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| NJM3775 DUAL STEPPER MOTOR DRIVER s GENERAL DESCRIPTION The NJM3775 is a switch-mode (chopper), constantcurrent driver with two channels: one for each winding of a two-phase stepper motor. NJM3775 is equipped with a Disable input to simplify half-stepping operation. The NJM3775 contains a clock oscillator, which is common for both driver channels, a set of comparators and flip-flops implementing the switching control, and two output H-bridges, including recirculation diodes. Voltage supply requirements are + 5 V for logic and + 10 to + 45 V for the motor. Maximum output current is 750mA per channel. s PACKAGE OUTLINE NJM3775D2 NJM3775E3 NJM3775FM2 s FEATURES * Dual chopper driver * 750 mA continuous output current per channel * Digital filter on chip eliminates external filtering components * Packages DIP22 / PLCC28 / EMP24(batwing) s BLOCK DIAGRAM Phase 1 Dis1 VR1 C1 E1 NJM3775 VCC V -- + CC R S Q M A1 Logic M B1 V MM1 + -- V MM2 M B2 Logic M A2 RC + -- S R Q Phase 2 Dis 2 V R2 C2 GND E2 Figure 1. Block diagram NJM3775 s PIN CONFIGURATIONS MB1 1 NC 1 MB1 2 E1 3 MA1 4 VMM1 5 GND 6 GND 7 VR1 8 C1 9 Phase1 10 Dis1 11 RC 12 24 23 22 21 4 VMM2 3 GND 2 GND 1 GND 28 GND 22 MB2 21 E 2 20 MA2 MA2 5 MB2 E2 MA2 VMM2 GND GND VR2 C2 Phase2 Dis2 Vcc E1 2 MA1 3 VMM1 4 GND 5 GND 6 VR1 7 C1 8 Phase 1 9 Dis1 10 RC 11 26 C 2 NC 27 V R2 25 24 23 Phase 2 Dis 2 VCC RC Dis 1 Phase1 C1 19 VMM2 18 GND E2 6 M B2 7 M B1 8 NJM 3775E3 20 19 18 17 16 15 14 13 NJM 3775D2 17 GND 16 V R2 15 C 2 NJM3775FM2 22 21 20 19 GND 9 E1 10 M A1 11 VMM1 12 GND 13 GND 14 GND 15 GND 16 GND 17 14 Phase 2 13 Dis2 12 VCC Figure 2. Pin configurations s PIN DESCRIPTION EMP DIP PLCC Symbol Description 2 3 4 5 6,7 18,19 8 9 10 11 12 13 14 15 16 17 20 21 22 23 1 2 3 4 5, 6, 17, 18 7 8 9 10 11 12 13 14 15 16 19 20 21 22 [8] [10] [11] [12] [1-3, 9, 13-17, 28] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [4] [5] [6] [7] MB1 E1 MA1 VMM1 GND VR1 C1 Phase1 Dis1 RC VCC Dis2 Phase2 C2 VR2 VMM2 MA2 E2 MB2 Motor output B, channel 1. Motor current flows from MA1 to MB1 when Phase1 is HIGH. Common emitter, channel 1. This pin connects to a sensing resistor RS to ground. Motor output A, channel 1. Motor current flows from MA1 to MB1 when Phase1 is HIGH. Motor supply voltage, channel 1, +10 to +40 V. VMM1 and VMM2 should be connected together. Ground and negative supply. Note: these pins are used thermally for heat-sinking. Make sure that all ground pins are soldered onto a suitably large copper ground plane for efficient heat sinking. Reference voltage, channel 1. Controls the comparator threshold voltage and hence the output current. Comparator input channel 1. This input senses the instantaneous voltage across the sensing resistor, filtered by the internal digital filter or an optional external RC network. Controls the direction of motor current at outputs MA1 and MB1. Motor current flows from MA1 to MB1 when Phase1 is HIGH. Disable input for channel 1. When HIGH, all four output transistors are turned off, which results in a rapidly decreasing output current to zero. Clock oscillator RC pin. Connect a 12 kohm resistor to VCC and a 4 700 pF capacitor to ground to obtain the nominal switching frequency of 23.0 kHz and a digital filter blanking time of 1.0s. Logic voltage supply, nominally +5 V. Disable input for channel 2. When HIGH, all four output transistors are turned off, which results in a rapidly decreasing output current to zero. Controls the direction of motor current at outputs MA2 and MB2. Motor current flows from MA2 to MB2 when Phase2 is HIGH. Comparator input channel 2. This input senses the instantaneous voltage across the sensing resistor, filtered by the internal digital filter or an optional external RC network. Reference voltage, channel 2. Controls the comparator threshold voltage and hence the output current. Motor supply voltage, channel 2, +10 to +40 V. VMM1 and VMM2 should be connected together. Motor output A, channel 2. Motor current flows from MA2 to MB2 when Phase2 is HIGH. Common emitter, channel 2. This pin connects to a sensing resistor RS to ground. Motor output B, channel 2. Motor current flows from MA2 to MB2 when Phase2 is HIGH. VR1 18 NJM3775 s FUNCTIONAL