MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER DESCRIPTION PIN CONFIGURATION (TOP VIEW) The M56783AFP is a semiconductor integrated circuit in order to drive 3ch actuator. VREF 1 42 OUT1 VBS 2 41 IN1- SOUT1 3 40 IN1+ SIN1- 4 39 OP1OUT VM1- 5 38 OP1- VM1+ 6 37 OP1+ Vm12 7 36 MUTE1 MGND12 8 35 MUTE2 9 34 FEATURES M56783AFP ● 3.3V DSP available. ● Low saturation voltage. ● By taking advantage of the bootstrap function, the saturation voltage can be lower. ● There are two motor power supplies. Vm12 CH1, 2 motor power supply-1 Vm3 CH3 motor power supply-2 ● 7V power-supply is possible (Vm12 = 12V and MGND12 = 5V) ● Flexible Input amplifier setting. (It enables PWM control.) ● CH1 and CH2 can act in the Current Control mode. ● Low cross-over distortion. ● Wide supply voltage range. (4.5V – 13.2V) ● Including Thermal Shut Down circuit. ● Including 2 Operational Amplifiers. ● Including Mute circuit (2 lines). 10 GND 11 12 APPLICATION 33 32 GND 31 13 30 VM2+ 14 29 VM3+ MD, CD-audio, CD-ROM, VCD, DVD etc. VM2- 15 28 VM3- SIN2- 16 27 Vm3 SOUT2 17 26 IN3- OUT2 18 25 IN3+ IN2- 19 24 TP IN2+ 20 23 OP2+ OP2OUT 21 22 OP2- Outline 42P9R-F BLOCK DIAGRAM Vm12 VBS Vm3 7 2 27 SOUT1 3 VBS IN1+ 40 IN1- 41 + - OUT1 42 + R VBS R R - + +- - Vm12 - Vm3 26 IN3- B1 + S1 SIN1- 4 R VBS VBS Vrefm12 E1 25 IN3+ B2 VBS Vrefm3 VBS VM1(+) 6 + VM2(+) 14 + - VM2(-) 15 + CH3 ×12 CH1 ×12 VBS TSD OUT2 18 OP2 - 22 OP223 OP2+ 3CH 39 OP1OUT E2 S2 VREF 9 to 13 30 to 34 MGND12 GND (10PINS) - OP1 + VBS +-+ 8 21 OP2OUT Low,Open MUTE ON 1, 2 CH VBS VBS SOUT2 17 29 VM3(+) VBS VBS BIAS SIN2- 16 + SLEEP CH2 ×12 + 28 VM3(-) H: sleep BIAS VBS IN2- 19 IN2+ 20 + - 1 24 36 35 VREF TP MUTE1 MUTE2 - 38 OP1- + + - + VM1(-) 5 37 OP1+ MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER PIN DESCRIPTION Pin No. Symbol Function Pin No. VREF Reference voltage input Bootstrap power supply VBS 3 S1 amplifier output SOUT1 4 S1 amplifier inverted input SIN15 CH1 inverted output VM16 CH1 non-inverted output VM1+ 7 1CH, 2CH Motor power supply Vm12 8 Motor GND MGND 9 – 13 GND GND 14 CH2 non-inverted output VM2+ 15 CH2 inverted output VM216 S2 amplifier inverted input SIN217 S2 amplifier output SOUT2 18 OUT2 E2 amplifier output 19 IN2E2 amplifier inverted input 20 IN2+ E2 amplifier non-inverted input 21 OP2OUT OP2 amplifier output *Note1. The 24 pin (TP) is test terminal. Please make an open the 1 42 2 41 40 39 38 37 36 35 28 – 34 29 28 27 26 25 24 23 22 Function Symbol OUT1 IN1IN1+ OP1OUT OP1OP1+ MUTE1 MUTE2 GND VM3+ VM3Vm3 IN3IN3+ TP OP2+ OP2- E3 amplifier output E1 amplifier inverted input E1 amplifier non-inverted input OP1 amplifier output OP1 amplifier inverted input OP1 amplifier non-inverted input 1CH, 2CH mute 3CH mute GND CH3 non-inverted output CH3 inverted output 3CH Motor power supply B1 buffer input B2 buffer input TEST *Note1 OP2 amplifier non-inverted input OP2 amplifier inverted input pin (TP). 