LV8805V Bi-CMOS LSI Fan Motor Driver for PC and Server www.onsemi.com Overview The LV8805V is a motor driver for PC and server fans. Feature Direct PWM three-phase sensorless motor driver Typical Applications Computer peripherals Fan motor Unit Server SSOP36J (275mil) Specifications Absolute Maximum Ratings at Ta = 25C Parameter Symbol Conditions Ratings Unit VCC maximum supply voltage VCC max 16 V VG maximum supply voltage VG max 21 V OUT pin withstand voltage VOUT max 16 V OUT pin maximum output IOUT max 1.2 A SOFTST pin withstand voltage VSOFTST max 6 V FR pin withstand voltage VFR max 6 V PWMIN pin withstand voltage VPWMIN max 6 V FG output pin withstand voltage VFG max 16 V FG pin output current IFG max 5 mA 1/2FG output pin withstand V1/2FG max 16 V 1/2FG pin output current I1/2FG max 5 mA RD output pin withstand voltage VRD max 16 V RD pin output current IRD max 5 mA Allowable Power dissipation 1 Pd max1 Independent IC 0.6 W Allowable Power dissipation 2 Pd max2 Mounted on designated board *1 Operating temperature Topr Storage temperature Tstg *2 1.3 W 40 to +95 C 55 to +150 C *1: When mounted on the designated 76.1mm × 114.3mm × 1.6mm, glass epoxy board (single-layer) *2: Do not exceed Tjmax=150C. Caution 1) Absolute maximum ratings represent the value which cannot be exceeded for any length of time. Caution 2) Even when the device is used within the range of absolute maximum ratings, as a result of continuous usage under high temperature, high current, high voltage, or drastic temperature change, the reliability of the IC may be degraded. Please contact us for the further details. Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality should not be assumed, damage may occur and reliability may be affected. ORDERING INFORMATION See detailed ordering and shipping information on page 12 of this data sheet. © Semiconductor Components Industries, LLC, 2015 April 2015 - Rev. 2 1 Publication Order Number : LV8805V/D LV8805V Recommended Operating Conditions at Ta = 25C Parameter Symbol VCC supply voltage VCC SOFTST input voltage range Conditions Ratings Unit 6 to 15 V VSOFTST 0 to VREG V FR input voltage range VFR 0 to VREG V MINSP input voltage range VMINSP 0 to VREG V Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond the Recommended Operating Ranges limits may affect device reliability. Electrical Characteristics at Ta 25C, VCC = 12V, unless otherwise specified Parameter Circuit current 1 Symbol Conditions Ratings min typ Unit max ICC1 2.6 VVG 17 3.6 mA Charge pump block Charge pump output voltage V Regulator block 5V regulator voltage VVREG 4.75 5 5.25 V 1.2 2 Output on resistance Sum of high-/low-side output transistor on Ron (H+L) IO = 0.7A, VCC = 12V, VG = 17V resistance Startup oscillator (OSC) pin OSC pin charge current IOSCC 2.5 A OSC pin discharge current IOSCD 2.5 A PWM input (PWMIN) pin High-level input voltage range VPWMINH 2.5 VREG V Low-level input voltage range VPWMINL 0 1 V Range of PWM input frequency fPWMIN Minimum pulse width TMINPW 15 60 kHz 0.2 s 2.5 VREG V 0 1 V Input HIGH voltage 5[V] and input LOW voltage 0[V] Duty cycle range is determined by (TMINPW x fPWMIN) x 100% for minimum (1 − TMINPW x fPWMIN) x 100% for maximum When fPWMIN = 60[kHz], the input PWM duty cycle range = 1.2% - 98.8% When fPWMIN = 50[kHz], the input PWM duty cycle range = 1.0% - 99.0% When fPWMIN = 25[kHz], the input PWM duty cycle range = 0.5% - 99.5% When fPWMIN = 15[kHz], the input PWM duty cycle range = 0.3% - 99.7% Forward/reverse switching pin High-level input voltage range VFRH Low-level input voltage range VFRL Order of current application : UOUTVOUTWOUT Order of current application : UOUTWOUTVOUT FG, 1/2FG, and RD output pins FG output pin low-level voltage VFG When IO is 2mA FG output pin leak voltage ILFG When VFG is 16V 1/2FG output pin low-level voltage V1/2FG When IO is 2mA 1/2FG output pin leak voltage IL1/2FG When V1/2FG is 16V RD output pin low-level voltage VRD When IO is 2mA RD output pin leak voltage ILRD When VRD is 16V VRF Limit current set to 1A when RF is 0.25. 