LB11922_08

Ordering number : EN7497A Monolithic Digital IC LB11922 Overview For OA Products Three-Phase Brushless Motor Driver The LB11922 is a pre-driver IC designed for constantspeed control of 3-phase brushless motors. It can be used to implement a motor drive circuit with the desired output capacity (voltage, current) by using discrete transistors for the output stage. It implements direct PWM drive for minimal power loss. Features • Direct PWM drive output • Speed discriminator + PLL speed control circuit • Speed lock detection output • Built-in crystal oscillator circuit • Forward/reverse switching circuit • Braking circuit (short braking) • Full complement of on-chip protection circuits, including lock protection, current limiter, and thermal shutdown protection circuits. Specifications Absolute Maximum Ratings at Ta = 25°C Parameter Maximum supply voltage Maximum input current Output current Allowable power dissipation Symbol VCC max IREG max IO max Pd max1 Pd max2 Operating temperature Storage temperature Topr Tstg VREG pin UH, VH, WH, UL, VL, and WL outputs Independent IC When Mounted on the specified PCB Conditions Ratings 8 2 30 0.62 1.36 -20 to +80 -55 to +150 Unit V mA mA W W °C °C * Specified circuit board : 114.3 × 76.1 × 1.6mm3 : glass epoxy board 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 equipment etc.). The products mentioned herein shall not be intended for use for any "special application" (medical equipment whose purpose is to sustain life, aerospace instrument, nuclear control device, burning appliances, transportation machine, traffic signal system, safety equipment etc.) that shall require extremely high level of reliability and can directly threaten human lives in case of failure or malfunction of the product or may cause harm to human bodies, nor shall they grant any guarantee thereof. If you should intend to use our products for applications 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 no consultation or inquiry before the intended use, our customer shall be solely responsible for the use. Specifications of any and all SANYO Semiconductor Co.,Ltd. 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' s products or equipment. 82008 MS PC/41503RM (OT) No.7497-1/15 LB11922 Allowable Operating Conditions at Ta = 25°C Parameter Supply voltage Input current range FG Schmitt output applied voltage FG Schmitt output current Lock detection applied voltage Lock detection output current Symbol VCC IREG VFGS IFGS VLD ILD VREG pin (7V) Conditions Ratings 4.4 to 7.0 0.2 to 1.5 0 to 7 0 to 5 0 to 7 0 to 20 Unit V mA V mA V mA Electrical Characteristics at Ta = 25°C, VCC = 6.3V Parameter Supply current Symbol ICC1 ICC2 ICC3 ICC4 Output saturation voltage 1-1 Output saturation voltage 1-2 Output saturation voltage 2 Hall Amplifier Input bias current Common-mode input voltage range 1 Common-mode input voltage range 2 Hall input sensitivity Hysteresis width Input voltage low → high Input voltage high → low PWM oscillator Output high-level voltage 1 Output high-level voltage 2 Output low-level voltage 1 Output low-level voltage 2 Oscillator frequency Amplitude 1 Amplitude 2 CSD circuit Output high-level voltage 1 Output high-level voltage 2 Output low-level voltage 1 Output low-level voltage 2 External capacitor charge current External capacitor discharge current Oscillator frequency Amplitude 1 Amplitude 2 Crystal Oscillator Operating frequency range Low-level pin voltage High-level pin current Current Limiter Operation Limiter VRF 0.235 0.260 0.285 V fOSC VOSCL IOSCH IOSC = -0.3mA VOSC = VOSCL + 0.3V 3 1.65 0.35 10 MHz V mA VOH (CSD)1 VOH (CSD)2 VOL (CSD)1 VOL (CSD)2 ICHG1 ICHG2 f (RK) V (RK)1 V (RK)2 VCC = 5V C = 0.068μF 2.65 2.1 VCC = 5V VCC = 5V 3.95 3.15 1.1 0.9 -13 8 4.4 3.5 1.4 1.1 -9 12 22 3.0 2.4 3.35 2.65 4.85 3.85 1.7 1.3 -6 16 V V V V μA μA kHz Vp-p Vp-p VOH (PWM)1 VOH (PWM)2 VOL (PWM)1 VOL (PWM)2 f (PWM) V (PWM)1 V (PWM)2 VCC = 5V VCC = 5V C = 560pF 1.4 1.1 VCC = 5V 3.5 2.75 1.8 1.45 3.8 3.0 2.1 1.65 22 1.7 1.35 2.0 1.6 4.1 3.25 2.4 1.9 V V V V kHz Vp-p Vp-p ΔVIN (HA) VSLH VSHL IHB (HA) VICM1 VICM2 When Hall-effect sensors are used When