MSDL (Mobile Shrink Data Link) Transceivers for Mobile Phones Data rate 1350Mbps RGB Interface BU7963GUW No.10058EAT05 ●Description BU7963GUW is a differential serial interface connecting mobile phone LCD modules to the host CPU. Unique technology is utilized for lower power consumption and EMI. MSDL minimizes the number of wires required - an important consideration in hinge phones - resulting in greater reliability and design flexibility. ●Features 1) MSDL3 high-speed differential interface with a maximum transfer rate of 1350 Mbps. 2) Compatible with24-bit RGB video mode for LCD controller-to-LCD interface. 3) Pixel clock frequency range from 4 to 45MHz. 4) Depending on the data transfer rate, one, two or three differential data channels can be selected. ●Applications Serial Interface for LCD Display Interface of Mobile Devices Application. ●Absolute Maximum Ratings: Parameter Power Supply Voltage Input Voltage Output Voltage Input Current Symbol Ratings Unit Remarks DVDD -0.3 ~ +2.5 V - MSVDD VIN VOUT -0.3 ~ +2.5 V -0.3 ~ MSVDD+0.3 V I/O terminals of MSVDD line -0.3 ~ DVDD+0.3 V I/O terminals of DVDD line -0.3 ~ MSVDD+0.3 V I/O terminals of MSVDD line -0.3 ~ DVDD+0.3 V I/O terminals of DVDD line -10 ~ +10 mA IIN - - Output Current IOUT -70 ~ +70 mA - Preservation Temperature Tstg -55 ~ +125 ℃ - Unit Conditions ●Operating Conditions: Parameter Symbol Ratings Min Typ Max Supply Voltage for DVDD VDVDD 1.65 1.80 1.95 V Supply Voltage for MSVDD VMSVDD 1.65 1.80 1.95 V Data Transmission Rate DR 120 - 450 Mbps/ch - Operating Temperature Range Topr -30 25 85 ℃ - www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 1/19 VDVDD = VMSVDD 2010.04 - Rev.A Technical Note BU7963GUW ●Package View 1PIN MARK 5.0±0.1 BU7963 LOT NO. 0.9 MAX 5.0±0.1 0.10 S 0.08 S 0.75±0.1 0.75±0.1 A P = 0.5×7 0.5 63-φ0.295±0.05 0.05 M S AB H B G P = 0.5×7 F E D C B A 1 2 3 4 5 6 7 8 (UNIT:mm) Fig.1. Package View (VBGA063W050) www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 2/19 2010.04 - Rev.A Technical Note BU7963GUW ●Block Diagram DVDD MSVDD High Speed I/F D0+ Parallel to Serial D0- PD[26:0] D1+ Odd Parity I/F Logic D1- CKD D2+ D2- PCLK PCLK Control Timing Generator Tx PLL Tx CLK+ CLK- XSD LS[1:0] RVS POL_PCLK PLL_BW Reset Generator Clock Detection Control Logic Reference DRVR TEST[1:0] DGND MSGND Fig.2. Block Diagram www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 3/19 2010.04 - Rev.A Technical Note BU7963GUW ●Pin Layout A 1 2 3 4 5 6 7 8 TEST0 PD19 PD17 PD16 PD14 PD13 PD10 CKD PCLK PD18 PD15 PD12 PD11 PD9 PD8 B C PD22 PD20 PLL_BW DVDD N.C. RVS PD7 PD6 D PD23 PD21 N.C. DGND DGND DVDD PD4 PD5 E PD25 PD24 DVDD DGND MSGND N.C. PD1 PD3 F PD26 LS0 MSVDD MSGND MSVDD N.C. XSD PD2 G LS1 POL_ PCLK D2+ (D0+) D1+ (CLK+) CLK+ (D1+) D0+ (D2+) N.C. PD0 H N.C. N.C. D2(D0-) D1(CLK-) CLK(D1-) D0(D2-) DRVR TEST1 Fig.3. Pin Layout (Top View) www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 4/19 2010.04 - Rev.A Technical Note BU7963GUW ●Pin Functions Table 1. Power Supply and Ground Power Supply / Ground : 10-pin Name Width Functions DVDD 3 CMOS I/O and logic core power supply. MSVDD 2 Analog core power supply. DGND 3 CMOS I/O and logic core ground. MSGND 2 Analog core ground. Table 2. MSDL3 High-Speed Serial Interface 8-pin Shutdown Equivalent Schematic CLK+ pin When RVS = ‘L’ : CLK+ When RVS = ‘H’ : D1+ Hi-Z D O CLK- pin When RVS = ‘L’ : CLKWhen RVS = ‘H’ : D1- Hi-Z D Analog O D0+ pin When RVS = ‘L’ : D0+ When RVS = ‘H’ : D2+ Hi-Z D 1 Analog O D0- pin When RVS = ‘L’ : D0When RVS = ‘H’ : D2- Hi-Z D D1+ 1 Analog O D1+ pin When RVS = ‘L’ : D1+ When RVS = ‘H’ : CLK+ Hi-Z D D1- 1 Analog O D1- pin When RVS = ‘L’ : D1When RVS = ‘H’ : CLK- Hi-Z D D2+ 1 Analog O D2+ pin When RVS = ‘L’ : D2+ When RVS = ‘H’ : D0+ Hi-Z D D2- 1 Analog O D2- pin When RVS = ‘L’ : D2When RVS = ‘H’ : D0- Hi-Z D Shutdown Equivalent Schematic - D Name Width Level I/O CLK+ 1 Analog O CLK- 1 Analog D0+ 1 D0- Functions Table 3. Analog Analog 1-pin Name Width Level I/O DRVR 1 Analog - www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. Functions 10kΩ±5% register should be connected between DRVR and MSGND. 5/19 2010.04 - Rev.A Technical Note BU7963GUW Table 4. Parallel Data Interface Parallel Data Interface 29-pin Shutdown Equivalent Schematic PCLK interface. Input A I Parallel data interface. Input A O Output of PCLK detection result. ‘L’: clock stop. ‘H’: clock detect. ‘L’ C Shutdown Equivalent Schematic Name Width Level I/O PCLK 1 CMOS I PD[26:0] 27 CMOS CKD 1 CMOS Functions Table 5. Control Control 8-pin Name Width Level I/O Functions XSD 1 CMOS I Shutdown pin. ‘L’: shutdown. ‘H’: normal operation. Input A LS0 1 CMOS I Selection of the number of data channel and the data format. *Refer to "Selection of the number of MSDL3 channels". *Set the same number of data channel between the TX device and the RX device. Input A LS1 1 RVS 1 CMOS I Selection of MSDL3 pins assignment. ‘L’: Default matrix. ‘H’: Flipped matrix. Input A PLL_BW 1 CMOS I Selection of PLL bandwidth. Input A POL_PCLK 1 CMOS I Selection of input clock polarity. ‘L’: sample parallel data at falling. ‘H’: sample parallel data at rising. Input A TEST0 1 I Test mode pin. ‘L’: normal mode. ‘H’: test mode. Must be ‘L.’ Pull down TEST1 1 Input B DVDD DVDD A B B MSVDD DVDD C D Fig.4. Equivalent Schematics www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 6/19 2010.04 - Rev.A Technical Note BU7963GUW ●Operation Control MSDL3 Channel Count Selection Pin LS is used to control the high-speed data channel count and data format. The LS pin settings (i.e., high-speed data channel count, data format) should be the same between the transmitting and receiving devices (the BU7963GUW and BU7964GUW, respectively). Table 6 shows the PCLK input frequency ranges and transmission data rate ranges for the LS pin settings. Table 6. The Range of The Transmission Data rate LS1 LS0 The Number of Data Channel The Range of PCLK Input Frequency [MHz] The Range of The Data Transmission Rate [Mbits/sec] ‘L’ ‘L’ 1-channel 4.0-15.0 120-450 ‘L’ ‘H’ 2-channel 