Ordering number : EN8321B Monolithic Digital IC LB11600JV Brushless Motor Predriver IC for Automotive Applications Overview The LB11600JV is a direct PWM drive predriver IC appropriate for 3-phase power brushless motors in automotive applications. This IC can implement either high side PWM drive or low side PWM drive motor driver circuits depending on the configuration of the output circuits, which use discrete transistors such as MOSFETs or bipolar transistors. In addition to a full complement of protection functions, including overcurrent, thermal, motor constraint, and undervoltage protection, the LB11600JV also provides an integrated speed control function. Thus the LB11600JV can implement high reliability/high functionality drive circuits. Functions • Three-phase bipolar drive (UH, VH, and WH pins, PWM control) • Forward/reverse switching circuit • Overcurrent protection circuit • Undervoltage protection circuit • Motor constraint protection circuit • Thermal protection circuit • Speed control circuit Specifications Absolute Maximum Ratings at Ta = 25°C Parameter Supply voltage Symbol VCC max Conditions VCC Pin Rated value Unit 14.5 V Output Circuit current IO max UL, VL, WL, UH, VH, and WH pins 40 mA Allowable power dissipation Pd max Independent IC 0.5 W Operating temperature Topr -40 to 100 °C Storage temperature Tstg -55 to 150 °C 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. 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 new introduction or other application different from current conditions on the usage of automotive device, communication device, office equipment, industrial equipment etc. , please consult with us about usage condition (temperature, operation time etc.) 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. 82511 SY/D2706 MS IM 20060831-S00005 / 92706 / D0205 MH OT B8-8935 No.8321-1/30 LB11600JV Allowable Operating Ranges at Ta = 25°C Parameter Symbol VCC voltage supply voltage range VCC Output current VCC op Conditions Rated value VCC Pin Unit 4.5 to 14 UL, VL, WL, UH, VH, and WH pins 30 V mA RF pin voltage VRF 0 to 3 V HP pin voltage VHP 0 to 14 V HP pin voltage IHP 0 to 10 mA Electrical Characteristics at Ta = 25°C, VCC = 5V Rated value Parameter Symbol Conditions Unit Min. Typ. Max. Current drain 1 ICC1 S/S = 0V 13 20 27 mA Current drain 2 ICC2 Stop mode, S/S = 5V 1.5 2.5 3.5 mA Output voltage 1-1 VOUT1-1 Low level, IO = 400µA 0.1 0.3 V Output voltage 1-2 VOUT1-2 Low level, IO = 10mA 0.8 1.1 V VOUT2 High level, IO = -20mA Output Block Output voltage 2 VCC-1.1 VCC-0.9 -2 -0.5 V Hall Amplifier Block Input bias current Common-mode input IHB (HA) VICM1 When a Hall effect element is used μA 0.5 VCC-2.0 V 0 VCC V voltage range 1 Common-mode input VICM2 voltage range 2 When a single-sided input bias is used (Hall IC applications) Hall input sensitivity 80 mVP-P Hysteresis ΔVIN (HA) 15 24 40 mV Input voltage (low → high) VSLH (HA) 5 12 20 mV Input voltage (high → low) VSHL (HA) -20 -12 -5 mV TOC Pin Input voltage 1 VTOC1 Output duty: 100% 2.72 3.0 3.30 V Input voltage 2 VTOC2 Output duty: 0% 1.15 1.35 1.55 V Input voltage 1L VTOC1L When VCC = 4.7V Output duty: 100% 2.5 2.80 3.1 V Input voltage 2L VTOC2L When VCC = 4.7V, Output duty: 0% 1.05 1.24 1.43 V Input voltage 1H VTOC1H When VCC = 5.3V, Output duty: 100% 2.88 3.20 3.52 V Input voltage 2H VTOC2H When VCC = 5.3V, Output duty: 0% 1.17 1.38 1.59 V CTL Pin Input offset voltage Input bias current Common-mode input VIO (CONT) -10 10 mV IB (CONT) -1 1 μA VICM 0 VCC-1.7 V voltage range High-level output voltage VOH (CONT) ITOC = -0.2mA Low-level output voltage VOL (CONT) ITOC = 0.2mA VCC-1.1 VCC-0.8 V 0.8 1.1 V V PWM Oscillator (PWM pin) High-level output voltage VOH (PWM) 2.75 3.0 3.25 Low-level output voltage VOL (PWM) 1.2 1.35 1.5 V External capacitor charge 1CHG PWM = 2.1V -60 -45 -30 μA F (PWM) C = 1000pF current Oscillator frequency Amplitude Vp-p (PWM) 20 25 30 kHz 1.25 1.65 2.05 VP-P 0.15 0.5 V 10 μA HP Pin Output saturation voltage Output leakage current VHPL IHPleak IO = 7mA VO = 13.5V Continued on next page. No.8321-2/30 LB11600JV Continued from preceding page. Rated value Parameter Symbol Conditions Unit Min. Typ. Max. Motor Constraint Protection Circuit Block (CSD and CSET pins) CSD saturation voltage CSD off voltage VSCSD I0 = -0.5mA, VCC-VCSD VCSDOF 0.1 0.3 V 0.55 0.6 0.65 V 65 μA CSD voltage VCSD CSET = 4.9V 4.7 