24 ABSOLUTE MAXIMUM RATING (Ta = 25°C) Symbol VBS Vm Io12 Parameter Io3 Bootstrap power supply Motor power supply 1CH, 2CH Output Current 3CH Output Current Vin Maximum input voltage of terminals Pt Kθ Tj Topr Tstg Power dissipation Thermal derating Junction temperature Operating temperature Storage temperature Conditions VBS power supply Vm power supply *Note2 , 19 , 20 , , 16 Pins Free Air Free Air 1 22 , 23 , 25 , 26 , 35 , 36 , 37 , 38 , 40 , 41 Pins 4 *Note2. The ICs must be operated within the Pt (power dissipation) or the area of safety operation. Rating Units 15 15 1.0 0.7 0 – VBS Vm12 1.2 9.6 150 -20 – +75 -40 – +150 V V A A V V W mW/°C °C °C °C MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER RECOMMENDED OPERATING CONDITIONS Symbol Vm12, Vm3 VBS Parameter Min. Motor power supply 4.5 — Bootstrap power supply Limits Typ. 5.0 Vm + 1.0 Max. 13.2 13.2 Units V V ELECTRICAL CHARACTERISTICS (Ta = 25°C, VBS = 12V, Vm12 = Vm3 = 5V unless otherwise noted) Symbol ICC1 Min. — Limits Typ. 35 Max. 50 — — 10 µA — — — -47 -47 -47 0.6 0.6 0.6 — — — 0.9 0.9 0.9 47 47 47 V V V mV mV mV 0 — VBS-2.0 V No load 0.5 — VBS-1.0 V Vin = 1.65V and ±2mA load -10 -1 — 2.0 — — — — +10 0 0.8 — mV µA V V — — 250 µA Parameter Conditions Supply current - 1 VBS, Vm12, Vm3 current ICC2 Supply current - 2 VBS, Vm12, Vm3 current under Sleep Mode (MUTE1 = MUTE2 =0V). Vsat1 Vsat2 Vsat3 Voff1 Voff2 Voff3 CH1 Saturation voltage CH2 Saturation voltage CH3 Saturation voltage CH1 output offset voltage CH2 output offset voltage CH3 output offset voltage OP1, OP2 amplifier input voltage range VinOP VoutOP OP1, OP2 amplifier output voltage range OP1, OP2 amplifier offset voltage VofOP IinOP OP1, OP2 amplifier input current Vmute-on Mute-on voltage Vmute-off Mute-off voltage Imute Mute terminal input current Top and Bottom saturation voltage. Load current 0.5A (bootstrap) VREF = OUT1 = 1.65V VREF = OUT2 = 1.65V IN3+ = IN3- = 1.65V Mute-on Mute-off Mute terminal input current (at 5V input voltage) Units mA MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER ELECTRICAL CHARACTERISTICS (Ta = 25°C, VBS = 12V, Vm12 = Vm3 = 5V unless otherwise noted) Symbol Parameter Conditions Min. Limits Typ. Max. Units Gain1 CH1 Voltage Gain between input and output {VM1(+) – VM1(-)} (OUT1 – VREF) 10.8 12 13.2 V/V Gain2 CH2 Voltage Gain between input and output {VM2(+) – VM2(-)} (OUT2 – VREF) 10.8 12 13.2 V/V Gain3 CH3 Voltage Gain between input and output {VM3(+) – VM3(-)} (IN3(+) – IN3(-)) 10.8 12 13.2 V/V 0.5 — VBS-2.0 V no load 0.5 — VBS-0.5 V Vin = 1.65V (at buffer) IN+ = IN- = 1.65V -10 -1 0 0 -1 — — — — — +10 0 5.0 3.0 0 mV µA 0.9 1 1.1 V/V 0 — Vm12 V no load 1.0 — VBS-1.0 V S1: (SOUT1 – VREF) at SIN1- = VM1+ S2: (SOUT2 – VREF) at SIN2- = VM2+ VREF = 1.65V -20 — +20 mV 0.5 -1 — — VBS-2.0 0 V µA VinE E1, 2 amplifier input voltage range VoutE E1, 2 amplifier output voltage range E1, 2 amplifier offset voltage E1, 2 amplifier input