8.0-30.0 240-900 ‘H’ ‘L’ 3-channel 12.0-45.0 360-1350 ‘H’ ‘H’ Inhibit setting. MSDL3 Pin Assignment RVS determines the assignment of MSDL3 pins, CLK+ / CLK−, D0+ / D0−, D1+ / D1− and D2+ / D2-. Only the MSDL3 high-speed signaling pins are affected by RVS, while pin assignment of other functions does not change. User can select the assignment from ‘straight’ (default) and ‘flipped’ assignment in order to minimize channel-to-channel skew in PWB design. Table 7 shows the MSDL3 pin assignment, and Fig.5 shows the ‘straight’ and ‘flipped’ Table 7. MSDL3 Pin Assignment MSDL3 Pin Assignment RVS ‘L’ ‘Straight’ (default matrix) ‘H’ ‘Flipped’ Top View RVS='L' Default MSDL3 terminal assignment G D2+ D1+ CLK+ D0+ H D2- D1- CLK- D0- 3 4 5 6 1 2 7 8 (a) ‘Straight’ Pin Assignment Top View RVS='H' Flipped MSDL3 terminal assignment G D0+ CLK+ D1+ D2+ H D0- CLK- D1- D2- 3 4 5 6 1 2 7 8 (b) ‘Flipped’ Pin Assignment Fig.5. MSDL3 Pin Assignment www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 7/19 2010.04 - Rev.A Technical Note BU7963GUW PCLK Polarity Selection BU7963GUW controls PCLK input polarity by POL_PCLK setting. Table 8 shows PCLK input polarity. POL_PCLK Table 8. PCLK Polarity Selection Parallel Data Capturing Polarity ‘L’ Capture parallel data at falling edge. ‘H’ (default) Capture parallel data at rising edge. PLL Bandwidth Selection BU7963GUW controls the range of the CLK+ / CLK− input frequency (= PCLK output frequency) by the setting of the data format (LS1, and LS0) of the high-speed data channel and the bandwidth setting of PLL_BW. Table 9. PLL_BW Setting CLK+ / CLK− Frequency Range [MHz] (PCLK Input Frequency) PLL_BW Min Max LS1 LS0 ‘L’ ‘L’ ‘L’ 4 8 ‘L’ ‘L’ ‘H’ 7 15 ‘L’ ‘H’ ‘L’ 8 16 ‘L’ ‘H’ ‘H’ 14 30 ‘H’ ‘L’ ‘L’ 12 24 ‘H’ ‘L’ ‘H’ 21 45 www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 8/19 2010.04 - Rev.A Technical Note BU7963GUW ●Power Modes BU7963GUW has three power modes. 1) Shutdown Mode BU7963GUW goes to Shutdown Mode when XSD = ‘L’. All logic circuits are initialized in the Shutdown Mode. All high-speed signaling channels are disabled, and the outputs keep Hi-Z status. 2) Standby Mode BU7963GUW goes to Standby Mode when XSD = ‘H’ and PCLK is not provided. All high-speed signaling channel outputs keep Hi-Z status. BU7963GUW is monitoring whether PCLK input is running or not and the link switches to Active Mode when PCLK running is detected. 3) Active Mode BU7963GUW goes to Active Mode when XSD = ‘H’ and PCLK is running. All high-speed signaling channels are enabled. Table 10. Power Modes Power Mode Input Shutdown Standby XSD ‘L’ ‘H’ PCLK Static (‘L’ or ‘H’) Static (‘L’ or ‘H’) Active ‘H’ Clock input is active Operation Functions MSDL3 Terminals Initialized Disabled (Hi-Z) PCLK detection Disabled (Hi-Z) PCLK detection Normal operation Enabled (P2S conv) 4) Power Modes Transition Fig.6 shows the transition of power modes. XSD = ”L” Shutdown XSD = ”H” Standby PCLK input stopped PCLK input detected Active Fig.6. Power Modes Transition