4.9 CSET pin current ICSET CSET = 4.8V 35 50 0.1 0.3 V 0.6 0.7 0.85 V 0.216 0.24 0.264 V -60 -40 -20 μA CSET pin on voltage VCSETON VCC - CSET pin CSET pin off voltage VCSETOFF VCC - CSET pin V Current Limiter Circuit (RF pin) Limiter voltage RFGND pin current VRF IRFGND RFGND = 0V Undervoltage Protection Circuit Operating voltage VSDL 3.6 3.8 4.0 V Release voltage VSDH 4.1 4.3 4.5 V Hysteresis ΔVSD 0.35 0.5 0.65 V 150 170 °C 25 °C Thermal Shutdown Circuit (thermal protection circuit) Thermal shutdown TSD Design target value (junction temperature)* ΔTSD Design target value (junction temperature)* ICEG CEG = 4.8V temperature Hysteresis CEG Pin CEG pin current CEG pin on voltage VCEGON VCC - CSET pin CEG pin off voltage VCEGOFF VCC - CSET pin 35 0.6 50 65 μA 0.1 0.3 V 0.7 0.85 V CR Pin High-level output voltage VOH (CR) 3.12 3.4 3.68 V Low-level output voltage VOL (CR) 0.67 0.75 0.83 V Clamp voltage VCLP (CR) 1.3 1.45 1.6 V FV Pin Charge current ICHG1 FV = 2.5V -420 -300 -230 μA Discharge current ICHG2 FV = 1V 1.3 2.5 5.0 mA FV pin high-level voltage VOFVH IO = -200μA 4.7 FV pin low-level voltage VOFVL IO = 200μA 0.3 V 1.0 V VCC V 4.9 0.15 V S/S Pin High-level input voltage VIH(SS) Low-level input voltage VIL(SS) 2.0 V Input open voltage VIO(SS) Hysteresis VIS(SS) 0.2 0.3 0.4 V High-level input current IIH(SS) S/S = 5V -10 0 10 μA Low-level input current IIL(SS) S/S = 0V -130 -96 VCC-0.5 μA F/R Pin High-level input voltage VIH (FR) Low-level input voltage VIL (FR) 2.0 V Input open voltage VIO (FR) Hysteresis VIS (FR) 0.2 0.3 0.4 V High-level input current IIH (FR) F/R = 5V -10 0 10 μA Low-level input current IIL (FR) F/R = 0V -130 -96 VCC-0.5 1.0 V VCC V μA *: These are design target value and are not tested. Continued on next page. No.8321-3/30 LB11600JV Continued from preceding page. Rated value Parameter Symbol Conditions Unit Min. Typ. Max. PWMIN Pin High-level input voltage VIH (PWMIN) Low-level input voltage VIL (PWMIN) 2.0 V Input open voltage VIO (PWMIN) VCC-0.5 VCC V Hysteresis VIS (PWMIN) 0.2 0.3 0.4 V High-level input current IIH (PWMIN) PWMIN = 5V -10 0 10 μA Low-level input current IIL (PWMIN) PWMIN = 0V -130 -96 Input frequency F (PWMIN) 50 kHz 1.0 V μA PWMRE Pin PWMRE pin current -260 -200 -140 μA PWMRETH 1.12 1.25 1.38 V PWMREHYS 0.44 0.7 1.1 V IPWMIRE Threshold voltage Hysteresis PWMRE = 0V Package Dimensions unit : mm (typ) 3191C 9.75 0.5 5.6 7.6 30 1 0.65 0.15 0.22 1.5 MAX 0.1 (1.3) (0.33) SANYO : SSOP30(275mil) Pin Assignment WL WH RF 30 29 28 RFGND GND 27 26 S/S VCC 25 24 PWMIN PWMRE CSET CSD PWM TOC CTL- CTL+ 22 21 20 19 18 17 16 9 IN3+ 10 IN3- 11 F/R 12 HP 13 CEG 14 CR 15 FV 23 LB11600JV 1 VH 2 VL 3 UH 4 UL 5 IN1+ 6 IN1- 7 IN2+ 8 IN2- Top view No.8321-4/30 LB11600JV Block Diagram and Application Circuit 1 : MOS transistor drive (low side PWM), speed control feedback application No.8321-5/30 LB11600JV Application Circuit 2: Bipolar transistor (high side PWM) No.8321-6/30 LB11600JV Truth Table • Three-Phase Logic Truth Table (IN = H means that the input is in the IN+ > IN- state.) F/R=[L] F/R=[H] Output IN1 IN2 IN3 IN1 IN2 IN3 PWM Fixed 1 H L H L H L VH UL 2 H L L L H H WH UL 3 H H L L L H WH VL 4 L H L H L H UH VL 5 L H H H L L UH WL 6 L L H H H L VH WL When F/R is low, the IC recognizes the states where the Hall inputs in the above table occur in the order 1 → 6 as forward rotation, and the reverse order as reverse rotation. When F/R is high, the IC recognizes the states where the Hall inputs in the above table occur in the order 6 → 1 as forward rotation, and the reverse order as reverse rotation. • S/S Pin Input state Operating state High or open Stop state L Start state If the S/S pin is not used, the input must be held at the low-level voltage. No.8321-7/30 LB11600JV Pin Functions Pin Number Function Function 1 VH Outputs. These are push-pull 2 VL outputs. 3 UH Duty control is applied to the 4 UL UH, VH, and WH pins. Internal 29 WH 50kΩ leakage protection 30 WL resistors between the outputs Equivalent circuit VCC UH, VH, WH 50kΩ and ground are provided to protect against output leakage in standby mode. 5 IN1+ Hall effect sensor inputs from 6 IN1- each motor phase. 7 IN2+ The logic high state 8 IN2- corresponds to the state where 9 IN3+ IN+ > IN-. If input is provided 10 IN3- from a Hall IC, the common mode input range can be 1 3 29 2 4 30 UL, VL, WL VCC IN+ 5 7 9 300Ω 300Ω 6 IN8 10 expanded by biasing either the + or - input. 