current B1, 2 buffer input voltage range VofE IinE VinB IinB GainS VinS VoutS B1, 2 buffer input current S1, 2 amplifier Voltage Gain between input and output SIN1-, SIN2- input voltage range S1, 2 amplifier output voltage range VBS=12V VBS=5.0V and Vm3=5.0V IN3+ = IN3- = 1.65V S1: (SOUT1 – VREF) / (VM1+ – SIN1-) S2: (SOUT2 – VREF) / (VM2+ – SIN2-) VREF = 1.65V VofS S1, 2 amplifier offset voltage VinVREF IinVREF VREF amplifier input voltage range VREF amplifier input current VREF = 1.65V V µA MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER THERMAL CHARACTERISTICS TSD FUNCTION START TEMPERATURE OF IC Min. Typ. Max. Parameter Symbol — Thermal Shut Down 165 FUNCTION STOP TEMPERATURE OF IC Min. Typ. Max. — — 125 — Units °C THERMAL DERATING 6.0 (W) 3.9W using K-type board This IC’s package is POWER-SSOP, so improving the board on which the IC is mounted enables a large power dissipation without a heat sink. For example, using an 1 layer glass epoxy resin board, the IC’s power dissipation is 2.6W at least. And it comes to 3.9W by using an improved 2 layer board. The information of the K, L, M type board is shown in the board information. 5.0 Power Dissipation (Pdp) 2.9W using L-type board 4.0 2.6W using M-type board 3.0 2.0 1.0 0 25 50 75 100 Ambient Temperature Ta (°C) 125 150 MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER I/O CHARACTERISTICS OF EACH CHANNELS CH1, 2 amplifier <INPUT> OUT Vm12 + 20K 20K 1.5V Vrefm12 0.2V Vrefm1 Amp. 2.5K 15K VM+ <OUTPUT> + VREF 1.5V 2.5K + 15K Vrefm1 (Vm12/2) Vref Amp. OUT 2.5K + ININ+ Input Amp. 2.5K + - VM- VM+ 15K 1.2V 1.2V VM- 15K Gain = ×12 Reference 1.5V CH3 amplifier <INPUT> IN+ Vm3 + 20K 20K R R 0.2V Vrefm2 Amp. 4K 5.0V 2.5V Vrefm3 4K 24K . <OUTPUT> + 24K + - VM- 1.2V Vrefm2 (Vm/2) IN4K VM+ VM+ 1.2V 24K VM- IN+ Input Buffer Reference 2.5V 4K 24K Gain = ×12 S1, S2 amplifier <INPUT> SINSIN- VM+ 10K 10K 10K + VM+ 0.5V SOUT 10K <OUTPUT> SOUT VREF + Vref Amp. Vrefm2 (Vm/2) Gain = ×1 0.5V MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER MUTE FUNCTION This IC has two MUTE terminal (MUTE1 and MUTE2). It is possible to control ON / OFF of each circuit (CH1, CH2, CH3, etc) by external logic inputs. The table 1 shows its function. In case of both MUTE1 and MUTE2 is LOW or OPEN, the bias of all circuit becomes OFF. Therefore, this mode is available in order to reduce the power dissipation when the waiting mode. Table 1. CH1, CH2 CIRCUIT CH3 CIRCUIT OP1, OP2 CIRCUIT BIAS CIRCUIT TSD CIRCUIT MUTE1 MUTE2 H H ON ON ON ON ON H L,OPEN ON OFF ON ON ON L,OPEN H OFF ON ON ON ON L,OPEN L,OPEN OFF OFF OFF OFF OFF MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER I/O TERMINAL EQUIVALENT CIRCUIT (1) E1, E2 input amplifier I/O terminal equivalent circuit (2) B1, B2 input buffer input terminal equivalent circuit (IN1+, IN1-, OUT1, IN2+, IN2-, OUT2) (IN3+, IN3-) VBS GND VBS GND IN*- VBS GND IN*+ VBS VBS GND VBS IN3* OUT* (3) VREF