IS31FL3732 AUDIO MODULATED MATRIX LED DRIVER June 2016 GENERAL DESCRIPTION FEATURES The IS31FL3732 is a compact LED driver for 144 single LEDs. The device can be programmed via an I2C compatible interface. The IS31FL3732 offers two blocks each driving 72 LEDs with 1/9 cycle rate. The required lines to drive all 144 LEDs are reduced to 18 by using the cross-plexing feature optimizing space on the PCB. Additionally each of the 144 LEDs can be dimmed individually with 8-bit allowing 256 steps of linear dimming. To reduce CPU usage up to 8 frames can be stored with individual time delays between frames to play small animations automatically. LED frames can be modulated with audio signal. IS31FL3732 is available in QFN-40 (5mm×5mm) package. It operates from 2.7V to 5.5V over the temperature range of -40°C to +85°C. Supply voltage range: 2.7V to 5.5V 1MHz I2C-compatible interface 144 LEDs in dot matrix Individual blink control Individual PWM control 256 steps Individual on/off control Global current control 256 steps Cascade for synchronization of chips 8 frames memory for animations Picture mode and animation mode Auto intensity breathing during the switching of different frames LED frames displayed can be modulated with audio signal intensity LED light intensity can be modulated with audio signal intensity QFN-40 (5mm×5mm) package APPLICATIONS Mobile phones and other hand-held devices for LED display LED in home appliances TYPICAL APPLICATION CIRCUIT Figure 1 Typical Application Circuit Note 1: For the mobile applications the IC should be placed far away from the mobile antenna in order to prevent the EMI. Note 2: The average current of each LED is 3.2mA when REXT = 20kΩ. The LED current can be modulated by the REXT. Please refer to the detail information in Page 18. Note 3: The thermal pad should be connected to GND. Note 4: The VIO should be 1.8V≤ VIO ≤VCC. And it is recommended to be equal to VOH of the micro controller. For example, if VOH=1.8V, set VIO=1.8V is recommended. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 1 VBattery 1 VIO VIO PVCC AVCC 0.47 F 0.1 F 20 0.1 F 0.47 F PVCC CA1 0.47 F 0.1 F 4 CA2 VCC CA3 0.1 F CA4 VIO 100k CA5 1k 1k CA6 21 22 Micro Controller 5 25 CA7 SDA CA8 SCL IS31FL3732 INTB SDB CA9 CB1 CB2 100k CB3 CB4 0.22 F 6 Audio In 30 28 29 REXT 20k 0.1 F 24 23 27 26 CB5 IN CB6 SYNC CB7 R_EXT CB8 C_FILT CB9 32 33 34 35 36 37 38 39 40 11 12 13 14 15 16 17 18 19 A1 Matrix A A2 Matrix B A1 A3 A4 A5 A6 A7 A8 A9 B1 B2 B3 B4 B5 B1 A2 C1-1 C1-2 C1-3 C1-4 C1-5 C1-6 C1-7 C1-8 C1-9 C1-10 C1-11 C1-12 C1-13 C1-14 C1-15 C1-16 B2 A3 C2-1 C2-2 C2-3 C2-4 C2-5 C2-6 C2-7 C2-8 C2-9 C2-10 C2-11 C2-12 C2-13 C2-14 C2-15 C2-16 B3 A4 C3-1 C3-2 C3-3 C3-4 C3-5 C3-6 C3-7 C3-8 C3-9 C3-10 C3-11 C3-12 C3-13 C3-14 C3-15 C3-16 B4 A5 C4-1 C4-2 C4-3 C4-4 C4-5 C4-6 C4-7 C4-8 C4-9 C4-10 C4-11 C4-12 C4-13 C4-14 C4-15 C4-16 B5 A6 C5-1 C5-2 C5-3 C5-4 C5-5 C5-6 C5-7 C5-8 C5-9 C5-10 C5-11 C5-12 C5-13 C5-14 C5-15 C5-16 B6 A7 C6-1 C6-2 C6-3 C6-4 C6-5 C6-6 C6-7 C6-8 C6-9 C6-10 C6-11 C6-12 C6-13 C6-14 C6-15 C6-16 B7 A8 C7-1 C7-2 C7-3 C7-4 C7-5 C7-6 C7-7 C7-8 C7-9 C7-10 C7-11 C7-12 C7-13 C7-14 C7-15 C7-16 B8 A9 C8-1 C8-2 C8-3 C8-4 C8-5 C8-6 C8-7 C8-8 C8-9 C8-10 C8-11 C8-12 C8-13 C8-14 C8-15 C8-16 B9 C9-1 C9-2 C9-3 C9-4 C9-5 C9-6 C9-7 C9-8 C9-9 C9-10 C9-11 C9-12 C9-13 C9-14 C9-15 C9-16 B6 B7 B8 B9 ADDR1 ADDR2 GND 7,8,9,31 VBattery 23 1 ADDR2 VIO PVCC VIO AVCC 0.47 F 0.1 F 20 0.1 F 0.47 F PVCC 0.47 F 0.1 F 4 CA1 VCC CA2 0.1 F CA3 CA4 CA5 CA6 CA7 21 22 5 25 CA8 SDA CA9 SCL IS31FL3732 INTB SDB CB1 CB2 CB3 CB4 CB5 0.22 F 6 Audio In 30 28 REXT 20k 0.1 F 29 24 27 26 CB6 IN SYNC R_EXT CB7 CB8 CB9 32 33 34 35 36 37 38 39 40 11 12 13 14 15 16 17 18 19 C1 C2 C3 C4 C5 C6 C7 C8 C9 D1 D2 D3 D4 D5 D6 D7 Matrix C Matrix D C1 D1 C2 C1-1 C1-2 C1-3 C1-4 C1-5 C1-6 C1-7 C1-8 C1-9 C1-10 C1-11 C1-12 C1-13 C1-14 C1-15 C1-16 D2 C3 C2-1 C2-2 C2-3 C2-4 C2-5 C2-6 C2-7 C2-8 C2-9 C2-10 C2-11 C2-12 C2-13 C2-14 C2-15 C2-16 D3 C4 C3-1 C3-2 C3-3 C3-4 C3-5 C3-6 C3-7 C3-8 C3-9 C3-10 C3-11 C3-12 C3-13 C3-14 C3-15 C3-16 D4 C5 C4-1 C4-2 C4-3 C4-4 C4-5 C4-6 C4-7 C4-8 C4-9 C4-10 C4-11 C4-12 C4-13 C4-14 C4-15 C4-16 D5 C6 C5-1 C5-2 C5-3 C5-4 C5-5 C5-6 C5-7 C5-8 C5-9 C5-10 C5-11 C5-12 C5-13 C5-14 C5-15 C5-16 D6 C7 C6-1 C6-2 C6-3 C6-4 C6-5 C6-6 C6-7 C6-8 C6-9 C6-10 C6-11 C6-12 C6-13 C6-14 C6-15 C6-16 D7 C8 C7-1 C7-2 C7-3 C7-4 C7-5 C7-6 C7-7 C7-8 C7-9 C7-10 C7-11 C7-12 C7-13 C7-14 C7-15 C7-16 D8 C9 C8-1 C8-2 C8-3 C8-4 C8-5 C8-6 C8-7 C8-8 C8-9 C8-10 C8-11 C8-12 C8-13 C8-14 C8-15 C8-16 D9 C9-1 C9-2 C9-3 C9-4 C9-5 C9-6 C9-7 C9-8 C9-9 C9-10 C9-11 C9-12 C9-13 C9-14 C9-15 C9-16 D8 D9 C_FILT ADDR1 GND 7,8,9,31 Figure 2 Typical Application Circuit (Two Parts Synchronization-Work) Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 2 Figure 3 Typical Application Circuit (Eight Parts Synchronization-Work) Note 5: One part is configured as master, all the other 7 parts configured as slave. Work as master or slave specified by Configuration Register (Function register, 00h), and the detail described in Page 14. Master part output master clock, and all the other parts which work as slave input this master clock. The master clock is used for all parts which are connected synchronize Breath /Blink/ Auto Frame Play Mode related timing spec. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 3 PIN CONFIGURATION 31 GND 32 CA1 33 CA2 34 CA3 35 CA4 36 CA5 37 CA6 38 CA7 39 CA8 Pin Configuration (Top View) 40 CA9 Package PVCC 1 29 C_FILT NC 3 28 R_EXT VCC 4 27 VIO INTB 5 26 AVCC IN 6 25 SDB Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 CB9 19 PVCC 20 CB8 18 21 SDA CB7 17 22 SCL NC 10 CB6 16 GND 9 CB5 15 23 ADDR2 CB4 14 GND 8 CB3 13 24 ADDR1 CB1 11 GND 7 CB2 12 QFN-40 30 SYNC NC 2 4 PIN DESCRIPTION No. Pin Description 1,20 PVCC Power supply for internal power block. 2,3,10 NC Not connect. 4 VCC Digital power supply 5 INTB Interrupt output. Active low when movie end in Auto Frame Play Mode. Detail information refers to Page 19. 6 IN Audio input. 7~9,31 GND Digital ground. 11~19 CB1 ~ CB9 LED Matrix B current output/input port. 21 SDA I2C compatible serial data. 22 SCL I2C compatible serial clock. 23 ADDR2 I2C address 2 setting. 24 ADDR1 I2C address 1 setting. 25 SDB Shutdown the chip when pull to low. 26 AVCC Analog power supply. 27 VIO Input logic reference voltage. 28 R_EXT Input terminal used to connect an external resistor. This regulates the global output current. Detail information refers to Page 18. 29 C_FILT Filter capacitor for audio control. 30 SYNC Synchronize signal. It is used for more than one part work synchronize. Detail information refers to Page 20. If it is not used please float this pin. 32~40 CA1 ~ CA9 LED Matrix A current output/input port. Thermal Pad Connect to GND. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 5 ORDERING INFORMATION Industrial Range: -40°C to +85°C Order Part No. Package QTY/Reel IS31FL3732-QFLS2-TR QFN-40, Lead-free 2500 Copyright © 2016 Integrated Silicon Solution, Inc. All rights reserved. ISSI reserves the right to make changes to this specification and its products at any time without notice. ISSI assumes no liability arising out of the application or use of any information, products or services described herein. Customers are advised to obtain the latest version of this device specification before relying on any published information and before placing orders for products. Integrated Silicon Solution, Inc. does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless Integrated Silicon Solution, Inc. receives written assurance to its satisfaction, that: a.) the risk of injury or damage has been minimized; b.) the user assume all such risks; and c.) potential liability of Integrated Silicon Solution, Inc is adequately protected under the circumstances Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 6 ABSOLUTE MAXIMUM RATINGS Supply voltage, VCC Voltage at any input pin Maximum junction temperature, TJMAX Storage temperature range, TSTG Operating temperature range, TA Thermal resistance, junction to ambient, θJA ESD (HBM) ESD (CDM) -0.3V ~ +6.0V -0.3V ~ VCC+0.3V 150°C -65°C ~ +150°C -40°C ~ +85°C 24.96°C/W 8kV 1kV Note: Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only and functional operation of the device at these or any other condition beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS The following specifications apply for VCC = 3.6V, TA = 25°C, unless otherwise noted. Symbol Parameter VCC Supply voltage ICC Quiescent power supply current ISD IOUT VHR tSCAN tSCANOL ILED Conditions Min. Typ. 2.7 Max. Unit 5.5 V Picture Mode, all LEDs off 2.17 VSDB = 0V 0.1 VSDB = VCC, Software Shutdown 1 Function Register 0Ah written “0000 0000”. 230 VSDB = VCC, Software Shutdown 2 Function Register 0Ah written “0000 0010”. 3 Output DC current of CA1~CA9,CB1~CB9 Matrix display mode without audio modulation (Note 1) 34 Current sink headroom voltage C1~C9 ISINK = 270mA (Note 1,2) 350 Current source headroom voltage ISOURCE = 34mA (Note 1) C1~C9 350 Period of scanning (Figure 4) 100 µs Non-overlap blanking time during (Figure 4) scan 14 µs 3.2 mA Shutdown current Average current of each LED mA 1 μA mA mV REXT = 20kΩ, PWM Register written “1111 1111” (Note 3) Logic Electrical Characteristics (SDA, SCL, ADDR1, ADDR2, SYNC, SDB) VIL Logic “0” input voltage VIO=3.6V GND 0.2VIO V VIH Logic “1” input voltage VIO=3.6V 0.75VIO VIO V VOL Logic “0” output voltage for SYNC IOL = 8mA 0.4 V VOH Logic “1” output voltage for SYNC IOH = 8mA 0.75VIO V IIL Logic “0” input current VINPUT = 0V (Note 4) 5 nA IIH Logic “1” input current VINPUT = VIO (Note 4) 5 nA Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 7 DIGITAL INPUT SWITCHING CHARACTERISTICS (Note 4) Fast Mode Symbol Fast Mode Plus Parameter Units Min. fSCL Serial-Clock frequency tBUF Bus free time between a STOP and a START condition Typ. Max. Min. Typ. Max. - 400 - 1000 kHz 1.3 - 0.5 - μs tHD, STA Hold time (repeated) START condition 0.6 - 0.26 - μs tSU, STA Repeated START condition setup time 0.6 - 0.26 - μs tSU, STO STOP condition setup time 0.6 - 0.26 - μs tHD, DAT Data hold time - - - - μs tSU, DAT Data setup time 100 - 50 - ns tLOW SCL clock low period 1.3 - 0.5 - μs tHIGH SCL clock high period 0.7 - 0.26 - μs tR Rise time of both SDA and SCL signals, receiving (Note 5) - 20+0.1Cb 300 - 20+0.1Cb 120 ns tF Fall time of both SDA and SCL signals, receiving (Note 5) - 20+0.1Cb 300 - 20+0.1Cb 120 ns Note 1: In case of REXT = 20kΩ, Global Current Control Register (Function Register, 04h) written “1111 1111”. Note 2: All LEDs are on. Note 3: ILED = 