DESCRIPTION Each channel of the NJM3775 consists of the following sections: an output H-bridge with four transistors and four recirculation diodes, capable of driving up to 750 mA continuous current to the motor winding, a logic section that controls the output transistors, an S-R flip-flop, and a com- parator. The clock-oscillator is common to both channels. Constant current control is achieved by switching the output current to the windings. This is done by sensing the peak current through the winding via a current-sensing resistor RS, effectively connected in series with the motor winding. As the current increases, a voltage develops across the sensing resistor, which is fed back to the comparator. At the predetermined level, defined by the voltage at the reference input VR, the comparator resets the flipflop, which turns off the upper output transistor. The turn-off of one channel is independent of the other channel. The current decreases until the clock oscillator triggers the flip-flops of both channels simultaneously, which turns on the output transistors again, and the cycle is repeated. To prevent erroneous switching due to switching transients at turn-on, the NJM3775 includes a digital filter. The clock oscillator provides a blanking pulse which is used for digital filtering of the voltage transient across the current sensing resistor during turn-on. The current paths during turn-on, turn-off and phase shift are shown in figure 3. V MM 1 2 3 RS Motor Current 1 2 3 Fast Current Decay Slow Current Decay Time Figure 3. Output stage with current paths during turn-on, turn-off and phase shift. NJM3775 s ABSOLUTE MAXIMUM RATINGS Parameter Pin No. (DIP) Symbol Min Max Unit Voltage Logic supply Motor supply Logic inputs Analog inputs Current Motor output current Logic inputs Analog inputs Temperature Operating junction temperature Storage temperature Power Dissipation (Package Data) Power dissipation at TGND = +25C, DIP and PLCC package Power dissipation at TGND = +125C, DIP package Power dissipation at TGND = +125C, PLCC package 12 4, 19 9, 10, 13, 14 7, 8, 15, 16 1, 3, 20, 22 9, 10, 13, 14 7, 8, 15, 16 VCC VMM VI VA IM II IA Tj Tstg PD PD PD 0 0 -0.3 -0.3 -850 -10 -10 -40 -55 - 7 45 6 VCC +850 +150 +150 5 2.2 2.6 V V V V mA mA mA C C W W W s RECOMMENDED OPERATING CONDITIONS Parameter Symbol Min Typ Max Unit Logic supply voltage Motor supply voltage Output emitter voltage Motor output current Operating junction temperature Rise and fall time logic inputs Oscillator timing resistor VCC VMM VE IM Tj tr,, tf RT 4.75 10 -750 -20 2 5 12 5.25 40 1.0 +750 +125 2 20 V V V mA C ms kohm | V MA - V MB | Phase 1 9 Dis 1 VR1 10 7 C1 8 E1 2 t on 50 % t off NJM3775 I CC V CC V 12 -- + CC R S Q 3 Logic 1 M A1 M B1 V MM1 V MM2 M B2 M A2 IM I OL I MM VE ( I M ) V R t td 4 12 kW + RT 19 -- 22 Logic I RC RC 11 + -- 4 700 pF 20 S R Q VCC CT Phase 2 II I IH IR VI V V IH t 14 13 16 15 C2 IC IA VCH V VM VE V MA V MM 5, 6, 17, 18 GND 21 E2 V RC tb Dis 2 V R2 I IL IA VA V R VRC V C IL A t RS fs = t + t on off 1 D= ton ton + t off Figure 4. Definition of symbols Figure 5. Definition of terms NJM3775 s ELECTRICAL CHARACTERISTICS Electrical characteristics over recommended operating conditions, unless otherwise noted. - 20C Tj + 125C. Parameter Symbol Conditions Min Typ Max Unit General Supply current Supply current Total power dissipation Total power dissipation Thermal shutdown junction temperature Turn-off delay Logic Inputs Logic HIGH input voltage Logic LOW input voltage Logic HIGH input current Logic LOW input current Analog Inputs Threshold voltage Input current |VC1--VC2| mismatch Motor Outputs Lower transistor saturation voltage Lower transistor leakage current Lower diode forward voltage drop Upper transistor saturation voltage Upper transistor leakage current Upper diode forward voltage drop Chopper Oscillator Chopping frequency Digital filter blanking time ICC ICC PD PD Note 4. Dis1= Dis2= HIGH. VMM= 24 V, IM1= IM2= 500 mA. Notes 2, 3, 4. VMM= 24 V, IM1= 700 mA, IM2= 0 mA. Notes 2, 3, 4. TA = +25C, dVC/dt 50 mV/s, IM = 100 mA. Note 3. - 55 7 2.0 1.7 160 1.1 70 10 2.3 2.0 2.0 mA mA W W C s td VIH VIL IIH IIL VCH IA VCdiff VI = 2.4 V VI = 0.4 V VR=5 V VR= 5 V 2.0 -0.2 480 21.5 - -0.1 500 500 1 0.4 