principles of the invention. Power drive current supply means 100 is coupled to four motor stator windings 102-105. Power drive means 100 is controlled by stator winding phase enable leads 111-114 coupling sequencing signals from translator circuitry 110 and chopper enable leads 121 and 122 coupling signals from reference control means 120. Driver means 100 includes stator current level monitoring means associated with each pair of stator windings 102, 103, and 104, 105 whose respective outputs 123 and 124 are coupled to reference control means 120. 
     Two chopper inhibit signals are coupled from translator 110 to reference control 120 via paths 115 and 116. 
     The drive arrangement of the instant invention is under the control of an external source 130 of stepper motor command signals. Path 131 from external source 130 carries a direction-indicating logic signal, path 132 carries a clocked step command pulse train for the stepper motor, and path 133 couples a logic signal indicating which of two reference current levels are to be used by reference control 120 in determining the switching states of the chopper switches in power drive 100. 
     External source 130 could, for example, be comprised of a micro-computer-based controller such as that disclosed in the above copending application identified in the Cross Reference to Related Applications. 
     It should be noted with reference to subsequent discussions of FIGS. 2-4, that identical reference numerals to those of FIG. 1 are used for lead designations in the detailed circuit depictions of FIGS. 2-4. Hence, the system block diagram of FIG. 1 may be used as a guide to the source or destination of such leads shown in the other figures of the drawings. 
     POWER DRIVE--FIG. 2 
     A more detailed schematic of the power drive 100 of FIG. 1 is set forth in FIG. 2. Stator phase windings 102 (φ 1 ), 103, (φ 2 ), 104 (φ 3 ), and 105 (φ 4 ) are shown in schematic form detached from the motor stator pieces on which they are physically wound. One typical motor usable with the drive circuit of this invention is a model M092-FC301, commercially available from the Superior Electric Company. 
     To avoid repetitive detail in FIGS. 2-4, functional blocks with similar lettering in their lower right-hand corner, by convention, are assumed to contain the same components depicted in one representative functional block. Hence, detailed structural descriptions will be given with reference only to those representative functional blocks shown in detail in FIGS. 2-4. 
     Referring to the power drive apparatus of FIG. 2, motor stator windings 102-105 respectively corresponding to phases 1-4 (φ 1  -φ 4 ) are switched in the so-called full step mode by a power transistor Q1 in respective functional blocks 201-204. Phases φ 1  and φ 2  share a chopper switch transistor Q13 while Phases φ 3  and φ 4  share a corresponding chopper switching device (not shown) in functional block 206. 
     Drive current for φ 1  flows from positive supply +V 1   through the collector-emitter circuit of Q1 through protection diode D1, through winding 102, through the collector-emitter circuit of chopper transistor Q13, through resistor R57 to ground. 
     Transistor Q1 is enabled by a logic one signal at path 111 rendering transistors Q9 and Q5 conductive. Resistors R36, R37, R38, and R39 are bias elements for the transistors of functional block 201. 
     Chopper transistor Q13 is enabled by a logic one signal at path 121 rendering transistors Q17 and Q15 conductive. Resistors R52-R57 are bias elements for the transistors of functional block 205. 
     Diode D5, coupled between the junction of windings 102 and 103 and source +V 1 , is used during switch off of transistor Q13 for a purpose to be explained below. A filter network comprised of resistor R64 and capacitor C11 is coupled between negative voltage source -V 2  and ground. 
     As an example of chopping action and power drive to winding 102, during the &#34;on&#34; time of chopper switch Q13 and phase enabling transistor Q1, the φ 1  current increases rapidly due to the low impedance presented from ground to source +V 1  via the above-described stator current path. When, due to φ 1  current exceeding a predetermined threshhold, Q13 is switched off while Q1 remains on, the current path for φ 1  now becomes throiugh the collector-emitter of Q1 via winding 102 and diode D5 back to source +V 1 . Hence φ 1  current will decay slowly because both sides, 151 and 152, of φ 1  winding 102 are at substantially equal potentials. Such slow current decay permits a relatively low chop frequency and results in reduced heat dissipation in Q13 during chopping, as compared to prior art chopping arrangements. 
