61108hkim/22004tn(ot) no.7441-1/19 stk672-060-e overview the stk672-060-e is a stepping motor driver hybrid ic that uses power mosfets in the output stage. it includes a built- in microstepping controller and is based on a unipolar constant-current pwm system. the stk672-060-e supports application simplification and standardization by providing a built-in 4 phase distribution stepping motor controller. it supports five excitation methods: 2 phase, 1-2 phase, w1-2 phase, 2w1-2 phase, and 4w1-2 phase excitations, and can provide control of the basic stepping angle of the stepping motor divided into 1/16 step units. it also allows the motor speed to be controlled with only a clock signal. the use of this hybrid ic allows designers to implement syst ems that provide high motor torques, low vibration levels, low noise, fast response, and high-efficiency drive. applications ? facsimile stepping motor drive (send and receive) ? paper feed and optical system stepping motor drive in copiers ? laser printer drum drive ? printer carriage stepping motor drive ? x-y plotter pen drive ? other stepping motor applications note*: conditions: v cc 1 = 24v, i oh = 1.2a, 2w1-2 excitation mode. ordering number : en7441b thick-film hybrid ic unipolar constant-c urrent chopper (external excitation pwm) circuit with built-in microstepping controller stepping motor driver (sine wave drive) output current 1.2a (no heat sink*) specifications of any and all sanyo semiconductor co.,l td. products described or contained herein stipulate the performance, characteristics, and functions of the described products in the independent state, and are not guarantees of the performance, characteristics, and functions of the described products as mounted in the customer ' s products or equipment. to verify symptoms and states that cannot be evaluated in an independent device, the customer should always evaluate and test devices mounted in the customer ' sproductsor equipment. any and all sanyo semiconductor co.,ltd. products described or contained herein are, with regard to "standard application", intended for the use as general electronics equipment (home appliances, av equipment, communication device, office equipment, industrial equ ipment etc.). the products mentioned herein shall not be intended for use for any "special application" (medica l equipment whose purpose is to sustain life, aerospace instrument, nuclear control device, burning appliances, t ransportation machine, traffic signal system, safety equipment etc.) that shall require extremely high level of re liability and can directly threaten human lives in case of failure or malfunction of the product or may cause har m to human bodies, nor shall they grant any guarantee thereof. if you should intend to use our products for app lications outside the standard applications of our customer who is considering such use and/or outside the scope of our intended standard applications, please consult with us prior to the intended use. if there is n o consultation or inquiry before the intended use, our customer shall be solely responsible for the use.
stk672-060-e no.7441-2/19 features ? can implement stepping motor drive systems simply by providing a dc power supply and a clock pulse generator. ? one of five drive types can be selected with the drive mode settings (m1, m2, and m3) 1) 2 phase excitation drive 2) 1-2 phase excitation drive 3) w1-2 phase excitation drive 4) 2w1-2 phase excitation drive 5) 4w1-2 phase excitation drive ? provides four freely selectable modes for the vector locus during microstepping drive: circular mode, one inside mode, and two outside modes. ? phase retention even if excitation is switched. ? the excitation phase state can be verified in real time using the mo1, mo2, and moi signal output pins. ? the clk input counter block can be selected to be one of the following by the high/low setting of the m3 input pin. 1) rising edge only 2) both rising and falling edges ? the clk and return input pins include built-in malfunc tion prevention