1.1 1.1 1.1 23.0 1.0 0.6 20 520 0.8 100 1.3 1.4 100 1.4 24.5 - V V A mA mV A mV V A V V A V kHz s IM = 500 mA VMM=41 V,TA = +25C. Dis1= Dis2= HIGH. IM = 500 mA IM = 500 mA. VMM=41 V,TA = +25C. Dis1= Dis2= HIGH.. IM = 500 mA. fs tb CT = 4 700 pF, RT = 12 kohm CT = 4 700 pF. Note 3. s THERMAL CHARACTERISTICS Parameter Symbol Conditions Min Typ Max Unit Thermal resistance RthJ-GND RthJ-A RthJ-GND RthJ-A RthJ-GND RthJ-A DIP package. DIP package. Note 2. PLCC package. PLCC package. Note 2. EMP package EMP package - 11 40 9 35 13 42 - C/W C/W C/W C/W C/W C/W Notes 1. All voltages are with respect to ground. Currents are positive into, negative out of specified terminal. 2. All ground pins soldered onto a 20 cm2 PCB copper area with free air convection, TA = + 25 C. 3. Not covered by final test program. 4. Switching duty cycle D = 30 %, fs = 23.0 kHz. NJM3775 s APPLICATIONS INFORMATION Current control The regulated output current level to the motor winding is determined by the voltage at the reference input and the value of the sensing resistor, RS. The peak current through the sensing resistor (and the motor winding) can be expressed as: IM,peak = 0.1*VR / RS [A] With a recommended value of 0.5 ohm for the sensing resistor RS, a 2.5 V reference voltage will produce an output current of approximately 500 mA. RS should be selected for maximum motor current. Be sure not to exceed the absolute maximum output current which is 850 mA. Chopping frequency, winding inductance and supply voltage also affect the current, but to much less extent. For accurate current regulation, the sensing resistor should be a 0.5 -1.0 W precision resistor, i. e. less than 1% tolerance and low temperature coefficient. +5 V + V MM 0.1F 12 V 9 10 7 Phase 1 Dis1 V R1 Phase 2 Dis 2 V R2 RC GND 11 +5 V 12 k 4 700 pF RS 0.47 RS 0.47 CC 0.1 F 4 V MM1 10 F 19 V MM2 MA1 3 MB1 1 20 NJM3775 MA2 14 13 16 MB2 C1 8 E1 2 C2 15 E2 21 22 5, 6, 17, 18 STEPPER MOTOR Pin numbers refer to DIP package. GND (V MM ) GND (VCC ) Figure 6. Typical stepper motor driver application with NJM3775. VCC + 4.7 F 4x 10 k (+5 V) + V MM 0.1 F 12 4 V MM1 0.1 F 19 V MM2 10 F 16 Direction Step Half/Full Step 6 7 10 11 8 V DIR STEP HSM INH fl P B1 B GND CC P A1 4 V 9 10 7 Phase 1 Dis 1 V R1 Phase 2 Dis 2 V R2 RC GND 11 12 k CC MA1 3 NJM 3517 2 MB1 1 20 NJM3775 MA2 14 13 16 9fl A MB2 C1 8 E1 2 C2 15 E2 21 22 3 5, 6, 17, 18 STEPPER MOTOR 4 700 pF RS RS 1.0 1.0 Pin numbers refer to DIP package. GND (V MM ) GND (V CC ) Figure 7. Half stepping system where NJM3517 is used as controller circuit in order to generate the necessary sequence to the NJM3775. NJM3775 Current sense filtering At turn-on a current spike occurs, due to the recovery of the recirculation diodes and the capacitance of the motor winding. To prevent this spike from reseting the flip-flops through the current sensing comparators, the clock oscillator generates a blanking pulse at turn-on. The blanking pulse pulse disables the comparators for a short time. Thereby any voltage transient across the sensing resistor will be ignored during the blanking time. Choose the blanking pulse time to be longer than the duration of the switching transients by selecting a proper CT value. The time is calculated as: tb = 210 * CT [s] As the CT value may vary from approximately 2 200 pF to 33 000 pF, a blanking time ranging from 0.5 s to 7 s is possible. Nominal value is 4 700 pF, which gives a blanking time of 1.0 s. As the filtering action introduces a small delay, the peak value across the sensing resistor, and hence the peak motor current, will reach a slightly higher level than what is defined by the reference voltage. The filtering delay also limits the minimum possible output current. As the output will be on for a short time each cycle, equal to the digital filtering blanking time plus additional internal delays, an amount of current will flow through the winding. Typically this current is 1-10 % of the maximum output current set by RS. When optimizing low current performance, the filtering may be done by adding an external low pass filter in series with the comparator C input. In this case the digital blanking time should be as short as possible. The recommended filter component values are 1 kohm and 820 