amplifier input terminal equivalent circuit (4) OP1, OP2 input buffer I/O terminal equivalent circuit (VREF) (OP1+, OP1-, OP1OUT, OP2+, OP2-, OP2OUT) VBS VBS GND GND VBS GND VBS VBS GND VBS VREF OP*+ OP*- (5) S1, S2 input buffer I/O terminal equivalent circuit (6) MUTE equivalent circuit (SIN1-, SOUT1, SIN2-, SOUT2) (MUTE1, MUTE2) VM+ VREFO MUTE VBS GND VBS 2K 23K 23K GND GND VBS GND VBS SOUT* SIN*- OP*OUT MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER I/O TERMINAL EQUIVALENT CIRCUIT (7) CH1,CH2 power amplifier output terminal equivalent circuit (VM1+, VM1-, VM2+, VM2-) VBS Vm12 VM* The equivalent circuits of an output stage of the power amplifiers are shown in (7). The power supplies of CH1, CH2 are Vm12. And the power supplies of CH3 are Vm3. The source side of the power amplifier output stage consists of a PNP and a NPN. The emitta of the PNP is connected to VBS. So the power of the PNP supplies can be adjusted externally. GND MGND12 (8) CH3 power amplifier output terminal equivalent circuit (VM3+, VM3-) VBS Vm3 VM3* GND About bootstrap advantage The output stage of the power amplifiers consists of the preceding components. If VBS is provided with higher voltage input than Vm* (The recommendation voltage is Vm+1V) externally, the output range can be wider than that of VBS = Vm. Please take advantage of this bootstrap function for the system which has many power supplies. And it is the same with the external bootstrap circuit which provides VBS with higher voltage inputs than Vm*. Also the bootstrap can decrease the saturation voltage at the source side of the power amplifier output stage. Therefore, when the outputs of the power amplifiers which drive motors and actuators are fully swung, the power dissipation of the IC will be decreased. MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER APPLICATION CIRCUIT NO. 1 • Single input (linear signal) • Direct voltage control 1.5V R2 VREF OUT1 + - 1 R1 VCTL1 42 5V 3 4 VBS IN1- 41 IN1+ 40 - + 2 SOUT1 SIN1- 10K OP1OUT ×1 - + OP1- 10K - + 10K OP1+ VM1- 2.5K + - 15K 5 ×6 H: sleep MUTE1 SLEEP 2.5K 15K Ra FOCUS 15K 2.5K + - 6 ×6 1CH 20K VREF input 38 37 36 <Low, OPEN: MUTE ON> MUTE2 1, 2CH 3CH BIAS 15K 5V 39 35 BIAS VM1+ VREF 10K 23K 23K 23K 23K 2.5K 20K Vm12 Vrefm12 + - 7 TSD 8 34 MGND12 9 CH1,CH2 power gnd 10 33 32 11 31 3CH 12 30 2CH 13 2.5K ×6 15K + 24K 20K MCU 20K 5V 10K Vm3 - + R4 10K 20 R7 IN3- R7 IN3+ OUT2 IN2- TP IN2+ + OP2input R6 R5 25 24 23 - OP2OUT VCTL3 26 10K OP2+ 21 2.5V 0V 5V Vrefm3 + - 19 VREF 27 17 18 VREF VM3- 5V 16 ×1 R3 24K 28 4K 2.5K 10K SOUT2 ×6 + - SIN2- VCTL2 - 2.5K + - 15 24K M TRACKING 15K 29 4K 4K VM2- 24K VM3+ TRAY ×6 15K ×6 - VM2+ + - 14 2.5K + 4K 15K 22 Please make an open the 24 pin (TP) terminal! MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER APPLICATION CIRCUIT NO. 2 • Single input (linear signal) • Direct current control (for FOCUS and TRACKING) 1.5V C1 VREF OUT1 + - 1 