circuits for external pulse noise. ? enable and reset pins provided. these ar e schmitt trigger inputs with built-in 20k � (typical) pull-up resistors. ? no noise generation due to the differe nce between the a and b phase time cons tants during motor hold since external excitation is used. ? microstepping operation supported even for small motor curr ents, since the reference voltage vref can be set to any value between 0v and 1/2v cc 2. ? external excitation pwm drive allows a wide operating supply voltage range (v cc 1 = 10 to 45v) to be used. ? current detection resistor (0.22 � ) built-in the hybrid ic itself. ? power mosfets adopted for low drive loss. ? provides a motor output drive current of i oh = 1.2a. specifications absolute maximum ratings at ta = 25 c parameter symbol conditions ratings unit maximum supply voltage 1 v cc 1 max no signal 52 v maximum supply voltage 2 v cc 2 max no signal -0.3 to +7.0 v input voltage v in max logic input pins -0.3 to +7.0 v output current i oh max 0.5s, 1 pulse, when v cc 1 applied 1.6 a repeated avalanche capacity ear max 25 mj allowable power dissipation pd max � c-a = 0 7 w operating substrate temperature tc max 105 c junction temperature tj max 150 c storage temperature tstg -40 to +125 c allowable operating ranges at ta = 25 c parameter symbol conditions ratings unit supply voltage 1 v cc 1 with signals applied 10 to 45 v supply voltage 2 v cc 2 with signals applied 5 5% v input voltage v ih 0 to v cc 2v phase driver withstand voltage v dss tr1, 2, 3, and 4 (the a, a, b, and b outputs) 100 (min) v output current i oh duty 50% 1.2 a
stk672-060-e no.7441-3/19 electrical characteristics at tc = 25 c, v cc 1 = 24v, v cc 2 = 5v rating parameters symbols conditions min typ max unit control supply current i cc pin 7, with enable pin held low. 2.5 14 ma output saturation voltage vsat r l = 23 � (i � 1a) 0.8 1.1 v average output current ioave load: r = 3.5 � / l = 3.8mh for each phase, vref � 1.69v 0.470 0.524 0.580 a fet diode forward voltage vdf if = 1a 1.2 1.8 v [control inputs] v ih except for the vref pin 4 v input voltage v il except for the vref pin 1 v i ih except for the vref pin 0 1 10 a input current i il except for the vref pin 125 250 510 a [vref input pin] input voltage v i pin 8 0 2.5 v input current i i pin 8, v i = 2.5v 330 415 545 a [control outputs] v oh i = ?3ma, pins moi, mo1, mo2 2.4 v output voltage v ol i = +3ma, pins moi, mo1, mo2 0.4 v [current distribution ratio (ab)] 2w1-2, w1-2, 1-2 vref � = 1/8 100 % 2w1-2, w1-2 vref � = 2/8 92 % 2w1-2 vref � = 3/8 83 % 2w1-2, w1-2, 1-2 vref � = 4/8 71 % 2w1-2 vref � = 5/8 55 % 2w1-2, w1-2 vref � = 6/8 40 % 2w1-2 vref � = 7/8 21 % 2 vref 100 % pwm frequency fc 37 47 57 khz note: a constant-voltage power supply must be used. the design target value is shown for the current distribution ratio. package dimensions unit:mm (typ) 4161 122 53.0 0.5 2.0 22.0 9.0 0.4 2.9 4.0 1.0 21 2=42
stk672-060-e no.7441-4/19 internal block diagram 21 20 19 16 18 22 17 11 14 15 10 9 7 12 13 8 6 5 2 1 + ? + ? 3 4 m1 m2 cwb clk m3 return reset moi mo1 mo2 enable sg sub pg b b a a vref m5 m4 v cc 2 excitation mode control excitation state monitor phase advance counter current distribution ratio switching pseudo-sine wave generator rise detection rc oscillator itf02264 pwm control reference clock generation phase excitation drive signal generation rise/fall detection and switching
stk672-060-e no.7441-5/19 test circuit diagrams vsat vdf i ih , i il ioave, i cc , fc when measuring ioave: with sw1 set to ?b?, vref = 1.69v when measuring fc: with sw 1 set to ?a?, vref = 0v when measuring i cc : set enable low 14 9 10 8 16 22 1 3 4 2 5 6 a 23 � a b b 7 + v cc 2 v cc 2 stk672-060-e start v ref=2.5v v v cc 1 itf02265 22 1 2 5 6 a a b b 7 stk672-060-e v a itf02266 3 4 9 22 7 v cc 2 m1 stk672-060-e itf02267 10 m2 11 m3 12 m4 13 m5 14 14 clk 15 cwb 16 reset 17 return 18 enable 8 vref i il i ih a + 14 9 10 8 16 22 1 5 2 6 a a b a b a b sw2 sw1 b 7 18 v cc 2 v cc 2 vref=1.69v 0v 5v 0v low when measuring i cc v cc 1 v cc 1 stk672-060-e itf02268 a a start