pF. Lowering the switching frequency also helps reducing the minimum output current. To create an absolute zero current, the Dis input should be HIGH. Switching frequency The frequency of the clock oscillator is set by the timing components RT and CT at the RC-pin. As CT sets the digital filter blanking time, the clock oscillator frequency is adjusted by RT. The value of RT is limited to 2 - 20 kohm. The frequency is approximately calculated as: fs = 1 / ( 0.77 * RT * CT) Nominal component values of 12 kohm and 4 700 pF results in a clock frequency of 23.0 kHz. A lower frequency will result in higher current ripple, but may improve low level linearity. A higher clock frequency reduces current ripple, but increases the switching losses in the IC and possibly the iron losses in the motor. Phase inputs A logic HIGH on a Phase input gives a current flowing from pin MA into pin MB. A logic LOW gives a current flow in the opposite direction. A time delay prevents cross conduction in the H-bridge when changing the Phase input. Phase 1 Dis 1 Phase 2 Dis 2 Thermal resistance [C/W] 80 22-pin DIP V R1 140% 100% 70 V R2 60 140% 100% 50 I MA1 140% 100% 40 24-pin EMP -100% -140% 30 I MA2 20 5 10 15 20 25 30 35 28-pin PLCC 140% 100% PCB copper foil area [cm 2 ] PLCC package DIP package -100% -140% Full step mode Half step mode Modified half step mode Figure 8. Typical thermal resistance vs. PC Board copper area and suggested layout. Figure 9. Stepping modes NJM3775 Dis (Disable) inputs A logic HIGH on the Dis inputs will turn off all four transistors of the output H-bridge, which results in a rapidly decreasing output current to zero. VR (Reference) inputs The Vref inputs of the NJM3775 have a voltage divider with a ratio of 1 to 10 to reduce the external reference voltage to an adequate level. The divider consists of closely matched resistors. Nominal input reference voltage is 5 V. Interference Due to the switching operation of NJM3775, noise and transients are generated and might be coupled into adjacent circuitry. To reduce potential interference there are a few basic rules to follow: * Use separate ground leads for power ground (the ground connection of RS), the ground leads of NJM3775, and the ground of external analog and digital circuitry. The grounds should be connected together close to the GND pins of NJM3775. * Decouple the supply voltages close to the NJM3775 circuit. Use a ceramic capacitor in parallel with an electrolytic type for both VCC and VMM. Route the power supply lines close together. * Do not place sensitive circuits close to the driver. Avoid physical current loops, and place the driver close to both the motor and the power supply connector. The motor leads could preferably be twisted or shielded. Motor selection The NJM3775 is designed for two-phase bipolar stepper motors, i.e. motors that have only one winding per phase. The chopping principle of the NJM3775 is based on a constant frequency and a varying duty cycle. This scheme imposes certain restrictions on motor selection. Unstable chopping can occur if the chopping duty cycle exceeds approximately 50 %. See figure 5 for definitions. To avoid this, it is necessary to choose a motor with a low winding resistance and inductance, i.e. windings with a few turns. It is not possible to use a motor that is rated for the same voltage as the actual supply voltage. Only rated current needs to be considered. Typical motors to be used together with the NJM3775 have a voltage rating of 1 to 6 V, while the supply voltage usually ranges from 12 to 40 V. Low inductance, especially in combination with a high supply voltage, enables high stepping rates. However, to give the same torque capability at low speed, the reduced number of turns in the winding in the low resistive, low inductive motor must be compensated by a higher current. A compromise has to be made. Choose a motor with the lowest possible winding resistance and inductance, that still gives the required torque, and use as high supply voltage as possible, without exceeding the maximum recommended 40 V. Check that the chopping duty cycle does not exceed 50 % at maximum current. Heat sinking NJM3775 is a power IC, packaged in a power DIP,EMP or PLCC package. The ground leads of the package (the batwing) are thermally connected to the chip. External heatsinking is achieved by soldering the ground leads onto a copper ground plane on the PCB. Maximum continuous output current is heavily dependent on the heatsinking and ambient temperature. Consult figures 8,10 and 11 to determine the necessary heatsink, or to find the maximum output current under varying conditions. A copper area of 20 cm2 (approx. 