0.25 0.35 V 1 A 0.25 0.35 V 1 A 0.25 0.35 V 1 A V Current limiter circuit Limiter voltage 0.225 0.25 0.275 Constraint protection circuit CT pin high-level voltage VCTH 2.25 2.8 2.95 V CT pin low-level voltage VCTL 0.43 0.5 0.65 V CT pin charge current ICTC 2.9 2.5 2.2 A CT pin discharge current ICTD 0.21 0.25 0.32 A ICT charge/discharge ratio RCT 7 10 13 Continued on next page. www.onsemi.com 2 LV8805V Continued from preceding page. Parameter Symbol Conditions Ratings min typ max Unit Soft start circuit Soft start releasing voltage VSOFTST 2.5 V SOFTST pin charge current ISOFTST 0.6 A Thermal protection circuit Thermal protection circuit operating TSD Design target * 150 180 210 C temperature * : Design target value and no measurement is made. The thermal protection circuit is incorporated to protect the IC from burnout or thermal destruction. Since it operates outside the IC's guaranteed operating range, the customer's thermal design should be performed so that the thermal protection circuit will not be activated when the fan is running under normal operating conditions. Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product performance may not be indicated by the Electrical Characteristics if operated under different conditions. www.onsemi.com 3 LV8805V Package Dimensions unit : mm SSOP36J (275mil) Exposed Pad CASE 940AH ISSUE A www.onsemi.com 4 LV8805V 1.00 SOLDERING FOOTPRINT* (Unit: mm) 7.00 (3.5) (4.0) 0.80 0.42 NOTES: 1. The measurements are for reference only, and unable to guarantee. 2. Please take appropriate action to design the actual Exposed Die Pad and Fin portion. 3. After setting, verification on the product must be done. (Although there are no recommended design for Exposed Die Pad and Fin portion Metal mask and shape for Through−Hole pitch (Pitch & Via etc), checking the soldered joint condition and reliability verification of soldered joint will be needed. Void gradient insufficient thickness of soldered joint or bond degradation could lead IC destruction because thermal conduction to substrate becomes poor.) *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. GENERIC MARKING DIAGRAM* XXXXXXXXXX YMDDD XXXXX = Specific Device Code Y = Year M = Month www.onsemi.com 5 LV8805V Allowable power dissipation, Pd max – W 1.5 Pd max – Ta Thermal resistance evaluation board Thermal resistance evaluation board : 76.1 × 114.3 × 1.6mm3 glass epoxy 1.30 1.0 Independent IC 0.60 0.57 0.5 0.26 0 – 30 – 20 0 20 40 60 80 100 120 Ambient temperature, Ta – °C Pin Assignment COMIN 1 36 COM FIL 2 35 VCC VREG 3 34 VCC VREG 4 33 VCC NC 5 32 VCC NC 6 31 NC F/R 7 30 UO PWMIN 8 29 VO NC 9 SOFTST 10 28 WO LV8805V 27 RF FG 11 26 RF 1/2FG 12 25 NC NC 13 24 RF RD 14 23 SUB_GND NC 15 22 CPC CT 16 21 CP OSC 17 20 VG GND 18 19 GND Top view www.onsemi.com 6 LV8805V Block Diagram 1/2FG FG RD FG CT RD CTOSC VG CPC CP CHARGE PUMP VREG REFOSC VREG PWMIN OSC SENSORLESS LOGIC F/R START OSC PRI DRIVE FIL VCC COMIN UO VO WO SELECTOR COM RF CURR LIM SUB_GND GND SOFTST www.onsemi.com 7 COM LV8805V Pin Function Pin No. 36 1 Pin name COM COMIN Function Equivalent circuit Motor middle point connection. VG Motor position detection comparator filter pin. A capacitor must be connected between this pin and the FIL pin (pin 2). 2 FIL 36 Motor position detection comparator filter pin. A capacitor must be connected between this pin and the COMIN pin (pin 5). 1 3 VREG Regulator voltage (5V) output. 2 VCC A capacitor must be connected between these pins and ground. 4 3 4 VREF 5, 6, 9 NC No connection. These pins are not connected with the internal parts. 13, 15, 25, 31 7 F/R Motor rotation direction switching. A high-level input causes current to flow into VREG Reverse signal the motor in the order of U, V, and W and a low-level input in the order of U, W, and V. Changing the order of current application 7 turns the motor in the opposite direction. 