www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 9/19 2010.04 - Rev.A Technical Note BU7963GUW ●High-Speed Data Channel Protocols Fig.7, Fig.8 and Fig.9 show high-speed data channel protocols. D0channel CP PD26 PD25 PD24 PD23 PD22 PD21 PD20 PD19 PD18 PD17 PD16 PD15 PD3 PD2 PD0 PD14 PD13 PD12 CLK channel Frame start/end PD11 PD10 PD9 PD8 PD7 PD6 PD5 PD4 PD1 res res CP PD26 PD25 Fig.7. MSDL3 Protocol for 1-channel Data (27-bit) D0channel CP PD26 PD25 PD24 PD23 PD22 PD21 PD20 D1channel res PD14 PD13 PD12 PD11 PD10 PD9 PD8 PD19 PD18 PD17 PD2 res CP PD26 PD3 PD1 PD0 res PD14 PD19 PD18 PD17 PD16 PD15 PD2 res CP PD26 PD7 PD6 PD5 PD16 PD15 PD4 CLK channel Frame start/end Fig.8. MSDL3 Protocol for 2-channel Data (27-bit) D0channel CP PD26 PD25 PD24 PD23 PD22 PD21 PD20 CLK channel Frame start/end Fig.9. MSDL3 Protocol for 1-channel Data (13-bit) “res” is reserved bit for the future use, the default state of those is ‘0.’ CP is the parity bit of data payload. BU7961GUW adds an odd parity on CP of the high-speed channel data. ・When the number of ‘H’ bits in parallel data is even, CP bit is ‘H.’ ・When the number of ‘H’ bits in parallel data is odd, CP bits is ‘L.’ www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 10/19 2010.04 - Rev.A Technical Note BU7963GUW ●Electrical Characteristics 1) DC Characteristics Table 11. Digital Input / Output DC Characteristics Ta=25°C, DVDD=MSVDD=1.80V and DGND=MSGND=0.00V, unless otherwise noted. Parameter Symbol Limits Min Typ Max Unit Conditions PCLK, PD[26:0], LS[1:0], RVS, POL_PCLK, XSD, PLL_BW, TEST[1:0] pin PCLK, PD[26:0], LS[1:0], RVS, POL_PCLK, PLL_BW, TEST[1:0] pin ‘L’ Input Voltage 1 VIL1 DGND - 0.3 x DVDD V ‘H’ Input Voltage 1 VIH1 0.7 x DVDD - DVDD V ‘L’ Input Current 1 IIL1 -5 - +5 µA VIN = DGND ‘H’ Input Current 1 IIH1 -5 - +5 µA VIN = DVDD ‘L’ Input Current 2 IIL2 -5 - +5 µA VIN = MSGND ‘H’ Input Current 2 IIH2 -5 - +5 µA VIN = MSVDD ‘L’ Output Voltage 1 VOL1 DGND - 0.3 x DVDD V IO = 1mA,CKD pin ‘H’ Output Voltage 1 VOH1 0.7 x DVDD - DVDD V IO = -1mA,CKD pin Table 12 Current Consumption Ta=25°C, DVDD=MSVDD=1.80V and DGND=MSGND=0.00V, unless otherwise noted. Parameter Symbol Limits Min Typ Max Unit Shutdown Current Iop_sht_rx - 0.2 10 µA Standby Current Iop_stb_rx - 0.2 10 µA Active Current 1-channel / 27-bit Format Active Current 2-channel / 27-bit Format Active Current 3-channel/ 27-bit Format Iop_act_rx1 Iop_act_rx2 Iop_act_rx3 www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. - - - 14.0 19.7 25.4 11/19 18.5 25.7 32.9 Conditions XSD = ‘L’, IDVDD + IMSVDD XSD = ‘H’, IDVDD + IMSVDD mA LS[1:0] = ‘LL,’ PLL_BW[1:0] = ‘H’ DVDD = MSVDD PCLK=15MHz,XSD=‘H CL=10pF Total operating current (IDVDD + IMSVDD ) with PD[26:0] inputs to ggling 0x2AAAAAA and 0x5555555 mA LS[1:0] = ‘LH,’ PLL_BW[1:0] = ‘H’ DVDD = MSVDD PCLK=30MHz,XSD=‘H’ CL=10pF Total operating current (IDVDD + IMSVDD) with PD[26:0] inputs to ggling 0x2AAAAAA and 0x5555555 mA LS[1:0] = ‘HL,’ PLL_BW[1:0] = ‘H’ DVDD = MSVDD PCLK=45MHz,XSD=‘H’ CL=10pF Total operating current (IDVDD + IMSVDD) with