11 F/R Forward/reverse switching VCC 50kΩ input. 3.5kΩ F/R 11 12 HP Hall signal single-phase output. (This pin is an VCC HP open-collector output.) This pin 12 outputs a signal that is inverted from the signal formed from the IN3 input. 13 CEG Rotation pulse edge detection input. (This input is used by the VCC VCC 24 one-shot multivibrator circuit.) Insert a capacitor between this pin and VCC. CEG 300Ω 13 Continued on next page. No.8321-8/30 LB11600JV Continued from preceding page. Pin Number 14 Function CR Function One-shot multivibrator pulse width setting. Equivalent circuit VCC VCC 24 Insert a resistor between this pin and VCC and a capacitor between this pin and ground. If unused: short to ground. CR 300Ω 14 15 FV Hall signal one-shot multivibrator output. VCC If unused: leave open. FV 300Ω 15 16 CTL+ CTL+: Control voltage input 17 CTL- (Integrating amplifier noninverting input) VCC CTL-: Control voltage input (Integrating amplifier inverting input) CTL+ CTL- 300Ω 300Ω 16 PWM waveform comparator (Integrating amplifier output) VCC TOC 18 PWM pin 300Ω 38Ω 38Ω TOC 40kΩ 18 17 Continued on next page. No.8321-9/30 LB11600JV Continued from preceding page. Pin Number 19 Function PWM Function PWM oscillator frequency Equivalent circuit VCC setting. Insert a capacitor between this pin and ground. PWM 200Ω 2kΩ 19 20 CSD Motor constraint protection detection sense input. VCC VCC 24 Insert a capacitor between this pin and VCC and a resistor between this pin and ground. CSD 300Ω 20 21 CSET Motor constraint protection VCC circuit rotation input pulse VCC 24 detection. Insert a capacitor between this pin and VCC. CSET 300Ω 21 22 PWMRE PWM input reset. Insert a resistor and a VCC capacitor between this pin and ground. 300Ω PWMRE 22 PWMIN External PWM input. When the input is low, the out VCC put will be in the drive state and when the input is high or open, the output will be off. 50kΩ 23 3.5kΩ PWMIN 23 Continued on next page. No.8321-10/30 LB11600JV Continued from preceding page. Pin Number Function Function 24 VCC VCC power supply connection. 25 S/S Start/stop control. A low level sets the IC to the start state Equivalent circuit VCC 50kΩ and a high level or open sets it to the stop state. S/S 3.5kΩ 26 GND 27 RFGND 28 RF 25 Ground connection RFGND: Output current detection circuit VCC comparator reference ground. RF: Output current detection. Insert a resistor with a low resistance between the RF pin and ground. The maximum output current is set to IOUT = 0.24/RF by the resistor RF. RFGND 27 6kΩ 5kΩ RF 28 No.8321-11/30 LB11600JV Timing Charts (Hall input/output, startup, input off state, and constraint protection timing charts) F/R = “L” Forward IN1 IN2 IN3 UH VH WH UL VL WL F/R = “H” Forward IN1 IN2 IN3 UH VH WH UL VL WL The gray areas indicate PWM output. No.8321-12/30 LB11600JV Startup Timing Chart (When a buffered input is provided to CTL+) 5V VCC TOC PWM The PWM and TOC duty signal 0.7V PWMIN 0V 4.9V PWMRE PWMRE VthH=1.25V PWMRE(OFF)VthL=0.5V Hysteresis = 0.7V Trset 4.9V CSD 3.8V or higher - Rapid charging off. Output on 4.2V UH (When the output is on.) No.8321-13/30 LB11600JV Startup Timing Chart (When the PWMIN input is used) 5V VCC TOC PWM The PWM and TOC duty signal 0.7V 5V PWMIN 4.9V PWMRE PWMRE VthH=1.25V PWMRE(OFF)VthL=0.5V Hysteresis = 0.7V Trset 4.9V CSD 3.8V or higher - Rapid charging off. Output on 4.2V UH (When the output is on.) No.8321-14/30 LB11600JV Input Off State (CTL+input) Reset Operation Timing Chart 5V VCC PWM TOC The PWM and TOC duty signal 0.7V PWMIN 0V 4.9V PWMRE PWMRE VthH = 1.25V PWMRE (OFF) VthL = 0.5V Hysteresis = 0.7V Toff 4.9V CSD Constraint protection Vth = 0.6V Output off 4.2V UH (When the output is on.) No.8321-15/30 LB11600JV Input Off State (PWMIN input) Reset Operation Timing Chart 5V VCC TOC PWM The PWM and TOC duty signal 0.7V PWMIN 0V 4.9V PWMRE PWMRE VthH = 1.25V PWMRE (OFF) VthL = 0.5V Hysteresis = 0.7V Toff 4.9V CSD Constraint protection Vth = 0.6V Output off 4.2V UH (When the output is on.) No.8321-16/30 LB11600JV Constraint Protection State Latch Release Timing Chart (CLT+ input) 5V VCC PWM TOC The PWM and TOC duty signal 0.7V PWMIN 0V 4.9V PWMRE PWMRE VthH = 1.25V PWMRE (OFF) VthL = 0.5V Hysteresis = 0.7V Toff CSD Tchg Latch released 4.9V Tchg: CSD voltage rise time Constraint protection Vth = 0.6V Torc Torc: Output off latch state