stk672-060-e no.7441-6/19 power-on reset the application must perform a power-on reset operation when v cc 2 power is first applied to this hybrid ic. application circuit that used 2w1-2 phase excitation (microstepping operation) mode. setting the motor current the motor current i oh is set by the vref voltage on the hybrid ic pin 8. the following formula gives the relationship between i oh and vref. rox = (ro2 6k � ) (ro2 + 6k � ) (1) vref = v cc 2 rox (ro1 + rox) (2) i oh = (3) k: 7.66 (voltage divider ratio), rs: 0.22 � (this is the hybrid ic's internal current detection resistor. it has a tolerance of 3%.) applications can use motor currents from the current (0.05 to 0.1a) set by the duty of the frequency set by the oscillator up to the limit of the allowable operating range, i oh = 1.2a function table m2 0 0 1 1 m1 m3 0 1 0 1 phase switching clock edge timing 1 2 phase excitation 1-2 phase excitation w1-2 phase excitation 2w1-2 phase excitation rising edge only 0 1-2 phase excitation w1-2 phase excitation 2w1-2 phase excitation 4w1-2 phase excitation rising and falling edges forward reverse enable motor current is cut off when low cwb 0 1 reset active low a a b b mo1 1 0 0 1 mo2 0 0 1 1 k 1 rs vref 8 6 a a 7 22 12 11 10 9 14 13 15 14 18 16 17 19 + + v cc 2=5v v cc 2=5v sg 100 f or higher pg vref v cc 2=5v clk 1k � enable ret reset moi v cc 1=10v to 45v two-phase stepping motor stk672-060-e itf02269 b b 5 2 1 3 4 20 mo1 21 mo2 ro1 ro2 simple power-on reset circuit (this circuit cannot be used to detect drops in the supply voltage.) v f 0.3v rox a value of about 100 � is recommended for ro2 to minimize the influence of the 6k � internal resistance of the vref pin. rox: input impedance of 6k � 30% motor current waveform ioave i ol i oh 0a a13262
stk672-060-e no.7441-7/19 printed circuit board design recommendations this hybrid ic has two grounds, the pg pins (pins 3 and 4) and the sg pin (pin 22). these are connected internally in the hybrid ic. two power supplies are required: a motor drive supply and a 5v supply for the hybrid ic itself. if the ground connections for these supplies are not good, the motor current waveforms may become unstable, motor noise may increase, and vibration levels may increas e. use appropriate wiring for these gr ounds. here we present two methods for implementing these ground connections. if the grounds for the motor drive supply and the hybrid ic 5v supply are connected in th e immediate vicinity of the power supplies: ? if pg and sg are shorted at the power supply, connect only the pg line to pins 3 and 4 on the hybrid ic. also, be sure that no problems occur due to voltage drops due to common impedances. in the specifications, this must be v cc 2 5%. ? the current waveforms will be more stable if the vref ground is connected to pin 22. ? for initial values, use 100 f or over for c1 and 10 f or over for c2. locate c1 as close to the hybrid ic as possible, and the capacitor ground line must be as short as possible. if the grounds for the motor drive supply and the hybrid ic 5v supply are separated: ? insert a capacitor (c1) of 100 f or over as close as possible to the hybrid ic. the capacitor ground line must be as short as possible. the capacitor c2 may be included if necessary. its ground line should also be as short as possible. sg 3 4 pg stk672-060-e v cc 2 vref clk 7 8 22 14 -- + -- + sg pg c1 + + itf02270 motor drive power supply 5v power supply 100 f or over stepping motor c2 10 f or over oscillator circuit (clk) sg 3 4 pg stk672-060-e v cc 2 vref clk 7 8 22 14 -- + -- + sg pg c1 + + itf02271 separation motor drive power supply 5v power supply 100 f or over stepping motor c2 10 f or over oscillator circuit (clk)