one-side biased inputs are used (Hall-effect IC applications) Sine wave 100 20 9 -25 30 17 -13 50 29 -5 mVp-p mV mV mV -2 0.5 0 -0.1 VCC-2.0 VCC μA V V VO sat1-1 VO sat1-2 VO sat2 In stop mode VCC = 5V VCC = 5V, In stop mode At low level : IO = 400μA At low level : IO = 10mA At high level : IO = -20mA VCC-1.2 Conditions min Ratings typ 22 2.4 21 2.1 0.1 0.8 VCC-0.9 max 30.5 3.4 28 2.9 0.3 1.2 mA mA mA mA V V V Unit Continued on next page. No.7497-2/15 LB11922 Continued from preceding page. Parameter Thermal Shutdown Operation Thermal shutdown operating temperature Hysteresis width VREG Pin VREG pin voltage Low-voltage Protection Circuit Operating voltage Release voltage Hysteresis width FG Amplifier Input offset voltage Input bias current Output high-level voltage 1 Output high-level voltage 2 Output low-level voltage 1 Output low-level voltage 2 FG input sensitivity Schmitt amplitude for the next stage Operating frequency range Open-loop gain Reference voltage FGS Output Output saturation voltage Output low-level voltage Speed Discriminator Output Output high-level voltage Output low-level voltage Speed Control PLL Output Output high-level voltage VOH (P)1 VOH (P)2 Output low-level voltage VOL (P)1 VOL (P)2 Lock Detection Output saturation voltage Output leakage current Lock range Integrator Input offset voltage Input bias current Output high-level voltage 1 Output high-level voltage 2 Output low-level voltage 1 Output low-level voltage 2 Open-loop gain Gain-bandwidth product Reference voltage VB (INT) Design target value * Design target value * -5% VIO (INT) IB (INT) VOH (INT)1 VOH (INT)2 VOL (INT)1 VOL (INT)2 IINTI = -0.1mA, No load IINTI = -0.1mA, No load, VCC = 5V IINTI = 0.1mA, No load IINTI = 0.1mA, No load, VCC = 5V Design target value * -10 -0.4 4.1 3.45 1.2 1.1 45 4.4 3.7 1.4 1.3 51 1.0 VCC/2 5% +10 +0.4 4.7 3.95 1.65 1.5 mV μA V V V V dB MHz V VOL (LD) IL (LD) ILD = 10mA VO = VCC -6.25 0.25 0.4 10 +6.25 V μA % VCC = 5V VCC = 5V 4.05 3.25 1.85 1.25 4.30 3.50 2.15 1.60 4.65 3.85 2.45 1.85 V V V V VOH (D) VOL (D) VCC-1.0 VCC-0.7 0.8 1.1 V V VO (FGS) IL (FGS) IO (FGS) = 2mA VO = VCC 0.2 0.4 10 V μA VB (FG) f (FG) = 2kHz 45 -5% 51 VCC/2 5% VIO (FG) IB (FG) VOH (FG)1 VOH (FG)2 VOL (FG)1 VOL (FG)2 IFGI = -0.1mA, No load IFGI = -0.1mA, No load, VCC = 5V IFGI = 0.1mA, No load IFGI = 0.1mA, No load, VCC = 5V Gain : 100 × -10 -1 4.2 3.6 1.3 0.7 3 100 180 250 2 4.6 3.95 1.7 1.05 +10 +1 5.0 4.3 2.1 1.4 mV μA V V V V mV mV kHz dB V VSDL VSDH ΔVSD 3.55 3.85 0.18 3.75 4.03 0.28 4.00 4.25 0.38 V V V VREG I = 500μA 6.6 7.0 7.4 V ΔTSD Design target value * 30 °C TSD Design target value * 150 180 °C Symbol Conditions min Ratings typ max Unit Note : * These items are design target values and are not tested. Continued on next page. No.7497-3/15 LB11922 Continued from preceding page. Parameter S/S Pin Input high-level voltage Input low-level voltage Input open voltage Hysteresis width Input high-level current Input low-level current Pull-up resistance F/R Pin Input high-level voltage Input low-level voltage Input open voltage Hysteresis width Input high-level current Input low-level current Pull-up resistance BR Pin Input high-level voltage Input low-level voltage Input open voltage Hysteresis width Input high-level current Input low-level current Pull-up resistance N Pin Input high-level voltage Input low-level voltage Input open voltage Hysteresis width Input high-level current Input low-level current Pull-up resistance VIH (N) VIL (N) VIO (N) ΔVIN (N) IIH (N) IIL (N) RU (N) VCC = 6.3V, 5V, Design target value * VN = VCC VN = 0V VCC = 6.3V, 5V VCC = 6.3V, 5V 2.0 0 VCC-0.5 0.13 -10 -170 37 0.22 0 -118 53.5 70 VCC 1.0 VCC 0.31 +10 V V V V μA μA kΩ VIH (BR) VIL (BR) VIO (BR) ΔVIN (BR) IIH (BR) IIL (BR) RU (BR) VCC = 6.3V, 5V VBR = VCC VBR = 0V VCC = 6.3V, 5V VCC = 6.3V, 5V 2.0 0 VCC-0.5 0.13 -10 -170 37 0.22 0 -118 53.5 70 VCC 1.0 VCC 0.31 +10 V V V V μA μA kΩ VIH (F/R) VIL (F/R) VIO (F/R) ΔVIN (F/R) IIH (F/R) IIL (F/R) RU (F/R) VCC = 6.3V, 5V VF/R = VCC VF/R = 0V VCC = 6.3V, 5V VCC = 6.3V, 5V 2.0 0 VCC-0.5 0.13 -10 -170 37 0.22 0 -118 53.5 70 VCC 1.0 VCC 0.31 +10 V V V V μA μA kΩ VIH (S/S) VIL (S/S) VIO (S/S) ΔVIN (S/S) IIH (S/S) IIL (S/S) RU (S/S) VCC = 6.3V, 5V VS/S = VCC VS/S = 0V VCC = 6.3V, 5V VCC = 6.3V, 5V 2.0 0 VCC-0.5 0.13 -10 -170 37 0.22 0 -118 53.5 70 VCC 1.0 VCC 0.31 +10 V V V V μA μA kΩ Symbol Conditions min Ratings typ max Unit Note : * These items are design target values and are not tested. Package Dimensions unit : mm (typ) 3247A 1.6 Pd max -- Ta Specified board : 114.3×76.1×1.6mm3 glass epoxy 36 19 Allowable power dissipation, Pd max – W 1.36 1.2 5.6 1 0.3 18 0.2 0.5 7.6 0.8 0.62 0.76 Independent IC 1.7max 15.0 (1.5) 0.4 0.35 0.1 (0.7) 0.8 0 – 20 0 20 40 60 80 100 Ambient temperature, Ta – °C SANYO : SSOP36(275mil) No.7497-4/15 LB11922 Pin Assignment RFGND FGIN+ 20 17 IN1+ GND IN2- IN3- WH UH 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 LB11922 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 FGIN19 18 Top view Condition Brake Released IN2+ IN3+ VCC IN1- WL VH LD DOUT POUT INT.OUT INT.IN PWM CSD FGS RF VL UL XI Speed Discriminator Counts N High or open Low Number of counts 512 1024 fFG = fOSC ÷ (16 × ) Three-Phase Logic Truth Table (A high (H) input is the state where IN+ > IN-.) Item 1 2 3 4 5 6 F/R = L IN1 H H H L L L IN2 L L H H H L IN3 H L L L H H IN1 L L L H H H F/R = H IN2 H H L L L H IN3 L H H H L L PWM VH WH WH UH UH VH Output UL UL VL VL WL WL S/S pin Input condition High or open Low Condition Stop Start BRK pin Input condition High or open Low FGOUT No.7497-5/15 VREG S/S XO F/R NC NC BR N FGO FGS DOUT LD POUT INT IN INT OUT S/S BR VCC FR Block Diagram FGINFG FILTER LD VCC – + FG RST Speed discriminator BR CSD OSC F/R – – FGIN+ + + CSD IN1+ IN1IN2+ HALL HYS AMP S/S LOGIC IN2IN3+ IN3- LB11922 Speed control system PLL 1.3VREF VREG ECL 1/16 1/N LVSD VREG COMP LOGIC TSD X tal OSC N PWM OSC CURR LIM PRI DRIVER XI XO N GND PWM RFGND RF UL VL WL UH VH WH No.7497-6/15 LB11922 Pin Functions Pin No. 1 Pin name VREG Function 7V shunt regulator output. Equivalent circuit 1 VCC 2 S/S Start/stop control. Low : 0 to 1.0V High : 2.0V to VCC Goes high when left open. Low for start. High or open for stop. The hysteresis is about 0.22V. VCC 50kΩ 3.5kΩ 2 3 F/R Forward/reverse control. Low : 0 to 1.0V High : 2.0V to VCC Goes high when left open. Low for forward. High or open for reverse. The hysteresis is about 0.22V. VCC 50kΩ 3.5kΩ 3 4 BR Brake control (short braking operation). Low : 0 to 1.0V High : 2.0V to VCC Goes high when left open. High or open for brake mode operation. The hysteresis is about 0.22V. VCC 50kΩ 3.5kΩ 4 5 N Speed discriminator count switching. Low : 0 to 1.0V High : 2.0V to VCC Goes high when left open. The hysteresis is about 0.22V. VCC 50kΩ 3.5kΩ 5 Continued on next page. No.7497-7/15 LB11922 Continued from preceding page. Pin No. 6 Pin name FGS Function FG amplifier output (after the Schmitt circuit). This is an open collector output. Equivalent circuit VCC 6 7 LD Speed lock detection output. Goes low when the motor speed is within the speed lock range (±6.25%). VCC 7 8 DOUT Speed discriminator output. Acceleration → high, deceleration → low VCC 8 9 POUT Speed control system PLL output. Outputs the phase comparison result for CLK and FG. VCC 9 10 INT IN Integrating amplifier inverting input. VCC 500Ω 30kΩ 500Ω 10 30kΩ Continued on next page. No.7497-8/15 LB11922 Continued from preceding page. Pin No. 11 Pin name INT OUT Function Integrating amplifier output (speed control). Equivalent circuit VCC 11 12 PWM PWM oscillator frequency setting. Connect a capacitor between this pin and ground. VCC 40kΩ 300Ω 7.5kΩ 12 13 CSD Sets the operating time of the constrained-rotor protection circuit. Reference signal oscillator used when the clock signal is cut off and to prevent malfunctions. The protection function operating time can be set by connecting a capacitor between this pin and ground. This pin also functions as the logic circuit block power-on reset pin. VCC Reset circuit 300Ω 13 15 16 XO XI Oscillator circuit connections. XO : Output pin XI : Input pin A reference clock can be generated by connecting an oscillator element to these pins. If an external clock with a frequency of a few MHz is used, input that signal through a