UH (When the output is on.) 4.2V Constraint protection operation (output off) No.8321-17/30 LB11600JV Constraint Protection Timing Chart No.8321-18/30 LB11600JV LB11600JV Application Circuit Diagram (FET driver: low side PWM control) VM 10μF 1kΩ 1kΩ 680Ω 680Ω 680Ω WL 30 WL VL 2 29 WH UH 3 28 RF IN1+ 5 27 26 RFGND GND IN16 25 S/S UL 4 IN3+ 9 IN310 23 22 21 24 VCC PWMIN PWMRE CSET IN28 LB11600JV IN2+ 7 F/R 11 20 CSD HP 12 19 PWM 5V 10μF 3300pF 0.022μF 200kΩ 33μF 150kΩ 1000pF 18 TOC CEG 13 CR 14 17 CTL- 0.033μF 16 CTL+ FV 15 100kΩ 200Ω VH 1 3300pF WH 1kΩ VL 200Ω VH 1kΩ UL 200Ω UH 51kΩ 1kΩ 0.055 (2W) 1000pF 1000pF 1000pF 1kΩ Top view ILB01741 *: The resistor, capacitor, and transistor values shown are for reference purposes only. The values used in an application will depend on the motor used and the control specifications. No.8321-19/30 LB11600JV LB11600JV Operation 1. Output Drive Circuit The LB11600JV adopts direct PWM drive to minimize power loss in the output system. The output transistors are always saturated when on and the motor drive power is adjusted by changing the output on duty. Output PWM switching is applied the UH, VH, and WH output side circuits. Since the UL to WL and UH to WH outputs have the same output configuration, either low side PWM or high side PWM drive can be implemented by using appropriate circuit structures with the external output drive transistors. Since the reverse recovery time for the diodes connected to the non-PWM side outputs can be a problem, care is required in selecting these diodes. (If diodes with a short reverse recovery time are not used, through currents will flow at the instant the PWM side transistors are turned on.) The UL to WL and UH to WH outputs go to the high-impedance state in the stopped state and when the supply voltage is extremely low (i.e. lower than the allowable operating voltage). This means that workarounds (such as pull-down resistors) are required so that leakage currents and other phenomenon do not cause incorrect operation in external circuits. 2. Power Saving Circuit The LB11600JV goes to a power saving state in which power consumption is reduced when the S/S pin is set to the high level. The power saving state cuts off the bias current from most of the circuits in the IC. 3. Notes on the PWM Frequency The PWM frequency is set by the capacitance of the capacitor (C) connected to the PWM pin. The formula for calculating the PWM frequency is shown below. T2 V2 V1 T1 Formula (When VCC = 5V (typical)) Oscillator period: T = T1 + T2 (s) Threshold voltage: V1 = 0.25 × VCC + 0.0975 = 1.35 (V) V2 = 0.6 × VCC = 3.0V (V) Charge time: T1 = C × (V2 - V1)/IC (s) IC: Charge current provided by the PWM pin: 45µA Discharge time: T2 = - C × Rin × ln (V1/V2) (s) Rin: PWM pin internal discharge resistor (2kΩ) C: External capacitor Oscillator frequency: Fpwm = 1/T (Hz) If a 1000pF capacitor is used, the oscillator frequency will be about 25kHz. If the PWM frequency is too low, the motor may emit audible switching noise, and if it is too high, power loss in the output circuits will be excessive. We recommend using a frequency in the range 15 to 50kHz. Connect the ground side of the external capacitor as close as possible to the IC GND pin to minimize the influence of output noise and other problems. No.8321-20/30 LB11600JV 4. Notes on PWM Drive Methods The output duty can be controlled by any of the following methods. • Control by Comparing the TOC Pin Voltage with the PWM Oscillator Waveform This method sets the UH, VH, and WH output duty by comparing the TOC pin voltage with the PWM oscillator waveform. When the TOC pin voltage falls below 1.35V (typical), the duty will be 0%, and when it rises above 3.0V (typical), the duty will be 100%. Since the TOC pin is the control amplifier's output pin, it is not possible to directly input a control voltage to the TOC pin. Therefore, the control amplifier is normally used as a buffer amplifier (by connecting the CTL- pin to the TOC pin) and inputting a DC voltage to the CTL+ pin. (This causes the TOC pin voltage to become the same as the CTL+ pin voltage.) In this case, the output duty will increase as the CTL+ pin voltage becomes higher. Since the motor will be driven if the CTL+ pin is in the open state, a pull-down resistor must be connected to the CTL+ pin if it is not desirable to drive the motor when the input is in the