stk672-060-e no.7441-8/19 functional description external excitation chopper drive block description driver block basic circuit structure since this hybrid ic adopts an external excitation method, no external oscillator circuit is required. when a high level is input to � a in the basic driver block circuit shown in the figure and the mosfet is turned on, the comparator + input will go low and the comparator output will go low. since a set signal with the pwm period will be input, the q output will go high, and the mosf et will be turned on as its initial value. the current i on flowing in the mosfet passes through l1 and generates a potential difference in rs. then, when the rs potential and the vref potential become the same, the co mparator output will invert, and the reset signal q output will invert to the low level. then, the mosfet will be turned off and the energy stored in l1 will be induced in l2 and the current i off will be regenerated to the power supply. this state will be maintained until the time when an input to the latch circuit set pin occurs. in this manner, the q output is turned off and on repeatedly by the reset and set signals, thus implementing constant current control. the resistor and capacito r on the comparator input are spike re moval circuit elements and synchronize with the pwm frequency. since this hybrid ic uses a fixed frequency due to the external excitation method and at the same time also adopts a synchronized pwm technique, it ca n suppress the noise associated with holding a position when the motor is locked. input pin functions pin no. symbol function pin circuit type 14 clk phase switching clock built-in pull-up resistor cmos schmitt trigger input 15 cwb rotation direction setting (cw/ccw) built-in pull-up resistor cmos schmitt trigger input 17 return forced phase origin return built-in pull-up resistor cmos schmitt trigger input 18 enable output cutoff built-in pull-up resistor cmos schmitt trigger input 9, 10, 11 m1, m2, m3 excitation mode setting built-in pull-up resistor cmos schmitt trigger input 12, 13 m4, m5 vector locus setting built-in pull-up resistor cmos schmitt trigger input 16 reset system reset built-in pull-up resistor cmos schmitt trigger input 8 vref current setting operational amplifier input itf02272 d1 rs l2 v cc 1 i off l1 � a � a mosfet and q s r 800khz 45khz latch circuit noise filter cr oscillator divider current divider m4 m5 vref a=1 + ? enable � a (control signal) i on
stk672-060-e no.7441-9/19 input signal functions and timing ? clk (phase switching clock) 1) input frequency range: dc to 50khz 2) minimum pulse width: 10 s 3) duty: 40 to 60% (however, the minimum pulse width takes precedence when m3 is high.) 4) pin circuit type: built-in pull-up resistor (20k � , typical) cmos schmitt trigger structure 5) built-in multi-stage noise rejection circuit 6) function: - when m3 is high or open: the phase excited (driven) is advanced one step on each clk rising edge. - when m3 is low: the phase is advanced one step by both rising and falling edges, for a total of two steps per cycle. clk input acquisition timing (m3 = low) ? cwb (method for setting the rotation direction) 1) pin circuit type: built-in pull-up resistor (20k � , typical) cmos schmitt trigger structure 2) function: - when cwb is low: the motor turns in the clockwise direction. - when cwb is high: the motor turns in the counterclockwise direction. 3) notes: when m3 is low, the cwb input must not be changed for about 6.25 s before or after a rising or falling edge on the clk input. ? return (forcible return to the or igin for the currently excited phase) 1) pin circuit type: built-in pull-up resistor (20k � , typical) cmos schmitt trigger structure 2) built-in noise rejection circuit 3) notes: the currently excited (driven) phase can be forcibly moved to the origin by switching this input from low to high. normally, if this input is unused, it must be left open or connected to v cc 2. ? enable (controls the on/off state of the a, a, b, and b excitation drive outputs and sel ects either operating or hold as the internal state of this hybrid ic.) 1) pin circuit type: built-in pull-up resistor (20k � , typical) cmos schmitt trigger structure 2) function: - when enable is high or open: normal operating state - when enable is low: this hybrid ic goes to the hol d state and excitation drive output (motor current) is forcibly turned off. in this mode, the hybrid ic system clock is stopped and no inputs other than the reset input have any effect on the hybrid ic state. excitation counter up/down control output switching timing clk input system clock phase excitation counter clock control output timing a13264