series resistor of about 5.1kΩ. The XO pin must be left open in this case. VCC 15 16 18 FGOUT FG amplifier output. This pin is connected to the FG Schmitt comparator circuit internally in the IC. VCC 18 40kΩ FG Schmitt comparator Continued on next page. No.7497-9/15 LB11922 Continued from preceding page. Pin No. 19 20 Pin name FGINFGIN+ Function FG amplifier inputs. FGIN- : FG amplifier inverting input FGIN+ : FG amplifier noninverting input Insert capacitors between these pins (which have a potential of 1/2 VCC) and ground. Equivalent circuit VCC 500Ω FGOUT 20 500Ω 30kΩ 500Ω 19 21 RFGND Output current detection. Connect a resistor between this pin and ground. 21 22 RF Output current detection. Connect a resistor between this pin and ground. The output limitation maximum current, IOUT, is set to be 0.26/Rf by this resistor. 30kΩ VCC VCC 22 23 24 25 26 27 28 29 GND UL UH VL VH WL WH Ground connection. Outputs (that are used to drive external transistors). These are push-pull outputs. The PWM duty is controlled on the UH, VH, and WH side of these outputs. VCC 24 26 28 50kΩ Power-supply voltage. Connect a capacitor between this pin and ground for power supply stabilization. Hall-effect device inputs. The input is seen as a high-level input when IN+ > IN-, and as a low-level input for the opposite state. If noise on the Hall-effect device signals is a problem, insert capacitors between the corresponding IN+ and IN- inputs. The logic high state indicates that VIN+ > VIN-. 25 27 29 30 VCC 31 32 33 34 35 36 IN3IN3+ IN2IN2+ IN1IN1+ VCC 32 34 36 500Ω 500Ω 31 33 35 14 17 NC These are unconnected pins, and can be used for wiring. No.7497-10/15 LB11922 Sample Application Circuit 1 (P-channel + n-channel, Hall-effect sensor application) 24V 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 WL IN1+ IN2+ IN1- IN2- WH RF LB11922 INT.OUT INT.IN FGOUT 18 VREG DOUT POUT PWM CSD FGS S/S F/R XO NC RFGND 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 S/S F/R BR N FGS LD Sample Application Circuit 2 (PNP + NPN, Hall-effect sensor application) + 24V + 36 IN1+ 35 IN1- 34 IN2+ 33 IN2- 32 IN3+ 31 IN3- 30 VCC 29 WH 28 WL 27 VH 26 VL 25 UH 24 UL 23 GND 22 RF 21 RFGND 20 FGIN+ NC BR LD XI N FGIN+ 19 FGIN- LB11922 INT.OUT INT.IN FGOUT VREG DOUT POUT PWM CSD FGS S/S F/R XO NC 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 NC BR LD XI N 18 S/S F/R BR N FGS LD FGIN- IN3+ IN3- GND VCC VL VH UH UL No.7497-11/15 LB11922 LB11922 Description 1. Speed Control Circuit This IC implements speed control using the combination of a speed discriminator circuit and a PLL circuit. The speed discriminator circuit outputs (This counts a single FG period.) an error signal once every two FG periods. The PLL circuit outputs an error signal once every one FG Period. As compared to the earlier technique in which only a speed discriminator circuit was used, the combination of a speed discriminator and a PLL circuit allows variations in motor speed to be better suppressed when a motor that has large load variations is used. The FG servo frequency (fFG) is controlled to have the following relationship with the crystal oscillator frequency (fOSC). fFG = fOSC ÷ (16 × ) N High or open Low Number of counts 512 1024 Therefore it is possible to implement half-speed control without switching the clock frequency by using combinations of the N1 = high, N2 = low state and other setting states. 2. Reference Clock This IC supports the use of either of the following methods for providing the speed control reference clock. (1) Crystal oscillator Use a circuit consisting of a crystal and capacitors such as the one shown below to implement a crystal oscillator. XI C3 XO C1 C2 C1 : Used to prevent oscillation at upper harmonic frequencies. C2 : Used for stabilization and to prevent oscillation at upper harmonic frequencies. C3 : Used for oscillator coupling. Oscillator frequency (MHz) 3 to 5 5 to 8 8 to 10 C1 (pF) 39 10 5 C2 (pF) 10 10 10 C3 (pF) 47 47 22 (Values provided for reference purposes) This circuit and these component values are only provided for reference purposes. When implementing a crystal oscillator in an application, it is