15kΩ Forward/reverse switching signal 100kΩ Forward signal 8 PWMIN PWM signal input pin. VREG "H" The output transistor is turned on by the level voltage input. "L" The output transistor is turned off by the level voltage input, and the motor stops. The speed of the motor is controlled by controlling Duty of the input 8 signal. When the pin opens, the motor becomes all velocities. 10 SOFTST Soft start time setting. VREG The motor can be started smoothly by connecting a capacitor between this pin and ground. 500Ω 10 Continued on next page. www.onsemi.com 8 LV8805V Continued from preceding page. Pin No. Pin name 11 FG 12 1/2FG 14 RD 16 CT Function Equivalent circuit FG pulse output. This pin outputs a Hall 11 12 14 sensor system equivalent pulse signal. FG pulse output. This pin outputs 1/2 Hall sensor system equivalent pulse signal. Motor lockup detection output. Output is fixed high when motor is locked up. Motor lockup detection time setting. VREG When the motor lockup condition is detected, the protection time period before the protection circuit is activated is set by connecting a capacitor between this pin and ground. 500Ω 16 17 OSC Motor startup frequency setting. A capacitor VREG must be connected between this pin and ground. The startup frequency is adjusted by controlling the charge/discharge current and 500Ω capacitance of the capacitor. 17 18, 19 20 GND VG 500Ω GND pin. Charge pump step-up voltage output. 21 A capacitor must be connected between this 21 CP 22 VCC pin and the VCC pin or ground. VREG Charge pump step-up pulse output pin. 20 A capacitor must be connected between this pin and the CPC pin (pin 22). 22 CPC Charge pump step-up pin. A capacitor must be connected between this pin and the CP pin (pin 21). 23 32, 33, SUB_GND VCC 34, 35 30 UO 29 VO 28 WO 24, 26, RF 27 GND pin. Power supply for the IC and motor. Capacitors must be connected between 32 33 these pins and ground. 34 35 Output pins. Connect these pins to the U, V, 28 and W of the motor coil. 29 30 24 26 27 Output current detection pins. The drive current is detected by connecting a resistor between these pins and ground. www.onsemi.com 9 LV8805V Application Circuit Example *3 VCC UO VG VO CP WO COM CPC COMIN VREG *10 F/R FG PWMIN PWM Control Signal F=20kHz to 50kHz *11 RFG, R1/2FG, RRD =10k to 100k FIL PWMIN 1/2FG RD *11 *11 *11 FG 1/2FG RD CT RF SOFTST OSC *8 1000pF GND SUB GND *1 *1. Power supply and GND wiring The GND is connected to the control circuit power supply system. *2. Power-side power stabilization capacitor For the power-side power stabilization capacitor, use a capacitor of 10F or more. Connect the capacitor between VCC and GND with a thick and along the shortest possible route. The VCC pins (pins 32, 33, 34, and 35) must be short-circuited on the print pattern. The GND pins (pins 18 and 19) and the SUB_GND pin (pin 23) must be short-circuited on the print pattern. LV8805V uses synchronous rectification for high efficiency drive. Synchronous rectification is effective for heat reduction and higher efficiency. However, it may increase supply voltage. If the supply voltage shall increase, make sure that it does not exceed the maximum ratings by inserting a zener diode between power supply and GND. *3. Reverse connection protection diode This diode protects reverse connection. Insert a diode between power supply and VCC pin to protect the IC from destruction due to reverse connection. Connection of this diode is not necessary required. *4. COMIN and FIL pins These pins are used to connect the filter capacitor. The LV8805V uses the back EMF signal generated when the motor is running to detect the information on the rotor position. The IC determines the timing at which the output block applies current to the motor based on the position information obtained here. Insert a filter capacitor with a capacitance ranging from 1,000pF to 10,000pF (reference value) between the COMIN pin and FIL pin to