stk672-060-e no.7441-10/19 ? m1, m2, and m3 (excitation mode and clk input edge timing selection) 1) pin circuit type: built-in pull-up resistor (20k � , typical) cmos schmitt trigger structure 2) function: m2 0 0 1 1 m1 m3 0 1 0 1 phase switching clock edge timing 1 2 phase excitation 1-2 phase excitation w1-2 phase excitation 2w1-2 phase excitation rising edge only 0 1-2 phase excitation w1-2 phase excitation 2w1-2 phase excitation 4w1-2 phase excitation rising and falling edges 3) valid mode setting timing: applications must not change the mode in the period 5 s before or after a clk signal rising or falling edge. mode setting acquisition timing ? m4 and m5 (microstepping mode rotation vector locus setting) m4 1 0 1 0 m5 1 0 0 1 mode circular 1 2 3 see page 11 for details on the current division ratio. ? reset (resets all parts of the system.) 1) pin circuit type: built-in pull-up resistor (20k � , typical) cmos schmitt trigger structure 2) function: - all circuit states are set to their initial values by settin g the reset pin low. (note that the pulse width must be at least 10 s.) at this time, the a and b phases are set to their origin , regardless of the excitation mode. the output current goes to about 71% after the reset is released. 3) notes: when power is first applied to this hybrid ic, vref must be established by applying a reset. applications must apply a power on reset when the v cc 2 power supply is first applied. ? vref (sets the current level used as the reference for constant-current detection.) 1) pin circuit type: analog input structure 2) function: - constant-current control can be applied to the motor excitation current at 100% of the rated current by applying a voltage less than the control system power supply voltage v cc 2 minus 2.5v. - applications can apply constant-current control proportiona l to the vref voltage, with this value of 2.5v as the upper limit. phase b phase a circular 3 2 1 itf02273 mode switching timing excitation counter up/down clk input system clock mode setting m1 to m3 mode switching clock hybrid ic internal setting state phase excitation clock a13265
stk672-060-e no.7441-11/19 output pin functions pin no. symbol function pin circuit type 19 moi phase excitation origin monitor standard cmos structure 20, 21 mo1, mo2 phase excitation sta te monitor standard cmos structure output signal functions and timing ? a, a, b, and b (motor phase excitation outputs) 1) function: - in the 4 phase and 2 phase excitation modes, a 3.75 s (typical) interval is set up between the a and a and b and b output signal transition times. ? mo1, mo2, and moi (phase excitation state monitors) 1) pin circuit type: standard cmos structure 1) function: - output of the current phase excitation output state. phase coordinate phase a phase b phase a phase b mo1 1 0 0 1 mo2 0 1 0 1 moi outputs a 0 when each phase is at the origin, and outputs a 1 otherwise. ? current division ratios set by m3, m4, and m5 values provided for reference purposes. mode circular 1 2 3 [load conditions] v cc 1 = 24v, v cc 2 = 5v, r/l = 3.5/3.8mh