680/(10.5*REXT), REXT = 20kΩ is recommended. The recommended minimum value of REXT is 18kΩ.ILED=IOUT/10.5. Global Current Control Register (Function Register, 04h) written “1111 1111”. Note 4: Guaranteed by design. Note 5: Cb = CI2C+CW, where CW is the parasitic capacitance of SDA/SCL PCB wire and CI2C (2pF, Typ.) is the capacitance of SDA or SCL pins. tR and tF measured between 0.3 × VIO and 0.7 × VIO and ISINK ≤ 6mA. Figure 4 Scanning Timing Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 8 DETAILED DESCRIPTION I2C INTERFACE The IS31FL3732 uses a serial bus, which conforms to the I2C protocol, to control the chip’s functions with two wires: SCL and SDA. The IS31FL3732 has a 7-bit slave address (A7:A1), followed by the R/W bit, A0. Set A0 to “0” for a write command and set A0 to “1” for a read command. The value of bits A1 and A2 are decided by the connection of the ADDR1 pin. The value of bits A3 and A4 are decided by the connection of the ADDR2 pin. The complete slave address is: Table 1 Slave Address: ADDR2 ADDR1 GND GND GND GND SCL SCL SCL SCL SDA SDA SDA SDA VCC VCC VCC VCC GND SCL SDA VCC GND SCL SDA VCC GND SCL SDA VCC GND SCL SDA VCC A7:A5 A4:A3 A2:A1 101 00 00 00 00 01 01 01 01 10 10 10 10 11 11 11 11 00 01 10 11 00 01 10 11 00 01 10 11 00 01 10 11 A0 After the last bit of the chip address is sent, the master checks for the IS31FL3732’s acknowledge. The master releases the SDA line high (through a pull-up resistor). Then the master sends an SCL pulse. If the IS31FL3732 has received the address correctly, then it holds the SDA line low during the SCL pulse. If the SDA line is not low, then the master should send a “STOP” signal (discussed later) and abort the transfer. Following acknowledge of IS31FL3732, the register address byte is sent, most significant bit first. IS31FL3732 must generate another acknowledge indicating that the register address has been received. Then 8-bit of data byte are sent next, most significant bit first. Each data bit should be valid while the SCL level is stable high. After the data byte is sent, the IS31FL3732 must generate another acknowledge to indicate that the data was received. 0/1 ADDR1/2 connected to GND, (A2:A1)/(A4:A3)=00; ADDR1/2 connected to VCC, (A2:A1)/(A4:A3)=11; ADDR1/2 connected to SCL, (A2:A1)/(A4:A3)=01; ADDR1/2 connected to SDA, (A2:A1)/(A4:A3)=10; The SCL line is uni-directional. The SDA line is bidirectional (open-collector) with a pull-up resistor (typically 1kΩ). The maximum clock frequency specified by the I2C standard is 1MHz. In this discussion, the master is the microcontroller and the slave is the IS31FL3732. The timing diagram for the I2C is shown in Figure 5. The SDA is latched in on the stable high level of the SCL. When there is no interface activity, the SDA line should be held high. The “START” signal is generated by lowering the SDA signal while the SCL signal is high. The start signal will alert all devices attached to the I2C bus to check the incoming address against their own chip address. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 The 8-bit chip address is sent next, most significant bit first. Each address bit must be stable while the SCL level is high. The “STOP” signal ends the transfer. To signal “STOP”, the SDA signal goes high while the SCL signal is high. ADDRESS AUTO INCREMENT To write multiple bytes of data into IS31FL3732, load the address of the data register that the first data byte is intended for. During the IS31FL3732 acknowledge of receiving the data byte, the internal address pointer will increment by one. The next data byte sent to IS31FL3732 will be placed in the new address, and so on. The auto increment of the address will continue as long as data continues to be written to IS31FL3732 (Figure 8). READING OPERATION All of registers in IS31FL3732 can be read. But Frame Register can only be read in Software Shutdown 1 as SDB pin is high. The Function Register can be read in all modes. To read the device data, the bus master must first ____ send the IS31FL3732 address with the R/W bit set to “0”, followed by the Command Register (FDh) then send command data which determines which response register is accessed. After a restart, the bus master must send the IS31FL3732 address with the ____ R/W bit set to “0” again, followed by the register address which determines which register is accessed. Then restart I2C, the bus master should send the ____ IS31FL3732 address with the R/W bit set to “1”. Data from the register defined by the command byte is then sent from the IS31FL3732 to the master (Figure 9). 