prevent any motor startup misoperation that is caused by noise. However, care must be taken since an excessively high capacitance will give rise to deterioration in efficiency and delays in the output power-on timing while the motor is running at high speed. Furthermore, connect the capacitor between the COMIN pin and FIL pin as close as possible in order to avoid the effects of noise from other sources. www.onsemi.com 10 LV8805V *5. CT pin This pin is used to connect the lock detection capacitor. The constant-current charging and constant-current discharging circuits incorporated cause locking when the pin voltage reaches 2.5V, and releasing the lock protection when it drops to 0.5V. This pin must be connected to the GND when it is not going to be used. *6. RF pins These pins are used to set the current limit. When the pin voltage exceeds 0.25V, the current is limited, and regeneration mode is established. In the application circuit, this voltage is set in such a way that the current limit will be established at 1A. The calculation formula is given below. RF resistance = 0.25V/target current limit value All the RF pins (pins 24, 26 and 27) must be short-circuited on the print pattern. *7. SOFTST pin This pin is used to set the soft start. By connecting a capacitor between this pin and GND, the motor speed can be increased gradually. When the pin voltage exceeds 2.5V, the soft start is released, and the LV8805V is switched to normal control. If the soft start function is not going to be used, connect the pin to the VREG pin. *8. OSC pin This pin is used to connect the capacitor for setting the startup frequency. A capacitor with a capacitance ranging from about 500pF to 2,200pF (reference value) must be connected between this pin and GND. The OSC pin determines the motor startup frequency, so be sure to connect a capacitor to it. <How to select the capacitance> Select a capacitance value that will result in the shortest possible startup time for achieving the target speed and produce minimal variations in the startup time. If the capacitance is too high, variations in the startup time will increase; conversely, if it is too low, the motor may idle. The optimum OSC constant depends on the motor characteristics and startup current, so be sure to recheck them when the type of motor used or circuit specifications are changed. *9. VG, CP, and CPC pins These pins are used to connect the capacitors to generate the pre-drive voltage and stabilize the pre-drive power supply. Be sure to connect these capacitors in order to generate the drive voltage for the high-side (upper) output DMOS transistor. *10. VREG pins These are the control system power supply pin and regulator output pin, which create the power supply of the control unit. Be sure to connect a capacitor between this pin and GND in order to stabilize control system operation. Since these pins are used to supply current for control and generate the charge pump voltage, connect a capacitor with a capacitance that is higher than that of the capacitor connected to the charge pump. Both the VREG pins (pins 3 and 4) must be short-circuited on the print pattern. *11. Pin protection resistor It is recommended that resistors higher than 1kΩ are connected serially to protect pins against misconnection such as GND open and reverse connection. www.onsemi.com 11 LV8805V ORDERING INFORMATION Device LV8805V-MPB-H Package SSOP36J (275mil) (Pb-Free / Halogen Free) LV8805V-TLM-H SSOP36J (275mil) (Pb-Free / Halogen Free) Shipping (Qty / Packing) 30 / Fan-Fold 2000 / Tape & Reel ON Semiconductor and the ON logo are registered trademarks of Semiconductor Components Industries, LLC (SCILLC) or its subsidiaries in the United States and/or other countries. SCILLC owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent-Marking.pdf . SCILLC reserves the right to make changes without further notice to any products herein. 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