open state. If the CTL+ pin is used for motor control, set the PWMIN pin to the low level or short it to ground. • Pulse Control Using the PWMIN Pin A pulse input can be applied to the PWMIN pin and the duty of that signal used to To the control the output. PWMIN pin When a low-level input voltage is applied to the PWMIN pin the output will be on, and when a high-level input voltage is applied the output will be off. When the PWMIN pin is open, it goes to the high level and the output will be turned off. If the inverse input logic is required, use an external npn transistor as shown in the figure. If the PWMIN pin is used for control, connect the CTL- pin to ground and connect the CTL- pin to the TOC pin. A 1000pF capacitor must be connected to the PWM pin even when the PWMIN pin is used for control. Pulse input • PWMRE Pin Input Pulse Reset To prevent incorrect operation of the constraint protection circuit when the VCC power supply is started or when the motor is stopped (the constraint protection circuit will operate immediately if the CSD pin potential is low), that is to assure that the CSD pin is set to the high-level voltage reliably (by assuring the capacitor charge time), a reset period (outputs off, the rapid charge time for the CSD pin) is set up by a resistor and capacitor connected to the PWMRE pin. When the motor is controlled by either the CTL+ pin or by pulses input to the PWMIN pin, output to the motor is not provided immediately. Rather the output remains in the off state (the reset period) until the charge/discharge potential due to the on/off operation set by the input pulse duty width, the PWMRE pin charge current, and the capacitor and resistor connected to the PWMRE pin rises above 1.25V (typical). The IC enters operating mode when the PWMRE potential is over 1.25V (typical), and the output goes to the off state (reset state) when the PWMRE potential falls below 0.55V (typical) in the input pulse off state. The IC operates with the outputs on (UH, VH, and WH), when the PWMRE potential is over 1.25V (typical) and the CSD pin potential is over 0.76 × VCC (3.8V typical when VCC = 5V). See the timing chart for startup and the input off state. The formula for setting the reset time (Trest) and the timing charts are shown on the following pages. <Reset time (Trest f) due to the PWMRE pin (PWMIN input mode) when VCC = 5V> The rise potential (V1) and the fall potential (V2) due to the on/off duty ratio when a PWMIN input is used: When on: V1 = (V0 - Ipwmre × R) × e-t1/RC + Ipwmre × R When off: V2 = V1 × e-t2/RC = ΔV Ipwmre: PWMRE pin charge current: 200µA (typical) V0: PWMRE initial potential: 0V C: PWMRE pin external capacitor R: PWMRE pin external resistor t1: PWMIN input duty on time t2: PWMIN input duty off time No.8321-21/30 LB11600JV The time (n times the PWMIN period) required for the potential, which is increased by the V2 potential difference (ΔV) on each input pulse, to exceed the threshold voltage (Vth = 1.25V) is the reset period (Trest). V2 + ΔV + ΔV⋅⋅⋅ ≥ 1.25V Trest ≤ TPWMIN × n (s) <PWMRE Reset Time Setting Example> VCC = 5V, PWMIN = 25kHz, on duty ratio = 20% PWMRE: C = 2200pF, R = 180kΩ PWMIN = 25kHz = 40μs t1 = 40μs × 0.2 = 8μs t2 = 40μs × 0.8 = 32μs V1 = (V0 - Ipwmre × R) × e-t1/RC + Ipwmre × R = (0 - 200μA × 180kΩ) × 0.98 + (200μA × 180kΩ) = - 35.28 + 36 = 0.72 (V) V2 = V1 × e-t2/RC = 0.72 × 0.922 = 0.664 (V) Since ΔV (0.644) is added on each PWMIN input pulse, and V2 + ΔV = 0.664 + 0.664 ≥ 1.25V the threshold voltage (1.25V) will be exceeded on the second pulse. From the formula for the on time: t1' = CR × ln ((V0 – Ipwmre × R)/(V1 - Ipwmre × R)) Since the potential difference with respect to 1.25V due to the rise potential V2 of the second PWMIN pulse is 1.25 0.664 = 0.586V, 1.25V will be exceeded in the on duty state. Therefore, t1' = 2200pF × 180kΩ × ln ((0.664 – 200μA × 180kΩ) / (1.25 – 200μA × 180kΩ)) = 396μs × ln (35.336/34.75) = 6.622μs (s) Thus the reset time Trest will be one PWMIN period plus t1'. Trest = 40μs + 6.622μs = 46.622μs (s) No.8321-22/30 LB11600JV PWMRE Timing Chart for PWMIN Pin Input TOC PWM t2 5V PWMIN t1 4.9V PWMRE PWMRE VthH=1.25V V1 PWMRE(OFF)VthL=0.5V V2 V0 Hysteresis = 0.7V V ΔV Trset 4.9V CSD 3.8V or higher - Rapid charging off. Output on UH (When the output is on.) 4.2V No.8321-23/30 LB11600JV <Reset time (Trest f) due to the PWMRE pin (CTL+ buffer