necessary to consult the manufacturer of the crystal to verify that problems will not occur due to interactions between stray capacitances due to wiring in the PCB and the crystal. Notes : The capacitor C1 is effective at lowering negative resistance values at high frequencies, but care is required to assure that it does not excessively reduce the negative resistance at the fundamental frequency. Since this crystal oscillator circuit is a high-frequency circuit, it can be easily influenced by stray capacitances on the PCB. To minimize stray capacitances, keep connections between external components as short as possible and use narrower line widths in the PCB patter. The C1 and C2 ground lines must be as short as possible, and must be connected to the IC's ground pin (pin 23, GND). If the PCB lines are excessively long, the oscillator circuit may be influenced by fluctuations in the ground line voltage when, for example, the motor is overloaded, and the oscillator frequency may change. The C1 and C2 ground lines can be made shorter by using the NC pins next to the XI and XO pins for the C1 and C2 ground, and connecting those pins across the back of the IC to the IC GND pin. No.7497-12/15 LB11922 (2) External clock (A frequency equivalent to that of the crystal oscillator circuit : a few MHz) If a signal from an external signal source with a frequency equivalent to that of the crystal oscillator circuit is used, input that signal to the IC through a series resistor (example value : 5.1kΩ). In this case, the XO pin must be left open. Input signal levels (signal source) Low-level voltage : 0 to 0.8V High-level voltage : 2.5 to 5.0V 3. Output Drive Circuit To reduce power loss in the output, this IC adopts the direct PWM drive technique. The output transistors (which are external to the IC) are always saturated when on, and the motor drive output is adjusted by changing the duty with which the output is on. The PWM switching is performed on the high side for each phase (UH, VH, and WH). The PWM switching side in the output can be selected to be either the high or low side depending on how the external transistors are connected. 4. Current Limiter Circuit The current limiter circuit limits the (peak) current at the value I = VRF/Rf (VRF = 0.26V (typical), Rf : current detection resistor). The current limitation operation consists of reducing the output duty to suppress the current. High accuracy detection can be achieved by connecting the RF and RFGND pin lines near the ends of the current detection resistor (Rf). 5. Speed Lock Range The speed lock range is ±6.25% of the fixed speed. When the motor speed is in the lock range, the LD pin (an open collector output) goes low. If the motor speed goes out of the lock range, the motor on duty is adjusted according to the speed error to control the motor speed to be within the lock range. 6. Notes on the PWM Frequency The PWM frequency is determined by the capacitor (F) connected to the PWM pin. When VCC = 6.3V : fPWM ≈ 1/(82000 × C) When VCC = 5.0V : fPWM ≈ 1/(66000 × C) A PWM frequency of between 15 and 25kHz is desirable. If the PWM frequency is too low, the motor may resonate at the PWM frequency during motor control, and if that frequency is in the audible range, that resonation may result in audible noise. If the PWM frequency is too high, the output transistor switching loss will increase. To make the circuit less susceptible to noise, the connected capacitors must be connected to the GND pin (pin 23) with lines that are as short as possible. 