     As an example of current switching, or translation, between stator phase windings, assume φ 1  current is flowing and we wish to switch stator winding current to φ 2  winding 103. To translate, the enable signal is removed from path 111 and a new enabling logic one signal is applied to path 112 by translator 110 (FIG. 1). As Q1 is switched off, the current path for φ 1  winding 102 to the negative voltage supply -V 2  via diode D7 causes φ 1  current to decay rapidly allowing fast commutation to phase φ 2 . Diode D2 in functional block 202, corresponding to diode D1 of block 201, serves to protect phase enabling transistor Q2 of block 202 from the resulting positive-going voltage spike developed at winding 103 that results from φ 1  current conduction through diode D7. 
     During the transistion period when transistor Q1 is turning off and its couterpart in functional block 202, Q2, is enabled, chopper transistor Q13 is momentarily turned off until the current through Q1 decays to zero. Such action by transistor Q13 prevents transient current spikes which would occur if windings 102 and 103 were simultaneously conducting current, thereby eliminating excessive heating of the power switching transistors of the drive circuitry of FIG. 2. 
     Reference Control Means--FIG. 3 
     FIG. 3 sets forth a more detailed schematic of reference control circuitry 120 of FIG. 1. Again, to avoid repetition, the convention of similarly designated functional blocks, with only one representative block shown in detail, has been used. The structural and functional descriptions below apply equally well to functional blocks not shown in detail. 
     Reference control 120 determines the appropriate conduction state of chopper switching transistors Q13 of the power drive circuit 120 of FIG. 2 by monitoring the potential developed across Q13 emitter resistor R57 via path 123 and amplifier 302 of FIG. 3, and comparing that potential with a dual level reference signal at comparator 304. 
     As seen from FIG. 3, path 123 is coupled via a filter network comprised of resistor R22 and capacitor C5 to the noninverting input of amplifier 302. Resistors R24 and R23 are bias and gain adjusting elements configured with amplifier 302 in a manner well known in the art. 
     The output of amplifier 302 is coupled via path 311 and resistor R28 to a non-inverting input of amplifier 304, which is configured using resistors R28-R30 as a comparator. 
     The dual level reference is obtained by summing an &#34;idle&#34; current reference developed at the junction of resistors R17 and R18 with a &#34;high&#34; current reference developed at the output of amplifier 301 in response to a logic one signal sent from external controller 130 (FIG. 1) via path 133 and resistor R9 to a non-inverting input of amplifier 301. Resistors R7 through R10 are typically arranged biasing elements for amplifier 301, while resistors R11 through R16 are configured to generate a desired &#34;idle&#34; current reference. A combined reference signal is coupled to an inverting input of comparator 304 via buffer amplifier 303 and its associated biasing elements R20 and R21. 
     The dual level reference arrangement described above enables use of a low stepper motor drive current level during standstill and a relatively high motor current during acceleration, thereby providing for a more efficient power drain when compared to stepper motor controllers of the prior art. 
     The chopper enable signals at path 121 are developed using the output of comparator 304 as a triggering signal for monopulser 305. Monopulser 305 may, for example, comprise IC type 14538, commercially available from Motorola, Inc. The time interval of the triggered monpulser outputs (a low-going logic signal at Q) is determined by the selected values of resistor R31 and capacitor C7. 
     When the current feedback signal at path 123, for example, exceeds the current chop reference at output 310 of amplifier 303, the output of comparator 304 goes positive to trigger monopulser 305. The monopulser output at Q goes low resulting in a chopper disabling signal at path 121 for the duration of the monopulser&#39;s active period. The monopulser active period is selected such that sufficient time is provided for the drive current in FIG. 2 to decay below the chop reference thereby resetting comparator 304 of FIG. 3. When monopulser 305 times out, the chopper switching transistors such as Q13 of FIG. 2, again are conductive and the chopper operation cycle continues. 
     Chopper transistor Q13 of FIG. 2 can alternatively be reset via path 121 due to the action of translator 110 (FIG. 1) producing a negative-going signal at path 115, which will override any pre-existing state of monopulser 305 to disable the corresponding chopper transistor. Such a signal is furnished by the translator at path 115 whenever two phases of stator winding current are being switched. These disabling pulses insure that if a new phase is switched during a chopping &#34;off&#34; state, the chopper circuit will be re-initialized for the newly active phase. 