stk672-060-e no.7441-12/19 phase states during excitation switching ? excitation phases before and after excita tion mode switching b24 24 27 28 31 3 4 5 8 11 12 15 16 19 20 25 a a a 0 16 17 1 a a b b b24 25 26 27 28 29 30 31 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 24 26 28 30 0 2 4 6 8 10 12 14 16 18 20 22 22 23 a a b b 8 9 12 4 28 20 20 24 28 0 4 8 12 16 b24 26 28 30 a a a 0 16 18 20 22 24 28 0 4 8 12 16 20 20 28 4 12 20 28 4 0 12 16 16 18 20 22 24 25 27 29 31 1 3 5 7 9 23 22 8 24 20 10 26 18 12 16 14 28 30 6 4 2 0 11 21 13 19 15 17 24 28 0 4 8 12 16 20 26 28 30 0 2 4 6 8 10 12 14 2 4 6 b b a b a b 30 2 26 6 10 14 22 18 a b a b a b a b b a a b b 8 10 12 14 12 4 28 20 24 0 8 16 20 22 30 28 4 12 20 14 6 28 4 12 a b a b 29 1 25 5 9 13 21 24 28 0 4 8 12 16 20 17 a b a b 29 5 13 21 28 20 4 12 17 a b a b a1326 6 2w1-2 phase � 2 phase w1-2 phase � 2 phase 1-2 phase � 2 phase 2 phase � 1-2 phase excitation phase developed by the first clk internal pulse after the change in the excitation mode setting with m1 and m excitation phase immediately prior to the excitation mode setting 2w1-2 phase � 1-2 phase w1-2 phase � 1-2 phase 1-2 phase � w1-2 phase 2 phase � w1-2 phase 2 phase � 2w1-2 phase 2w1-2 phase � w1-2 phase w1-2 phase � 2w1-2 phase 1-2 phase � 2w1-2 phase
stk672-060-e no.7441-13/19 ? excitation phases before and after excitation mode switching b24 23 24 25 28 29 0 1 4 5 8 9 12 13 16 17 20 21 a a a 0 16 15 31 a a b b b24 25 26 27 28 29 30 31 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 24 26 28 30 0 2 4 6 8 10 12 14 16 18 20 22 22 23 a a b b 8 7 12 4 28 20 20 24 28 0 4 8 12 16 b24 30 a a a 0 16 22 24 28 0 4 8 12 16 20 20 28 4 12 16 28 24 20 0 4 12 16 18 20 22 24 25 27 29 31 1 3 5 7 9 23 22 8 24 20 10 26 18 12 16 14 28 30 6 4 2 0 11 21 13 19 15 17 24 28 0 4 8 12 16 20 26 28 30 0 2 4 6 8 10 12 14 6 b b a b a b 30 2 26 6 10 14 22 18 a b a b a b a b b a a b b 8 14 12 4 28 20 24 0 8 16 20 26 2 10 28 4 12 20 28 4 12 20 18 28 4 12 a b a b 30 3 27 7 11 15 23 24 28 0 4 8 12 16 20 19 a b a b 27 3 11 19 a b a b a13267 2w1-2 phase � 2 phase w1-2 phase � 2 phase 1-2 phase � 2 phase 2 phase � 1-2 phase 2w1-2 phase � 1-2 phase w1-2 phase � 1-2 phase 1-2 phase � w1-2 phase 2 phase � w1-2 phase 2 phase � 2w1-2 phase 2w1-2 phase � w1-2 phase w1-2 phase � 2w1-2 phase 1-2 phase � 2w1-2 phase
stk672-060-e no.7441-14/19 excitation time and timing charts ? clk rising edge operation itf02274 m1 0 m2 0 m3 reset cwb clk moi mo1 mo2 0 1 m1 1 0 1 0 m2 0 m3 reset cwb clk moi mo2 mo1 m1 1 1 0 m2 0 m3 reset cwb clk moi 0 m1 1 0 1 0 1 0 m2 m3 reset cwb clk moi mosfet gate signal comparator reterence voltage a a b b vref a vref b 100% 71% 100% 71% comparator reterence voltage vref a 100% 92% 71% 40% vref b 100% 92% 71% 40% moi mo2 mo1 comparator reterence voltage vref a 100% 92% 83% 71% 55% 40% 20% moi mo2 mo1 mosfet gate signal a a b b mosfet gate signal comparator reterence voltage a a b b vref a vref b 100% 71% 100% 71% mosfet gate signal a a b b vref b 100% 92% 83% 71% 55% 40% 20% 2 phase excitation timing chart (m3 = 1) 1-2 phase excitation timing chart (m3 = 1) w1-2 phase excitation timing chart (m3 = 1) 2w1-2 phase excitation timing chart (m3 = 1)
stk672-060-e no.7441-15/19 ? clk rising and falling edge operation itf02275 m1 0 m2 0 m3 reset cwb clk mosfet gate signal comparator reterence voltage a a b b moi mo1 mo2 vref a vref b 100% 71% 100% 71% comparator reterence voltage vref a vref b 100% 92% 83% 71% 55% 40% 20% 20% 0 m1 1 0 m2 0 m3 reset cwb clk 0 m1 0 m2 0 1 m3 reset cwb clk moi mo2 mo1 100% 92% 83% 71% 55% 40% comparator reterence voltage vref a 100% 96% 87% 76% 63% 47% 31% 63% 47% 31% 15% 92% 83% 71% 55% 40% 21% 0 m1 1 0 1 0 m2 0 m3 reset cwb clk moi mo2 mo1 0 mosfet gate signal a a b b mosfet gate signal comparator reterence voltage a a b b moi mo2 mo1 vref a vref b 100% 71% 40% 92% 100% 92% 71% 40% mosfet gate signal a a b b vref b 100% 97% 88% 77% 15% 92% 83% 71% 55% 40% 21% 1-2 phase excitation timing chart (m3 = 0) w1-2 phase excitation timing chart (m3 = 0) 2w1-2 phase excitation timing chart (m3 = 0) 4w1-2 phase excitation timing chart (m3 = 0)