7. Hall effect sensor input signals An input amplitude of over 100mVp-p is desirable in the Hall effect sensor inputs. The closer the input waveform is to a square wave, the lower the required input amplitude. Inversely, a higher input amplitude is required the closer the input waveform is to a triangular wave. Also note that the input DC voltage must be set to be within the commonmode input voltage range. If noise on the Hall inputs is a problem, that noise must be excluded by inserting capacitors across the inputs. Those capacitors must be located as close as possible to the input pins. When the Hall inputs for all three phases are in the same state, all the outputs will be in the off state. If a Hall sensor IC is used to provide the Hall inputs, those signals can be input to one side (either the + or - side) of the Hall effect sensor signal inputs as 0 to VCC level signals if the other side is held fixed at a voltage within the common-mode input voltage range that applies when a Hall effect sensors are used. No.7497-13/15 LB11922 8. Forward/Reverse Switching The motor rotation direction can be switched using the F/R pin. However, the following notes must be observed if the motor direction is switched while the motor is turning. • This IC is designed to avoid through currents when switching directions. However, increases in the motor supply voltage (due to instantaneous return of motor current to the power supply) during direction switching may cause problems. The values of the capacitors inserted between power and ground must be increased if this increase is excessive. • If the motor current after direction switching exceeds the current limit value, the PWM drive side outputs will be turned off, but the opposite side output will be in the short-circuit braking state, and a current determined by the motor back EMF voltage and the coil resistance will flow. Applications must be designed so that this current does not exceed the ratings of the output transistors used. (The higher the motor speed at which the direction is switched, the more severe this problem becomes.) 9. Brake Switching The LB11922 provides short-circuit braking implemented by turning the output transistors for the high side for all phases (UH, VH, and WH) on. (The opposite side transistors are turned off for all phases.) Note that the current limiter does not operate during braking. During braking, the duty is set to 100%, regardless of the motor speed. The current that flows in the output transistors during braking is determined by the motor back EMF voltage and the coil resistance. Applications must be designed so that this current does not exceed the ratings of the output transistors used. (The higher the motor speed at which braking is applied, the more severe this problem becomes.) The braking function can be applied and released with the IC in the start state. This means that motor startup and stop control can be performed using the brake pin with the S/S pin held at the low level (the start state). 10. Constraint Protection Circuit The LB1922M includes an on-chip constraint protection circuit to protect the IC and the motor in motor constraint mode. If the LD output remains high (indicating the locked state) for a fixed period in the start state, the upper side (external) transistors are turned off. This time is set by the capacitance of the capacitor attached to the CSD pin. When VCC = 6.3V : The set time (in seconds) is 74 × C (μF) When VCC = 5.0V : The set time (in seconds) is 60 × C (μF) To clear the rotor constrained protection state, the application must either switch to the stop state for a fixed period (about 1ms or longer) or turn off and reapply power. If the rotor constrained protection circuit is not used, a 220kΩ resistor and a 1500pF capacitor must be connected in parallel between the CSD pin and ground. Since the CSD pin also functions as the power-on reset pin, if the CSD pin were connected directly to ground, the IC would go to the power-on reset state and motor drive operation would remain off. The power-on reset state is cleared when the CSD pin voltage rises above a level of about 0.64V. 11. Low-Voltage Protection Circuit The LB11922 includes a low-voltage protection circuit to protect against incorrect operation when power is first applied or if the power-supply voltage (VCC) falls. The (external) upper side output transistors are turned off if VCC falls under about 3.75V (tpyical), and this function is cleared at about 4.0V (typical). 