     Translator--FIG. 4 
     Translator 110 of FIG. 1 is shown in more schematic detail in FIG. 4. This section of the system of FIG. 1 generates the proper phase enable sequence for turning the stepper motor in either direction in response to appropriate command signals received from external control 130 via paths 131 and 132. The phase enable signals are generated at paths 111, 112, 113, and 114. In addition, as mentioned above in connection with FIG. 3, chopper inhibit pulses at paths 115 and 116, which re-set the monostables 305 and its counterpart in block 354 of FIG. 3 to inhibit the chopper transistors of FIG. 2 when switching between phases, are generated in translator 110. 
     The direction-indicating logic signal at path 131 is coupled to an input of inverter 401, a first input of NAND gate 403 and to a first input of NAND gate 405. The output of inverter 401 is coupled to a first input of NAND gate 402 and to a first input of NAND gate 404. 
     The outputs of gates 402 and 403 are respectively coupled to first and second inputs of NAND gate 406, while the outputs of gates 404 and 405 are respectively coupled to first and second inputs of NAND gate 407. 
     Clocked step command pulses appearing at path 132 are coupled to a C input of D-type flip-flops 408 and 409. The D input of flip-flop 408 is coupled to the output of gate 406, while the D input of flip-flop 409 is coupled to the output of gate 407. The Q output of flip-flop 408 is coupled to a second input of gate 404, and to one terminal of resistor R1 and a first input to NOR gate 413 of the monopulser control circuitry of functional block 451. The Q output of flip-flop 408 is coupled to a second input of gate 405, and to one terminal of resistor R2 and a first input to NOR gate 412 of the monopulser circuitry of block 451. 
     The Q output of flip-flop 409 is coupled to a second input of gate 403, and to components (not specifically shown) in block 452 corresponding to components in block 451 coupled to the Q output of flip-flop 408. The Q output of flip-flop 409 is coupled to a second input of gate 402, and to components (not specifically shown) in block 452 in a manner similar to the connections in block 451 shown to the Q output of flip-flop 408. 
     Signal transitions at the Q outputs of flip-flop 408 are delayed from reaching a second input to OR gate 412 by resistor R1, capacitor C1 and buffer amplifier 410. Signal transitions at the Q output of flip-flop 408 are similarly delayed from reaching a second input to OR gate 413 by resistor R2, capacitor C2 and buffer amplifier 411. 
     The outputs of buffers 410 and 411 respectively additionally provide phase enabling signals to paths 111 and 112. 
     The outputs of OR gates 412 and 413 are respectively coupled to first and second inputs of AND gate 414, whose output is coupled to provide a negative-going trigger signal to monopulser 415. Monopulser 415 typically may comprise the above-referenced IC type 14538. Normally logic high monopulser 415 ouput Q is coupled to path 115. The logic level at path 131 determines one of two possible phase-pair sequences provided by the logic structure of FIG. 4 set forth above. 
     When a logic one is present at path 131, then the following sequence is effected, each step occurring as a result of a clocked pulse received at path 132: 
     
         φ.sub.1 φ.sub.3 -φ.sub.1 φ.sub.4 -φ.sub.2 φ.sub.4 -φ.sub.2 φ.sub.3 -φ.sub.1 φ.sub.3 
    
     When a logic zero is present at path 131, the above sequence is reversed for opposite motor stepping motion as follows: 
     
         φ.sub.1 φ.sub.3 -φ.sub.2 φ.sub.3 -φ.sub.2 φ.sub.4 -φ.sub.1 φ.sub.4 -φ.sub.1 φ.sub.3 
    
     The symbol φ m  φ n  represents current flow in phase windings n and m. 
     It should be noted that the invention described herein has been illustrated with reference to a particular embodiment. It is to be understood that many details used to faciliate the description of such a particular embodiment are chosen for convenience only and without limitation on the scope of the invention. Many other embodiments may be devised by those skilled in the art without departing from the scope and spirit of the invention. Accordingly, the invention is intended to be limited only by the scope and spirit of the appended claims.