1.8" x 1.8"), copper foil thickness 35 m on a 1.6 mm epoxy PCB, permits the circuit to operate at 2 x 450 mA output current, at ambient temperatures up to 85 C. Thermal shutdown The circuit is equipped with a thermal shutdown function that turns the outputs off at a chip (junction) temperature above 160 C. Normal operation is resumed when the temperature has decreased. Programming Figure 9 shows the different input and output sequences for full-step, half-step and modified halfstep operations. NJM3775 Full-step mode. Both windings are energized at all the time with the same current, IM1 = IM2. To make the motor take one step, the current direction (and the magnetic field direction) in one phase is reversed. The next step is then taken when the other phase current reverses. The current changes go through a sequence of four different states which equal four full steps until the initial state is reached again. Half-step mode. In the half-step mode, the current in one winding is brought to zero before a complete current reversal is made. The motor will then have taken two half steps equalling one full step in rotary movement. The cycle is repeated, but on the other phase. A total of eight states are sequenced until the initial state is reached again. Half-step mode can overcome potential resonance problems. Resonances appear as a sudden loss of torque at one or more distinct stepping rates and must be avoided so as not to loose control of the motors shaft position. One disadvantage with the half-step mode is the reduced torque in the half step positions, in which current flows through one winding only. The torque in this position is approximately 70 % of the full step position torque. Modified half-step mode. The torque variations in half step mode will be elimi-nated if the current is increased about 1.4 times in the halfstep position. A constant torque will further reduce resonances and mechanical noise, resulting in better performance, life expectancy and reliability of the mechanical system. Modifying the current levels must be done by bringing the reference voltage up (or down) from its nominal value correspondingly. This can be done by using DACs or simple resistor divider networks. The NJM3775 is designed to handle about 1.4 times higher current in one channel on mode, for example 2 x 500 mA in the full-step position, and 1 x 700 mA in the half-step position. NJM3775 s TYPICAL CHARACTERISTICS PD (W) 6 Maximum allowable power dissipation [W] VCE Sat (V) 3.0 5 1.2 Batw Am bie 4 nt 1.0 0.8 0.6 0.4 0.2 pin ing te m 2.0 pe 3 ra tu ture pera tem re 1.0 Tw o ch n an els on 2 1 0 0 c One 0.20 han nel on 0 -25 0 25 50 75 100 125 150 Temperature [C] 0.40 0.60 0.80 0 0 0.20 0.40 0.60 0.80 I M (A) PLCC package DIP package All ground pins soldered onto a 20 cm2 PCB copper area with free air convection. I M (A) Figure 10. Power dissipation vs. motor current.Ta = 25C. Vd, ld (V) Figure 11. Maximum allowable power Figure 12. Typical lower transistor saturation voltage vs. output current. dissipation. VCE Sat (V) Vd, ud (V) 1.2 1.0 0.8 0.6 0.4 0.2 1.2 1.0 0.8 0.6 0.4 0.2 1.2 1.0 0.8 0.6 0.4 0.2 0 0 0.20 0.40 0.60 0.80 0 0 0.20 0.40 0.60 0.80 0 0 0.20 0.40 0.60 0.80 I M (A) I M (A) I M (A) Figure 11. Typical lower diode voltage Figure 12. Typical upper transistor Figure 13. Typical upper diode drop vs. recirculating current. saturation voltage vs. output current. voltage drop vs. recirculating current. The specifications on this databook are only given for information , without any guarantee as regards either mistakes or omissions. The application circuits in this databook are described only to show representative usages of the product and not intended for the guarantee or permission of any right including the industrial rights. |
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