9 IS31FL3732 Figure 5 Interface timing SDA SCL Data Line Stable Data Valid Change of Data Allowed Figure 6 Bit transfer Figure 7 Writing to IS31FL3732 (Typical) Figure 8 Writing to IS31FL3732 (Automatic address increment) Figure 9 Reading from IS31FL3732 Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 10 REGISTER DEFINITION Table 2 FDh Command Register (Write Only) Data Function Data 0000 0000 Point to Page One (Frame 1 Register is available) Function 0000 0001 Point to Page Two (Frame 2 Register is available) 0000 0010 Point to Page Three (Frame 3 Register is available) 0000 0011 Point to Page Four (Frame 4 Register is available) 0000 0100 Point to Page Five (Frame 5 Register is available) 0000 0101 Point to Page Six (Frame 6 Register is available) 0000 0110 Point to Page Seven (Frame 7 Register is available) 0000 0111 Point to Page Eight (Frame 8 Register is available) 0000 1011 Point to Page Nine (Function Register is available) Others Reserved Note: The Command Register should be configured first after writing in the slave address to choose the available register (Frame Register and Function Register). Then write data in the choosing register. Power up default state is “0000 0000”. For example, when write “0000 0011” in the Command Register (FDh), the data which writing after will be stored in the Frame 4 Register. Write new data can configure other registers. Table 3 Response Register Function (The address of each Page is starting from 00h. Frame Registers have the same format.) Address Name Function Table R/W Default Frame Register (Page One to Page Eight) (Note 6) 00h ~ 11h LED Control Register Store on or off state for each LED 4 R/W 12h ~ 23h Blink Control Register Control the blink function for each LED 5 R/W 24h ~ B3h PWM Register 144 LEDs PWM duty cycle data register 6 R/W xxxx xxxx Function Register (Page Night) (Note 7) 00h Configuration Register Configure the operation mode 8 R/W 01h Picture Display Register Set the display frame in Picture Mode 9 R/W 02h Auto Play Control Register 1 Set the way of display in Auto Frame Play Mode 10 R/W 03h Auto Play Control Register 2 Set the delay time in Auto Frame Play Mode 11 R/W 04h Global Current Control Set the global current for all LEDs 12 R/W 05h Display Option Register Set the display option 13 R/W 06h Audio Synchronization Register Set audio synchronization function 14 R/W 07h Frame State Register Store the frame display information 15 R 08h Breath Control Register 1 Set fade in and fade out time for breath function 16 R/W 09h Breath Control Register 2 Set the breath function 17 R/W 0Ah Shutdown Register Set software shutdown mode 18 R/W 0Bh AGC Control Register Set the AGC function and the audio gain. 19 R/W 0Ch Audio ADC Rate Register Set the ADC sample rate of the input signal 20 R/W 0000 0000 Note 6: The data of Frame Registers are random after power up. Please initialize the Frame Registers first to ensure operate normally. Frame Register writing operation must be in case of SDB pin high and Function Register (0Ah) written “0000 0000” (Software Shutdown 1) or “0000 0001” (Normal operation). Read operation asks for SDB pin high and Function Register (0Ah) written “0000 0000” (Software Shutdown 1). Due to max address of Frame Registers is B3h, value ‘110’ and ‘111’ are prohibited for Frame Register address 3 MSB. Note 7: Function registers can be written and read after power up. All function registers power up default state are ‘0000 0000’, once VCC drop to 1.75V (typical) all function registers are reset to their default state in case of SDB pin pulled high. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 11 REGISTER CONTROL For example, if write “0000 0001” into Command Register (FDh), it means choosing Page Two Frame 2 Register to configure. Then next address and data will take effect only for Frame 2 Register unless re-configure Command Register (FDh). FRAME REGISTER Table 4 00h ~ 11h LED Control Register Bit D7:D0 Name CX-8 : CX-1 or CX-16 : CX-9 Default xxxx xxxx The LED Control Registers store the on or off state of each LED in the Matrix A and B. Please refer to the detail information in Table 7. LED State Bit LED off LED on CX-Y 0 1 Figure 10 in Page 13 shows the ordering of CX-Y. Figure 10 in Page 13 shows the ordering of CX-Y. Table 6 24h ~ B3h PWM Register Bit D7:D0 Name PWM Default xxxx xxxx PWM Registers modulate the 144 LEDs average current in 256 steps. The value of the PWM Registers decides the output average current of each LED noted ILED. ILED computed by Formula (1): I LED D7:D0 Name CX-8 : CX-1 or CX-16 : CX-9 Default xxxx xxxx The Blink Control Registers configure the blink function of each LED in the Matrix A and B. Please refer to the detail information in Table 7. CX-Y 0 1 Blink Control Bit Disable Enable Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 (1) 7 PWM D[n ] 2 n Table 5 12h ~ 23h Blink Control Register Bit 1 PWM I OUT 256 10.5 n 0 Where D[n] stands for the individual bit value, 1 or 0, in location n. For example: if D7:D0 = 10110101, I LED 2 0 2 2 2 4 25 2 7 1 I OUT 256 10.5 IOUT is output DC current which can be set by the GCC bit of Global Current Control Register (04h) and REXT. Detail information refers to Table 12 in Page 15. 