R3 R1 VCTL1 42 5V 3 R2 4 IN1- VBS - + 2 SOUT1 SIN1- IN1+ 10K 10K - + OP1- 10K - 10K OP1OUT ×1 41 VREF 40 39 VREF input 38 + OP1+ VM1- 2.5K + - 15K 5 FOCUS ×6 MUTE1 SLEEP 2.5K 15K Ra H: sleep Rs VM1+ + - 6 2.5K ×6 1CH <Low, OPEN: MUTE ON> MUTE2 1, 2CH 3CH BIAS 15K 20K 2.5K + - 20K 5V Vrefm12 36 35 BIAS 15K 37 23K 23K 23K 23K Vm12 7 TSD 8 34 MGND12 9 33 CH1,CH2 power gnd 10 32 11 31 3CH 12 30 2CH 13 2.5K 2.5K ×6 + - 10K 10K 28 20K C2 Vrefm3 IN3- TP IN2+ - + OP2OUT OP2VREF input 5V VREF 26 R6 IN3+ OP2+ 21 27 10K 10K - + 20 Vm3 VREF - + ×1 OUT2 19 IN2VREF VM3- 24K 20K 17 18 VCTL2 4K 24K 16 R5 R4 ×6 2.5K 15K R6 M 15 + - 15K 29 24K + - 4K VM2- SOUT2 4K VM3+ 2.5K Ra SIN2- ×6 TRAY ×6 15K Rs + - VM2+ + - TRACKING 14 24K - 4K 15K input R5 VCTL3 25 24 23 22 Please make an open the 24 pin (TP) terminal! MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER APPLICATION CIRCUIT NO. 3 • Differential PWM input (for FOCUS and TRACKING and 3CH) • Direct voltage control C1 1.5V R1 VREF OUT1 + - 1 PWM1- 42 R2 5V 3 IN1- VBS - + 2 SOUT1 SIN1- IN1+ 10K 10K 4 - + 10K OP1OUT ×1 OP1- 10K - + OP1+ VM1- 2.5K + - 15K 5 H: sleep ×6 FOCUS SLEEP 2.5K 15K MUTE1 15K + - 6 VM1+ ×6 1CH PWM1+ R2 39 C1 3.3V 38 37 0V 3.3V VREF 0V 36 <Low, OPEN: MUTE ON> 1, 2CH MUTE2 3CH BIAS 15K 20K 5V 2.5K R1 40 35 BIAS Ra 41 23K 23K 23K 23K 2.5K 20K Vm12 Vrefm12 + - 7 TSD 8 34 MGND12 9 CH1,CH2 power gnd 10 33 32 11 31 3CH 12 30 2CH 13 2.5K ×6 SIN2- 0V 3.3V + - 15 ×6 2.5K 2.5K 15K 10K 10K 17 ×6 4K 24K VM328 24K 20K 3.3V 0V 3.3V 20K Vm3 + - 16 0V 24K M 4K 3.3V 29 4K + - TRACKING Ra 15K VM3+ 2.5K 15K VM2- 24K - 15K ×6 5V - + PWM3- 26 C3 R3 R4 19 R3 20 R4 R5 10K 10K IN3+ OUT2 IN2- C3 TP IN2+ C2 OP2OUT - + OP2+ 21 OP2- VREF PWM3+ 25 + - 18 PWM2+ R5 IN3- C2 PWM2- 0V 27 Vrefm3 ×1 SOUT2 TRAY VM2+ + - 14 + 4K 24 23 22 Please make an open the 24 pin (TP) terminal! MITSUBISHI <CONTROL / DRIVER IC> M56783AFP 3 CHANNEL ACTUATOR DRIVER APPLICATION CIRCUIT NO. 4 • Differential PWM input (for FOCUS and TRACKING and 3CH) • Direct current control (for FOCUS and TRACKING) 1.5V R3 C2 VREF OUT1 + - 1 R1 PWM1- 42 5V 3 R2 IN1- VBS - + 2 SOUT1 SIN1- IN1+ 10K 10K 4 ×1 - + C1 OP1- 10K - + 10K OP1OUT OP1+ VM1- + - 15K 5 ×6 H: sleep MUTE1 SLEEP 2.5K 15K FOCUS Ra 2.5K 2.5K R1 40 R2 PWM1+ 39 3.3V C1 38 37 0V 3.3V 0V VREF 36 <Low, OPEN: MUTE ON> 35 BIAS 15K 41 MUTE2 1, 2CH 3CH Rs + - 6 VM1+ ×6 1CH BIAS 15K 5V 20K 20K 23K 23K 23K 23K 2.5K Vm12 Vrefm12 - + 7 TSD 8 34 MGND12 9 33 CH1,CH2 power gnd 10 32 11 31 3CH 12 30 2CH 13 15K ×6 15 + - 15K 2.5K ×6 15K SIN2- 29 24K 2.5K + - 4K VM2- VM3+ M Ra 3.3V 0V 3.3V 0V 4K 24K 2.5K 15K Rs 2.5K ×6 ×6 4K 24K VM328 24K 20K 3.3V Vm3 10K ×1 27 Vrefm3 - + SOUT2 + - 10K 17 IN3- C4 18 PWM2+ 20 R5 IN3+ OUT2 IN2- OP2OUT R7 25 PWM3+ 24 Please make an open the 24 pin (TP) terminal! C6 IN2+ TP OP2- VREF PWM3- 10K 10K OP2+ 21 C4 R7 26 - + 19 R4 5V C6 C5 R6 - + R4 0V 3.3V 0V 20K 16 R5 PWM2- TRAY + - TRACKING 14 VM2+ + - 4K 23 22