stk672-060-e no.7441-16/19 thermal design the main elements internal to this hybrid ic with la rge average power losses are the current control devices, the regenerative current diodes, and the current detection resistor. since sine wave drive is used, the average power loss during microstepping drive can be approximated by applying a waveform factor of 0.64 to the square wave loss during 2 phase excitation. the losses in the various excitation modes are as follows. 2 phase excitation pd 2ex = (vsat+vdf) i oh t2 + (vsat t1+vdf t3) 1-2 phase excitation pd 1-2ex = 0.64 {(vsat+vdf) i oh t2 + (vsat t1+vdf t3)} w1-2 phase excitation pd w1-2ex = 0.64 {(vsat+vdf) i oh t2 + (vsat t1+vdf t3)} 2w1-2 phase excitation pd 2w1-2ex = 0.64 {(vsat+vdf) i oh t2 + (vsat t1+vdf t3)} 4w1-2 phase excitation pd 4w1-2ex = 0.64 {(vsat+vdf) i oh t2 + (vsat t1+vdf t3)} here, t1 and t3 can be determined from the same formulas for all excitation methods. t1 = n (1 ? i oh ) t3 = n ( ) however, the formula for t2 differs with the excitation method. 2 phase excitation t2 = ? (t1+t3) 1-2 phase excitation t2 = ? t1 w1-2 phase excitation t2 = ? t1 2w1-2 phase excitation t2 = ? t1 4w1-2 phase excitation motor phase current model figure (2 phase excitation) fclock : clk input frequency (hz) vsat : the voltage drop of the power mosfet and the current detection resistor (v) vdf : the voltage drop of the body diode and the current detection resistor (v) i oh : phase current peak value (a) t1 : phase current rise time (s) v cc 1 : supply voltage applied to the motor (v) t2 : constant-current operating time (s) l : motor inductance (h) t3 : phase switching current regeneration time (s) r : motor winding resistance ( � ) 2 fclock 2 fclock oh i 4 fclock 4 fclock oh i 8 fclock 8 fclock oh i 16 fclock 16 fclock oh i 16 fclock 16 fclock oh i 0.7 r l + ? 1 cc v 0.7 r + r l ? 0.7 1 cc v r oh i 0.7 1 cc v + + + fclock 2 fclock 3 fclock 7 fclock 15 t3 t1 t2 i oh a13270
stk672-060-e no.7441-17/19 determine � c-a for the heat sink from the average power loss determined in the previous item. tc max: hybrid ic substrate temperature ( c) � c-a = [ c/w] ta: application internal temperature ( c) pd ex : hybrid ic internal average loss (w) determine � c-a from the above formula and then size s (in cm 2 ) of the heat sink from the graphs shown below. the ambient temperature of the device will vary greatly acco rding to the air flow conditions within the application. therefore, always verify that the size of the heat sink is adequate to assure that the hybrid ic back surface (the aluminum plate side) will never exceed a tc max of 105 c, whatever the operating conditions are. next we determine the usage conditions with no heat sink by determining the allowable hybrid ic internal average loss from the thermal resistance of the h ybrid ic substrate, namely 23c/w. for a tc max of 105c at an ambient temperature of 50c pd ex = = 2.3w for a tc max of 105c at an ambient temperature of 40c pd ex = = 2.8w this hybrid ic can be used with no heat sink as long as it is used at operating conditions below the losses listed above. (see � tc ? pd curve in the graph on page 19.) the junction temperature, tj, of each device can be determin ed from the loss pds in each transistor and the thermal resistance � j-c. tj = tc + � j-c pds (c) here, we determine pds, the loss for each transistor, by determining pd ex in each excitation mode. pds = pd ex /4 the steady-state thermal resistance � j-c of a power mosfet is 18 c/w. ex pd ta - max tc 23 50 - 105 23 40 - 105 ic internal average power loss, pd - w � c-a - pd heat sink thermal resistance, � c-a - c/w itf02276 heat sink surface area, s - cm 2 � c-a - s heat sink thermal resistance, � c-a - c/w itf02277 4 0 8 12 16 20 0246810121416 4 0 c 6 0 c g u a r a n t e e d a m b i e n t t e m p e r a t u r e � c-a= tc max -- ta (c/w) tc max=105c pd no. fin 23.0 (c/w) 5 0 c 2 1.0 3 7 5 10 2 10 23 57 100 23 5 no. fin 23.0 (c/w) 2 m m a l p l a t e ( n o s u r f a c e f i n i s h ) ( f l a t b l a c k s u r f a c e f i n i s h ) vertical standing type natural convection air cooling