12 Table 7 Address of Frame Register LED Location LED Control Register Blink Control Register PWM Register Matrix A Matrix B Matrix A Matrix B Matrix A Matrix B Matrix A Matrix B CA1(C1-1~C1-8) CB1(C1-9~C1-16) 00h 01h 12h 13h 24h ~ 2Bh 2Ch ~ 33h CA2(C2-1~C2-8) CB2(C2-9~C2-16) 02h 03h 14h 15h 34h ~ 3Bh 3Ch ~ 43h CA3(C3-1~C3-8) CB3(C3-9~C3-16) 04h 05h 16h 17h 44h ~ 4Bh 4Ch ~ 53h CA4(C4-1~C4-8) CB4(C4-9~C4-16) 06h 07h 18h 19h 54h ~ 5Bh 5Ch ~ 63h CA5(C5-1~C5-8) CB5(C5-9~C5-16) 08h 09h 1Ah 1Bh 64h ~ 6Bh 6Ch ~ 73h CA6(C6-1~C6-8) CB6(C6-9~C6-16) 0Ah 0Bh 1Ch 1Dh 74h ~ 7Bh 7Ch ~ 83h CA7(C7-1~C7-8) CB7(C7-9~C7-16) 0Ch 0Dh 1Eh 1Fh 84h ~ 8Bh 8Ch ~ 93h CA8(C8-1~C8-8) CB8(C8-9~C8-16) 0Eh 0Fh 20h 21h 94h ~ 9Bh 9Ch ~ A3h CA9(C9-1~C9-8) CB9(C9-9~C9-16) 10h 11h 22h 23h A4h ~ ABh ACh ~ B3h Figure 10 LED Array Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 13 FUNCTION REGISTER Table 8 00h Configuration Register Bit D7:D6 D5 D4:D3 D2:D0 Name SYNC - MODE FS Default 00 0 00 000 The Configuration Register sets operating mode of IS31FL3732. SYNC 00/11 01 10 Synchronize Configuration High Impedance Master Slave MODE 00 01 1x Display Mode Picture Mode Auto Frame Play Mode Audio Frame Play Mode PFS Picture Frame Selection (Available in Picture Mode) 000 Frame 1 001 Frame 2 010 Frame 3 011 Frame 4 100 Frame 5 101 Frame 6 110 Frame 7 111 Frame 8 Table 10 02h Auto Play Control Register 1 Bit D7 D6:D4 D3 D2:D0 Name - CNS - FNS Default 0 000 0 000 The Auto Play Control Register 1 sets the way of display in Auto Frame Play Mode. FS Frame Start (Available in Auto Frame Play Mode) 000 Frame 1 001 Frame 2 010 Frame 3 011 Frame 4 100 Frame 5 101 Frame 6 110 Frame 7 111 Frame 8 CNS Number of Loops Playing Selection (Available in Auto Frame Play Mode) 000 Play endless 001 1 loop 010 2 loops 011 3 loops 100 4 loops 101 5 loops 110 6 loops 111 7 loops FS bit sets the start frame in Auto Frame Play Mode. Movie starts from Frame 4 when the FS bit is set to “011”. The FS bit is only available in Auto Frame Play Mode. Table 9 01h Picture Display Register Bit D7:D3 D2:D0 Name - PFS Default 00000 000 The Picture Display Register sets display frame in Picture Mode. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 FNS Number of Frames Playing Selection (Available in Auto Frame Play Mode) 000 All Frame 001 1 frame 010 2 frames 011 3 frames 100 4 frames 101 5 frames 110 6 frames 111 7 frames Movie will be stop in the next frame of the cycle. For example, FS bit is set to “011”, CNS bit is set to “011” and FNS bit is set to “011”. Then the movie will play from Frame 4 to Frame 6 and play three times it stops in Frame 7. 14 Table 11 03h Auto Play Control Register 2 Bit D7:D6 D5:D0 Name - A Default 00 000000 The Auto Play Control Register 2 sets the delay time in Auto Frame Play Mode (Figure 14). FDT Frame Delay Time (Available in Auto Frame Play Mode) If A = 0, FDT = τ×64; If A = 1~63, FDT = τ×A; A = 0~63 and τ = 11ms (Typ.); For example, when A = 23, FDT is 11ms×23 = 253ms Table 12 04h Global Current Control Register Bit D7:D0 Name GCC Default 0000 0000 The Global Current Control Register modulates all LEDs DC current which is noted as IOUT in 256 steps. IOUT is computed by the Formula (2): I OUT GCC 680 256 REXT Table 14 06h Audio Synchronization Register Bit D7:D1 D0 Name - AE Default 0000000 0 The Audio Synchronization Register sets audio synchronization function. AE Audio Synchronization Enable 0 Audio synchronization disable 1 Enable audio signal to modulate the intensity of the matrix (2) Table 15 07h Frame State Register (Read Only) GCC D[n ] 2 n n 0 Where D[n] stands for the individual bit value, 1 or 0, in location n. For example: if D7:D0 = 10110101, 2 0 2 2 2 4 2 5 2 7 680 256 REXT REXT is the external resistor to set DC current, detail information please refers to Page 18. Table 13 05h Display Option Register Bit D7:D6 D5 D4 D3 D2:D0 Name - IC - BE A Default 00 0 0 0 000 The Display Option Register sets display option of IS31FL3732. IC 0 1 BPT Blink Period Time BPT = τ×A; A = 0~7, τ = 0.27s (Typ.); For example, when A = 5, BPT is 0.27s×5 = 1.35s. The duty cycle for blink function is 50%. The intensity of matrix can be modulated by the audio input signal basing on each LED’s current is set by PWM when the AE bit is set to “1”. 7 I OUT Blink Enable Disable Enable BE 0 1 Intensity Control Set the intensity of each frame independently Use intensity setting of frame 1 for all other frames Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 Bit D7:D5 D4 D3 D2:D0 Name - INT - CFD Default - The Frame State Register stores the frame display information. INT Interrupt Bit (Available in Auto Frame Play Mode) 0 Movie has not finished 1 Movie has finished CFD 000 001 010 011 100 101 110 111 Current Frame Display Frame 1 Frame 2 Frame 3 Frame 4 Frame 5 Frame 6 Frame 7 Frame 8 The INT bit will be set to “1” automatically when movie is end in Auto Frame Play Mode. The INT bit can be cleared up by reading the Frame State Register. 15 Table 19 0Bh AGC Control Register Table 16 08h Breath Control Register 1 Bit D7 D6:D4 D3 D2:D0 Bit D7:D5 D4 D3 D2:D0 Name - A - B Name - AGCM AGC AGS Default 0 000 0 000 Default 000 0 0 000 The Breath Control Register 1 sets fade in and fade out time for breath function. The AGC Control Register sets the AGC function and the audio gain. FOT Fade Out Time FOT = τ×2A A = 0~7, τ = 26ms (Typ.) For example, when A = 4, FOT is 26ms×24 = 416ms AGCM 0 1 AGC Mode Slow Mode Fast Mode AGC 0 1 AGC Enable Disable Enable AGS 000 001 010 011 100 101 110 111 Audio Gain Selection 0dB 3dB 6dB 9dB 12dB 15dB 18dB 21dB FIT Fade In Time FIT = τ×2B B = 0~7, τ = 26ms (Typ.) For example, when A = 4, FIT is 26ms×24 = 416ms Table 17 09h Breath Control Register 2 Bit D7:D5 D4 D3 D2:D0 Name - B_EN - A Default 000 0 0 000 The Breath Control Register 2 sets the breath function. B_EN Breath Enable (Available in Picture Mode and Auto Frame Play Mode) 0 Disable 1 Enable ET Extinguish Time ET = τ×2A A = 0~7, τ = 3.5ms (Typ.) For example, when A = 4, ET is 3.5ms×24 = 56ms Table 18 0Ah Shutdown Register Bit D7:D2 D1:D0 Name - SSD Default 000000 00 The Shutdown Register sets software shutdown. SSD 00 01 1x The AGS bit is available in Audio Frame Play Mode and audio synchronization mode. Table 20 0Ch Audio ADC Rate Register Bit D7:D0 Name A Default 0000 0000 The Audio ADC Rate Register sets the ADC sample rate of the input signal in Audio Frame Play Mode. AAR Audio ADC Rate (Available in Audio Frame Play Mode) If A = 0, AAR = τ×256 If A = 1~255, AAR = τ×A τ = 46μs (Typ.) For example, when A = 14, AAR is 46μs×14 = 644μs Software Shutdown Control Software Shutdown 1 Normal Operation Software Shutdown 2 Frame Register and Function Register all can be written and read during Software Shutdown 1. Frame Register cannot be written during Software Shutdown 2. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 16 FUNCTIONAL BLOCK DIAGRAM VIO Frame Register SDA SCL ADDR1 I2C Interface INTB Function Register ADDR2 SYNC IN C_FILT VIO Digital Control Logic VIO Sync Interface Audio Signal Process SDB Current Sink CA1~CA9 CB1~CB9 PVCC AVCC Current Source VCC GND R_EXT Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 17 APPLICATION INFORMATION (The description below is for the Function Register unless otherwise noted.) PWM CONTROL The brightness of 144 LEDs can be modulated with 256 steps by PWM Register. For example, if the data in PWM Register is “0000 0100”, then the PWM is the fourth step. Writing new data continuously to the registers can modulate the brightness of the LEDs to achieve a breathing effect. EXTERNAL RESISTOR (REXT) The average output current of each LED can be adjusted by the external resistor, REXT, as described in Formula (3). I LED PWM GCC 680 1 256 256 REXT 10.5 (3) display. Since the IS31FL3732 can modulate the brightness of the LEDs with 256 steps, a gamma correction function can be applied when computing each subsequent LED intensity setting such that the changes in brightness matches the human eye's brightness curve. Table 21 32 Gamma Steps with 256 PWM Steps C(0) C(1) C(2) C(3) C(4) C(5) C(6) C(7) 0 1 2 4 6 10 13 18 C(8) C(9) C(10) C(11) C(12) C(13) C(14) C(15) 22 28 33 39 46 53 61 69 C(16) C(17) C(18) C(19) C(20) C(21) C(22) C(23) 78 86 96 106 116 126 138 149 C(24) C(25) C(26) C(27) C(28) C(29) C(30) C(31) 161 173 186 199 212 226 240 255 Where PWM is PWM Register (Frame Register, 04h~B3h) data showing in Page 12 Table 6, and GCC is Global Current Control Register (Function Register, 04h) data showing in Page 15 Table 12. And PWM=255, GCC=255. 160 128 64 The recommended minimum value of REXT is 18kΩ. 32 0 LED CURRENT (ILED) 0 The LED average current can be set by 3 factors: 1. REXT, resistant which is connected R_EXT pin and GND. REXT set all LED DC current value. 2. Global Current Control Register (Function Register, 04h). This register control global current, set all LED DC current by 256 steps. Details refer to Page 15. 3. PWM Registers (Frame Register, 04h~B3h), every LED has an own PWM register. PWM Registers set individual LED current by 256 steps. Details refer to Page 12. PWM GCC 680 1 256 256 REXT 10.5 192 96 255 255 1 680 3.21mA 256 256 10.5 20k I LED 224 PWM Data For example, in Figure 1, REXT = 20kΩ, So I LED 256 4 8 12 16 20 24 28 32 Intensity Steps Figure 11 Gamma Correction (32 Steps) Choosing more gamma steps provides for a more continuous looking breathing effect. This is useful for very long breathing cycles. The recommended configuration is defined by the breath cycle T. When T=1s, choose 32 gamma steps, when T=2s, choose 64 gamma steps. The user must decide the final number of gamma steps not only by the LED itself, but also based on the visual performance of the finished product. (3) GAMMA CORRECTION In order to perform a better visual LED breathing effect we recommend using a gamma corrected PWM value to set the LED intensity. This results in a reduced number of steps for the LED intensity setting, but causes the change in intensity to appear more linear to the human eye. Gamma correction, also known as gamma compression or encoding, is used to encode linear luminance to match the non-linear characteristics of Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 18 Table 22 64 Gamma Steps with 256 PWM Steps C(0) C(1) C(2) C(3) C(4) C(5) C(6) C(7) 0 1 2 3 4 5 6 7 C(8) C(9) C(10) C(11) C(12) C(13) C(14) C(15) 8 10 12 14 16 18 20 22 C(16) C(17) C(18) C(19) C(20) C(21) C(22) C(23) 24 26 29 32 35 38 41 44 C(24) C(25) C(26) C(27) C(28) C(29) C(30) C(31) 47 50 53 57 61 65 69 73 C(32) C(33) C(34) C(35) C(36) C(37) C(38) C(39) 77 81 85 89 94 99 104 109 C(40) C(41) C(42) C(43) C(44) C(45) C(46) C(47) 114 119 124 129 134 140 146 152 C(48) C(49) C(50) C(51) C(52) C(53) C(54) C(55) 158 164 170 176 182 188 195 202 C(56) C(57) C(58) C(59) C(60) C(61) C(62) C(63) 209 216 223 230 237 244 251 255 256 PWM Data 224 Register (00h). The Auto Play Control Register 1 (02h) can configure the display cycle and display frames. Configure the Auto Play Control Register 2 (03h), Breath Control Register 1 (08h) and Breath Control Register 2 (09h) can set the breath time between two frames switching. AUDIO FRAME PLAY MODE By setting the MODE bit of the Configuration Register (00h) to “1x”, the IS31FL3732 operates in Audio Frame Play Mode. It stores data of 8 frames and the 8 frames playing follow the input signal. 