input mode) when VCC = 5V> 1. CTL+ input mode (When the TOC potential is higher than the PWM triangle wave rise) The rise potential (V1) and fall potential (V2) due to the on/off duty due to the TOC potential and the PWM triangle wave When on: V1 = (V0 - Ipwmre × R) × e-t1/RC + Ipwmre × R When off: V2 = V1 × e-t2/RC When the TOC potential rises and the PWM triangle wave rise is slow, the IC will be in the ON duty state at startup. This results in the time Tpwmra, which is the time until the PWM triangle wave low level is reached. The potential difference due to each input pulse is: ΔV = V2 - Vpwmra. Vpwmra = (Ipwm × Tpwmra) / Cpwm Ipwm: PWM pin charge current: 45µA (typical) Cpwm: Capacitance of the PWM pin external capacitor Ipwmre: PWMRE pin charge current: 200µA (typical) V0: PWMRE pin initial potential: 0 V C: Capacitance of the PWMRE pin external capacitor R: Resistance of the PWMRE pin external resistor t1: PWMIN pin input duty on time t2: PWMIN pin input duty off time The time (n times the PWMIN period) required for the potential, which is increased by the V2 potential difference (ΩV) on each input pulse, to exceed the threshold voltage (Vth = 1.25V) is the reset period (Trest). V2 + ΔV + ΔV⋅⋅⋅ ≥ 1.25V Trest ≤ TPWMIN × n + Tpwmra (s) 2. CTL+ input mode (When the TOC potential rises after the PWM triangle wave rises) The time required for the sum of the potentials due to the times set for each on/off duty ratio for the rise time to exceed the threshold voltage (1.25V) becomes the reset time (Trest). The times t1 and t2 for the rise potential (V1) and fall potential (V2) due to each on duty ratio will differ. Thus these must be calculated individually for each input pulse signal. The formulas for calculating V1 and V2 are the same as for the PWMIN input case. No.8321-24/30 LB11600JV PWMRE Timing Chart for CTL+ Buffered Input (1) CTL+ input mode (When the TOC potential is high due to the rise of the PWM triangle wave) TOC PWM t1 The PWM and TOC duty signal 0.7V t2 PWMIN 0V 4.9V PWMRE Tpwmra PWMRE VthH=1.25V V1 V2 PWMRE(OFF)VthL=0.5V Hysteresis = 0.7V V0 Trset 4.9V 3.8V or higher - Rapid charging off. CSD Output on 4.2V UH (When the output is on.) No.8321-25/30 LB11600JV PWMRE Timing Chart for CTL+ Buffered Input (2) CTL+ input mode (When the TOC potential rises after the rise of the PWM triangle wave) TOC PWM T1 The PWM and TOC duty signal t5 t3 0.7V t2 t4 PWMIN 0V 4.9V PWMRE V5 V0 V0 PWMRE(OFF)VthL=0.5V V3 V1 V2 PWMRE VthH=1.25V Hysteresis = 0.7V V4 Trset 4.9V CSD 3.8V or higher - Rapid charging off. Output on 4.2V UH (When the output is on.) No.8321-26/30 LB11600JV 5. Hall Input Signals The Hall effect sensor inputs require input signals with an amplitude larger than the hysteresis (80mV maximum) and an even larger amplitude is desirable to avoid problems due to noise, phase displacement, and other issues. If disturbances to the output waveforms (at phase switching) or HP output occur due to noise, the disturbances must be prevented by inserting capacitors across the inputs or by other means. The Hall inputs are used as input discrimination signals to the constraint protection circuit and the one-shot multivibrator circuit. Although these circuits are designed to tolerate a certain amount of noise, care is required if these protection circuits are used. If all three phases of the Hall input signals go to the same state, all of the outputs will be turned off (all of the UL, VL, WL, UH, VH, and WH outputs will go to the low level potential). If the outputs from a Hall IC are used for these inputs, tying one side of the inputs (either the + or - side) to a voltage within the common-mode input range for when Hall sensors are used allows the other side of the input to be used with an input in the 0 to VCC range. 6. Undervoltage Protection Circuit This IC starts up (output operation turns on) at a VCC voltage of 4.3V (typical) and turns the outputs off (sets the UH, VH, and WH outputs to the low level potential) when the VCC voltage falls to under 3.8V(typical). 