stk672-060-e no.7441-18/19 fc - v cc 2 pwm frequency, fc - khz supply voltage, v cc 2 - v fc - tc pwm frequency, fc - khz substrate temperature, tc - c vsat - i oh output saturation voltage, vsat - v motor current, i oh - a vdf - i oh motor current, i oh - a fet diode forward voltage, vdf - v i oh - v cc 1 motor current, i oh - a motor supply voltage, v cc 1 - v i oh - tc motor current, i oh - a substrate temperature, tc - c 50 100 200 300 150 250 350 0 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 0 20406080100 10 30 50 70 90 110 10 15 20 25 30 35 40 45 0.2 0.4 0.8 1.2 0.6 1.0 0 0.2 0.4 0.8 1.2 0.6 1.0 0.1 0.3 0.7 1.1 0.5 0.9 0 0.4 0.8 1.2 0.6 1.0 1.4 0.2 0 0.4 1.2 2.0 0.8 1.6 0.2 1.0 1.8 0.6 1.4 0 0.2 0.4 0.6 0.8 1.6 1.0 1.2 1.4 0 0.4 0.8 1.2 1.6 2.0 0.2 0.6 1.0 1.4 1.8 30 35 60 40 45 50 55 0 20 40 60 80 100 140 120 4.0 4.4 4.8 5.2 5.6 6.0 4.2 4.6 5.0 5.4 5.8 itf02280 itf02281 itf02278 itf02279 30 35 60 40 45 50 55 itf02282 itf02284 itf02283 t c = 1 0 5 c v r e f = 0 v vref=0v motor current=0.5a motor current=1.0a motor current=0.5a motor current=1.0a 25 c tc = 2 5 c 1 0 5 c 0 20 40 60 80 100 120 50 100 200 300 400 500 450 150 250 350 0 ivref - tc itf02285 motor current=0.5a motor current=1.0a substrate temperature, tc - c reference voltage input current, ivref - a ivref - vref reference voltage, vref - v reference voltage input current, ivref - a
stk672-060-e no.7441-19/19 ps this catalog provides informati on as of june, 2008. specifications and information herein are subject to change without notice. sanyo semiconductor co.,ltd. assumes no responsibil ity for equipment failures that result from using products at values that exceed, even momentarily, rated v alues (such as maximum ratings, operating condition ranges, or other parameters) listed in products specifications of any and all sanyo semiconductor co.,ltd. products described or contained herein. sanyo semiconductor co.,ltd. strives to supply high-qua lity high-reliability products, however, any and all semiconductor products fail or malfunction with some probab ility. it is possible that these probabilistic failures or malfunction could give rise to accident s or events that could endanger human lives, trouble that could give rise to smoke or fire, or accidents that could cause damage to other property. when designing equipment, adopt safety measures so that these kinds of accidents or events cannot occur. such measures include but are not limited to protective circuits and error prevention circuits for safe design, redundant design, and structural design. upon using the technical information or products described herein, neither warranty nor license shall be granted with regard to intellectual property rights or any other rights of sanyo semiconductor co.,ltd. or any third party. sanyo semiconductor co.,ltd. shall not be liable for any claim or suits with regard to a third party's intellectual property rights which has resulted from the us e of the technical information and products mentioned above. information (including circuit diagrams and circuit par ameters) herein is for example only; it is not guaranteed for volume production. any and all information described or contained he rein are subject to change without notice due to product/technology improvement, etc. when designing equip ment, refer to the "delivery specification" for the sanyo semiconductor co.,ltd. product that you intend to use. in the event that any or all sanyo semiconductor co.,ltd. products described or contained herein are controlled under any of applicable local export control l aws and regulations, such products may require the export license from the authorities concerned in accordance with the above law. no part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, or any information storage or retrieval system, or otherwise, without the prior written consent of sanyo semiconductor co.,ltd. 5 10 20 30 40 15 25 35 012345 10 20 40 60 30 50 70 80 90 0.5 2.0 2.5 3.0 1.0 1.5 10k 1k 23 57 100 23 57 100k 23 57 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 0 0 vref - i oh � tc - pd(typ) itf02286 itf02288 0 � tc - pps itf02287 2 e x 2w1-2ex motor current, i oh - a power dissipation, pd - w clk frequency, pps - hz reference voltage, vref - v substrate temperature rise, � tc - c substrate temperature rise, � tc - c v cc 1=24v, v cc 2=5v dc test motor: pk244-01b r=3.5 � /l=3.3mh no heat sink, motor current=1a
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