0Ch register is used to set the ADC sample rate for the input signal to control frames playing. It plays the first frame when the value is the smallest and plays the eighth frame when the value is the biggest. AUDIO MODULATED AND GAIN SETTING By setting the AE bit of the Audio Synchronization Register (06h) to “1”, IS31FL3732 operates with audio synchronization. The intensity of LEDs is adjusted by the input signal. The audio input gain can be set by the AGC Control Register (0Bh). 192 BLINK FUNCTION SETTING 160 By setting the BE bit of the Display Option Register (05h) to “1”, blink function enable. If the BE bit is set to “1”, each LED can be controlled by the Blink Control Registers (12h~23h in Page One to Page Eight). The Display Option Register (05h) is used to set the blink period time, BPT, and the duty cycle is 50% (Figure 13). 128 96 64 32 0 0 8 16 24 32 40 48 56 64 Intensity Steps Figure 12 Gamma Correction (64 Steps) Note: The data of 32 gamma steps is the standard value and the data of 64 gamma steps is the recommended value. Figure 13 Blink Function OPERATING MODE BREATHING FUNCTION SETTING IS31FL3732 has three operating modes, Picture Mode, Auto Frame Play Mode and Audio Frame Play Mode. When IS31FL3732 switches playing frame, breath function is available. By setting the B_EN bit of the Breath Control Register 2 (09h) to “1”, breath function enable. When set the B_EN bit to “0”, breath function disables. PICTURE MODE By setting the MODE bit of the Configuration Register (00h) to “00”, the IS31FL3732 operates in Picture Mode. Set the PFS bit of Picture Display Register (01h) to choose the display frame. The Picture Mode can be operating with breath function by configuring Breath Control Register 2 (09h). AUTO FRAME PLAY MODE By setting the MODE bit of the Configuration Register (00h) to “01”, the IS31FL3732 operates in Auto Frame Play Mode. It stores data of 8 frames and automatically plays in order. Customers can configure the delay time between each two frames and the first playing frame by setting the FS bit of Configuration Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 Figure 14 Breathing Function INTERRUPT CONTROL When IS31FL3732 is playing frame in the Auto Frame Play Mode, the INTB pin is high and the INT bit of Frame State Register (07h) is “0”. It will be pulled low as movie end and the INT bit will be set to “1” at the same time. 19 The INTB pin will be pulled high after reading Frame State Register (07h) operation or it will be pulled high automatically after it stays low for 9ms (Typ.). The INT bit will be reset to “0” only after reading Frame State Register (07h) operation. Cx1 SYNCHRONIZE FUNCTION SYNC bit of the Configuration Register (00h) sets SYNC pin input or output synchronize clock signal. It is used for more than one part working synchronize. When SYNC bit is set to “01”, SYNC pin output synchronize clock to synchronize other parts as master. When SYNC bit is set to “10”, SYNC pin input synchronize clock and work synchronization with this input signal as slave. When SYNC bit is set to “00/11”,SYNC pin is high impedance. Synchronize function is disabled. SYNC bit default state is “00” and SYNC pin is high impedance when power up. Cx2 C1-1 C1-2 C1-3 C1-4 C1-5 C1-6 C1-7 C1-8 Cx3 C2-1 C2-2 C2-3 C2-4 C2-5 C2-6 C2-7 C2-8 Cx4 C3-1 C3-2 C3-3 C3-4 C3-5 C3-6 C3-7 C3-8 Cx5 C4-1 C4-2 C4-3 C4-4 C4-5 C4-6 C4-7 C4-8 Cx6 C5-1 C5-2 C5-3 C5-4 C5-5 C5-6 C5-7 C5-8 Cx7 C6-1 C6-2 C6-3 C6-4 C6-5 C6-6 C6-7 C6-8 Cx8 C7-1 C7-2 C7-3 C7-4 C7-5 C7-6 C7-7 C7-8 Cx9 C8-1 C8-2 C8-3 C8-4 C8-5 C8-6 C8-7 C8-8 C9-1 C9-2 C9-3 C9-4 C9-5 C9-6 C9-7 C9-8 Figure 16 Common Cathode RGBs Connection LED MATRIX CIRCUIT The IS31FL3732 can drive 144 LEDs totally. Part of LEDs can if there is no need to use all 144 LEDs (Figure 15). But the LEDs which are no connected must be off by LED Control Register (Frame Register) or it will affect other LEDs. Cx1 Cx2 C1-9 C1-10 C1-11 C1-12 C1-13 C1-14 C1-15 C1-16 Cx3 C2-9 C2-10 C2-11 C2-12 C2-13 C2-14 C2-15 C2-16 Cx4 C3-9 C3-10 C3-11 C3-12 C3-13 C3-14 C3-15 C3-16 Cx5 C4-9 C4-10 C4-11 C4-12 C4-13 C4-14 C4-15 C4-16 Matrix A CA1 CA2 C1-1 C1-2 C1-3 C1-4 C1-5 C1-6 C1-7 C1-8 Cx6 C5-9 C5-10 C5-11 C5-12 C5-13 C5-14 C5-15 C5-16 CA3 C2-1 C2-2 C2-3 C2-4 C2-5 C2-6 C2-7 C2-8 Cx7 C6-9 C6-10 C6-11 C6-12 C6-13 C6-14 C6-15 C6-16 CA4 C3-1 C3-2 C3-3 C3-4 C3-5 C3-6 C3-7 C3-8 Cx8 C7-9 C7-10 C7-11 C7-12 C7-13 C7-14 C7-15 C7-16 CA5 C4-1 C4-2 C4-3 C4-4 C4-5 C4-6 C4-7 C4-8 Cx9 C8-9 C8-10 C8-11 C8-12 C8-13 C8-14 C8-15 C8-16 CA6 C5-1 C5-2 C5-3 C5-4 C5-5 C5-6 C5-7 C9-9 C9-10 C9-11 C9-12 C9-13 C9-14 C9-15 C9-16 CA7 C6-1 C6-2 C6-3 C6-4 C6-5 C6-6 C6-7 CA8 C7-1 C7-2 C7-3 C7-4 C7-5 C7-6 C7-7 CA9 C8-1 C8-2 C8-3 C8-4 C8-5 C8-6 C8-7 C8-8 C9-1 C9-2 C9-6 C9-7 C9-8 Figure 17 Common Anode RGBs Connection MORE FRAMES DISPLAY Figure 15 No C9-3~C9-5, C5-8~C9-8 DRIVE RGBS MATRIX The IS31FL3732 can drive 32 common cathode / common anode RGBs at best (Figure 16 and 17). The location of red LED must follow the below circuit and the black location could connect single LED except red one, or the IC can’t work normally. Note, the LEDs which are no connected must be off by LED Control Register (Frame Register) or it will affect other LEDs. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 The IS31FL3732 can store 8 frames data at best. Each 4 frames writing in Frame Registers is recommended if there are more frames to play (Figure 18). First, store 8 frames data and play 4 frames in front. Then play last 4 frames and writing new data in the Frame Registers (1~4) at the same time. Play the new 4 frames (1~4) and write new data in the Frame Registers (5~8). 20 Registers Reset 8 frames data write into Frame Registers When SDB pin is pulled low, all registers won’t be reset. During SDB pin pulled high, Function Registers are reset to “0000 0000” once VCC drop below 1.75V (Typ.). SDB pin hold in low voltage state (Hardware Shutdown), all analog circuits are shutdown. The Function Register still can be reset in case of Hardware Shutdown when VCC drops below 0.1V. Play 1~4 frames Play end Interrupt sign Play 5~8 frames New data write into 1~4 Frame Registers Play end Interrupt sign Play end Interrupt sign Play 1~4 frames New data write into 5~8 Frame Registers All data play end All data play end Play end Figure 18 More Frame Data Writing In SHUTDOWN MODE Shutdown mode can be used as a means of reducing power consumption. During shutdown mode all registers retain their data. Software Shutdown By setting SSD bit of the Shutdown Register (0Ah) to “00”, the IS31FL3732 will operate in Software Shutdown 1. When the IS31FL3732 is in Software Shutdown 1, all current sources are switched off, so that the matrix is blanked. All registers (include Function Register and Frame Register) can be written or read when the SDB pin is pulled high. Typical current consume is 230μA. By setting SSD bit to “10” or “11”, the IS31FL3732 will operate in Software Shutdown 2. When the IS31FL3732 is in Software Shutdown 2, all current sources are turned off, the matrix is blanked. Function Register can be written or read. Frame Register can not be written or read. Typical current consume is 3μA. Frame Register constructed by SRAM. Frame Registers are random state after power up, and only can be changed by I2C writing operation. Hardware Shutdown The chip enters Hardware Shutdown when the SDB pin is pulled low. All analog circuits are disabled during Hardware Shutdown, typical current consume is 0.1μA. The chip enters Hardware Enable when the SDB pin is pulled high. During Hardware Shutdown state Function Register can be written and read, but Frame Register cannot be written and read. If VCC has risk drop below 1.75V but above 0.1V during SDB pulled low, please re-initialize all Function Registers before SDB pulled high. POWER DISSIPATION The power dissipation of the IS31FL3732 can calculate as below: P3732=IPVCC×PVCC+ ICC×VCC(AVCC)-IPVCC×VF(AVR) (4) ≈IPVCC×PVCC - IPVCC×VF(AVR) =IPVCC×(PVCC - VF(AVR)) Where IPVCC is the current of PVCC and VF(AVR) is the average forward of all the LED. For example, if REXT=20kΩ, GCC=255, PWM=255, PVCC=5V, VF(AVR)=3.4V@34mA, then the IPVCC=(34mA×8×9/10.5)x2=466.29mA. P3732=466.29mA×(5V-3.4V)=0.746W When operating the chip at high ambient temperatures, or when driving maximum load current, care must be taken to avoid exceeding the package power dissipation limits. The maximum power dissipation can be calculated using the following Formula (5): PD ( MAX ) 125C 25C RJA (5) So, PD ( MAX ) Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 125 C 25C 4W 24.96 C / W 21 Figure 19, shows the power derating of the IS31FL3732 on a JEDEC boards (in accordance with JESD 51-5 and JESD 51-7) standing in still air. 5 Power Dissipation (W) QFN-40 4 3 2 1 0 -40 -25 -10 5 20 35 50 65 80 95 110 125 Temperature (°C) Figure 19 Dissipation Curve Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 22 APPLICATION DESIGN Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 23 CLASSIFICATION REFLOW PROFILES Profile Feature Pb-Free Assembly Preheat & Soak Temperature min (Tsmin) Temperature max (Tsmax) Time (Tsmin to Tsmax) (ts) 150°C 200°C 60-120 seconds Average ramp-up rate (Tsmax to Tp) 3°C/second max. Liquidous temperature (TL) Time at liquidous (tL) 217°C 60-150 seconds Peak package body temperature (Tp)* Max 260°C Time (tp)** within 5°C of the specified classification temperature (Tc) Max 30 seconds Average ramp-down rate (Tp to Tsmax) 6°C/second max. Time 25°C to peak temperature 8 minutes max. Figure 20 Classification Profile Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 24 PACKAGE INFORMATION QFN-40 Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 25 RECOMMENDED LAND PATTERN Note: 1. Land pattern complies to IPC-7351. 2. All dimensions in MM. 3. This document (including dimensions, notes & specs) is a recommendation based on typical circuit board manufacturing parameters. Since land pattern design depends on many factors unknown (eg. user’s board manufacturing specs), user must determine suitability for use. Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 26 REVISION HISTORY Revision Detail Information Date A Initial release 2015.09.06 B 1. Revise VCC MAXIMUM RATINGS from 5.5V to 6.0V 2. Update Figure 1, 2, 10, Formula(1)(2)(3) 3. Add θJA in ABSOLUTE MAXIMUM RATINGS table 4. Add POWER DISSIPATION section in APPLICATION INFORMATION 2016.06.22 Integrated Silicon Solution, Inc. – www.issi.com Rev. B, 06/22/2016 27