7. Constraint Protection Circuit The LB11600JV includes a constraint protection circuit to protect the motor and the IC itself when the motor is physically prevented from turning. If the Hall input signals do not change for a certain fixed period when the IC is operating in the motor drive state, one side of the output system (the UH, VH, and WH outputs) is turned off. The time is set by the discharge time of the resistor and capacitor connected to the CSD pin. (See the constraint protection circuit timing chart.) The motor rotation pulse detection signal is detected with the timing of the fall (high to low) of the UH output signal, one of the three output phases. The rotation pulse detection signal time is set by the discharge time for the CSET pin capacitor. During motor rotation, the CSD pin potential will always be high during the rotation pulse detection time. If the motor becomes constrained (stopped), the CSD potential is discharged and the outputs (UH, VH, and WH) are set low when the CSP potential falls under 0.6V. After the constraint protection circuit operates, the outputs will be latched in the low state. To clear this latched state, set either PWMIN or S/S to the high level. The latched state is cleared when the PWMRE potential falls below 0.55V (typical) and the IC enters the reset state. (See the latch clear timing chart.) Note that if the CSD pin resistor Rc is too large, the CSD pin potential may rise due to the bias current from the internal comparator circuit. Rotation pulse detection signal time: Tps = Cs × VBE / Icset (s) Cs: CSET pin external capacitor (connected between VCC and CSET) VBE: VBE for the transistor in the constraint protection circuit: 0.7V (typical) Lcset: CSET pin discharge current: 50µA (typical) Motor constraint time: Tcsd = ln (VCC / (0.6 - Ibcd × Rc) × Cc × Rc (s) Cc: CSD pin external capacitor (connected between VCC and CSD) Rc: CSD pin external resistor (connected between the CSD pin and ground) Ibcd: CSD pin internal comparator bias current: 1µA (typical) CSD pin discharge potential threshold voltage: 0.6V (typical) Latch release time: Toff = ln (VCC / 0.55) × Cre × Rre (s) Cre: PWMRE pin external capacitor (connected between the PWMRE pin and ground) Rre: PWMRE pin external resistor (connected between the PWMRE pin and ground) CSD potential rise time (rapid charging time): Tchg ≈ Cc × Rc × ln ((V1 - Ic × Rc) / (V2 - Ic × Rc)) (s) Cc: CSD pin external capacitor (connected between VCC and CSD) Rc: CSD pin external resistor (connected between the CSD pin and ground) Ic: CSD pin transistor current (7mA maximum (design target value)) V1: CSD pin initial voltage V2: CSD pin voltage (when the transistor is in the on state): 4.9V (typical) No.8321-27/30 LB11600JV CSD voltage rise time (during motor rotation): Tchg ≈ Cc × Rc × ln((V1 - Ic × Rc) / (V2 - Ic × Rc)) (s) Cc: CSD pin external capacitor (connected between VCC and CSD) Rc: CSD pin external resistor (connected between the CSD pin and ground) Ic: CSD pin transistor current (3.5mA maximum (design target value)) V1: CSD pin initial voltage V2: CSD pin voltage (when the transistor is in the on state): 4.9V (typical) <Constraint Time Setting Example> When VCC = 5V, to set the motor constraint time to 3 seconds: Use a 10µF capacitor for the CSD pin capacitor Cc and a 130kΩ resistor for Rc. Motor constraint time: Tcsd = 1n (5 / (0.6 – 130kΩ × 1μA) × 10μF × 130kΩ = 2.36 × 10μF × 130kΩ = 3.068 (s) The discharge time for the capacitor specified above will be the motor constraint time. The pulse signal that detects whether or not the motor is turning is set by the CSET pin capacitor. If a 0.022 µF capacitor is used as the CSET pin capacitor Cs: Rotation pulse signal detection time: Tps = 0.022μF × 0.7/50μA = 308μs Note that care is required in setting these values since the amplitude of the rotation pulse detection signal is influenced by the motor speed, and the CSD capacitance. If the rotation pulse detection signal time is too short, the IC will not be able to raise the CSD potential to the high level. Also, if the CSD pin capacitor value is too small and the discharge time too short, the rotation detection pulse signal will not be issued for the motor rotation period at the start of motor rotation (when the motor is turning slowly), and the constraint protection circuit may latch. For example, since at speeds under 100rpm the UH output period will be 300ms, the motor constraint time must be set to a time of at least 600ms. 8. Overcurrent Protection Circuit To the RF pin The overcurrent protection circuit limits the output current to be a Current maximum of I = VRF/Rf (where VRF = 0.24V typical, and RF is the detection current detection resistor). The current limiter circuit detects the reverse resistor recovery current in the output diodes due to PWM operation and includes a built-in filter circuit to prevent incorrect operation. While this internal filter circuit is adequate for most applications, if the circuit is observed to operate incorrectly (for example, in cases where the diode reverse recovery current flows for over 3 µs), an external filter circuit (such as a passive low-pass filter circuit) must be added. 