12. Power Supply Stabilization Since this IC is used in applications that draw large output currents, the power-supply line is subject to fluctuations. Therefore, capacitors with capacitances adequate to stabilize the power-supply voltage must be connected between the VCC pin and ground. If diodes are inserted in the power-supply line to prevent IC destruction due to reverse power supply connection, since this makes the power-supply voltage even more subject to fluctuations, even larger capacitors will be required. 13. Ground Lines The signal system ground and the output system ground must be separated and a single ground point must be taken at the connector. Since the output system ground carries large currents, this ground line must be made as short as possible. Output system ground ... Ground for Rf and the output diodes Signal system ground ... Ground for the IC and the IC external components No.7497-14/15 LB11922 14. VREG Pin If a motor drive system is formed from a single power supply, the VREG pin (pin 1) can be used to create the powersupply voltage (about 6.3V) for this IC. The VREG pin is a shunt regulator and generates a voltage of about 7V by passing a current through an external resistor. A stable voltage can be generated by setting the current to value in the range 0.2 to 1.5mA. The external transistors must have current capacities of at least 80mA (to cover the ICC + Hall bias current + output current requirements) and they must have voltage handling capacities in excess of the motor power-supply voltage. Since the heat generated by these transistor may be a problem, heat sinks may be required depending on the packages used. If the IC power-supply voltage (4.4 to 7.0V) is provided from an external circuit, apply that voltage directly to the VCC pin (pin 30). In that case, the VREG pin must either be left open or connected to ground. 15. FG Amplifier The FG amplifier is normally implemented as a filter amplifier such as that shown in the application circuits to reject noise. Since a clamp circuit has been added at the FG amplifier output, the output amplitude is clamped at about 3Vp-p, even if the gain is increased. Since a Schmitt comparator is inserted after the FG amplifier, applications must set the gain so that the amplifier output amplitude is at least 250mVp-p. (It is desirable that the gain be set so that the amplitude is over 0.5Vp-p at the lowest controlled speed to be used.) The capacitor inserted between the FGIN+ pin (pin 20) and ground is required for bias voltage stabilization. To make the connected capacitor as immune from noise as possible, connect this capacitor to the GND pin (pin 23) with a line that is as short as possible. 16. Integrating Amplifier The integrating amplifier integrates the speed error pulses and the phase error pulses and converts them to a speed command voltage. At the same time it also sets the control loop gain and frequency characteristics using external components. 17. NC pin Since the NC pins are electrically open with respect to the IC itself, they can be used as intermediate connection points for lines in the PCB pattern. SANYO Semiconductor Co.,Ltd. assumes no responsibility for equipment failures that result from using products at values that exceed, even momentarily, rated values (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-quality high-reliability products, however, any and all semiconductor products fail or malfunction with some probability. It is possible that these probabilistic failures or malfunction could give rise to accidents 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. 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 laws 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. Any and all information described or contained herein are subject to change without notice due to product/technology improvement, etc. When designing equipment, refer to the "Delivery Specification" for the SANYO Semiconductor Co.,Ltd. product that you intend to use. Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed for volume production. 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 intellctual property rights which has resulted from the use of the technical information and products mentioned above. This catalog provides information as of August, 2008. Specifications and information herein are subject to change without notice. PS No.7497-15/15