9. Thermal Protection Circuit The thermal protection circuit turns off one side of the output (UH, VH, and WH) if the IC junction temperature (Tj) exceeds the stipulated temperature (TSD = 170°C, typical). 10. Direction Reversal Do not reverse motor direction while the motor is turning. To reverse directions, first stop the motor (set PWMIN high or set the S/S pin high) and then startup again with the desired direction. 11. HP Output The Hall signal created from the IN3 pin Hall amplifier input signal is inverted and output from the HP pin. Since the HP pin is an open-collector output, a pull-up resistor must be inserted between VCC and the HP pin. Hall amplifier input conditions: IN3-: fixed potential, HP pin: pulled up to VCC. IN3+ input IN3- HP pin No.8321-28/30 LB11600JV 12. One-Shot Multivibrator Circuit Block (CEG, CR, and FV pins) The LB11600JV includes a built-in one-shot multivibrator circuit to allow it to support speed feedback control. The signal used for speed control is a rotation pulse detection signal that is created in the CEG pin circuit block with the timing of the fall (high to low) of the UH output signal, one of the three output phases. The LB11600JV detects the rotation period from this signal. The rotation pulse detection signal time is set by the discharge time of the capacitor connected to the CEG pin. Rotation pulse detection signal time: Tps = Ce × VBE/Iceg (s) Ce: CEG pin external capacitor (connected between VCC and CEG) VBE: VBE for the transistor in the CEG edge detection circuit: 0.7V (typical) Iceg: CSET pin discharge current: 50µA (typical) The CR pin sets the pulse width (high period) generated at the FV pin at each signal from the CEG pin. The pulse width is set by connecting a resistor and a capacitor between the CR pin CR pin and VCC and ground, respectively. The pulse width TRC can be calculated approximately with the following formula. TRC ≈ 1.1 × R × C (s) Normally, a smoothing circuit consisting of a resistor and capacitor as shown in the figure is connected to the FV pin. A resistor with a value of at least 25kΩ must be selected. The value of the capacitor must be selected so that adequate smoothing of FV pin the FV voltage is provided when the motor speed is low. Normally, this circuit is set up so that the following relationship holds when fUH (Hz) is the UH output frequency at the highest motor speed. TRC ≤ 1/(2 × fUH) (s) In this case, the FV voltage will change from 0 to about 5V according to the motor speed. If the FV output is not used, connect the CR pin to ground and leave the FV pin open. To the VCC pin R C FV voltage 13. Power Supply Stabilization Since the LB11600JV adopts a switching-based drive method, the power supply line level is easily disturbed. Therefore it is necessary to connect a capacitor with adequate capacitance to stabilize the power supply between the VCC pin and ground. If diodes are inserted in the power supply lines to prevent damage if the power supply is inadvertently connected with reverse polarity, the power supply line will be even more sensitive to disruption. Here, an even larger capacitance must be provided. If the switch and the capacitor are widely separated when the power supply is turned on and off, such as during switching, the supply voltage may swing widely due to the surge current between the line inductance and the capacitor. Voltages that exceed the LB11600JV's voltage handling capacity may occur. In applications such as this, do not use components, such as ceramic capacitors, which have a low capacitor series impedance, but rather use electrolytic capacitors and implement measures to minimize the surge current and prevent voltage increases. No.8321-29/30 LB11600JV 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. 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 December, 2006. Specifications and information herein are subject to change without notice. PS No.8321-30/30