PD[26:0] inputs to ggling 0x2AAAAAA and 0x5555555 2010.04 - Rev.A Technical Note BU7963GUW 2) AC Characteristics Parallel Data Input Timing tTX_DH tTX_DS 0.7×DVDD PD[26:0] 0.3×DVDD 0.7×DVDD tTX_R1/tTX_R2 PCLK tTX_F1/tTX_F2 0.3×DVDD Fig.10 Parallel Data Input AC Timing Table 13. Parallel Data Input AC Timing Ta=25°C, DVDD=MSVDD=1.80V and DGND=MSGND=0.00V, unless otherwise noted. Parameter Symbol Limits Unit Conditions Min Typ Max fTX_PCLK1 4 - 15 MHz LS0=L, LS1=L fTX_PCLK2 8 - 30 MHz LS0=H, LS1=L fTX_PCLK3 12 - 45 MHz LS0=L, LS1=H tTX_DUTY 33 - 67 % Input Data Setup Time tTX_DS 5.0 - - ns POL_PCLK=H Input Data Hold Time tTX_DH 5.0 - - ns POL_PCLK=H Input Signal Rise Time 1 tTX_R1 - - 10 ns PCLK Frequency≦30MHz Input Signal Rise Time 2 tTX_R2 - - 5 ns PCLK Frequency>30MHz Input Signal Fall Time 1 tTX_F1 - - 10 ns PCLK Frequency≦30MHz Input Signal Fall Time 2 tTX_F2 - - 5 ns PCLK Frequency>30MHz PCLK Input Frequency PCLK Input Duty Cycle www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 12/19 2010.04 - Rev.A Technical Note BU7963GUW 3) Serial Data Input Timing Fig.11 and Table 14 shows Serial Data Input Timing of BU7963GUW. 1.0000 ×UI CLK+/ - tTXO_N tTXO_N tTXO_N tTXO_N D0+/ - UI = (1 cycle time of CLK +/ - ) / 30 N = Bit position (0 ≦ N ≦ 30 ) Fig.11. Serial Data input AC Timing Table 14. Serial Data input AC Timing Ta=25°C, DVDD=MSVDD=1.80V and DGND=MSGND=0.00V, unless otherwise noted. Parameter Output location CLKL+/- of N bit www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. Symbol tTXO_N Limits Min Typ Max -0.1845×UI + UI×N UI×N 0.1845×UI + UI×N 13/19 Unit Conditions sec 2010.04 - Rev.A Technical Note BU7963GUW 4) Power-On / Off Sequence Power-On Sequence Fig.12 shows power-on sequence of BU7963GUW. DVDD,MSVDD of Tx tTX_VDD_XSD XSD of Tx PCLK of Tx t TX_IN_VAL Provided Stopped tTX_OUT_VAL Tx MSDL3 Output HiZ Valid DVDD,MSVDD of Rx tRX_VDD_XSD XSD of Rx Rx Power mode t RX_IN_VAL Standby / Active Shutdown t RX_OUT_VAL Rx All Outputs Valid Outputs Initial Value Tx: BU7963GUW Rx: BU7964GUW Fig.12. Power-On / Off Sequence Table 15. Power-On Sequence Timing Ta=25°C, DVDD=MS VDD=1.80V, and DGND=MSGND=0.00V, unless otherwise noted. Parameter Symbol Limits Min Typ Max Unit Core power supply startup time tTX_VDD_IOV 0.0 - 2 ms Reset Valid After Power Supplied tTX_VDD_XSD 10 - - µs tTX_IN_VAL 10 - - µs tTX_OUT_VAL - - 2 ms PCLK clock input startup time MSDL3 output delay time www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 14/19 Conditions 2010.04 - Rev.A Technical Note BU7963GUW Power-Off Sequence Fig.13 shows the power-off sequence of BU7963GUW. PCLK of Tx Provided Stopped t Tx MSDL3 Output TX_OUT_INV HiZ Valid t RX_OUT_INV Rx All Outputs Valid Outputs Initial Value XSD of Tx DVDD,MSVDD of Tx t TX_XSD_VDD XSD of Rx DVDD,MSVDD of Rx t RX_XSD_VDD Tx: BU7963GUW Rx: BU7964GUW Fig.13. Power-Off Sequence Table 16. Power-Off Sequence Timing Ta=25°C, DVDD=MSVDD=1.80V, and DGND=MSGND=0.00V, unless otherwise noted. Parameter Symbol Limits Min Typ Max - - 100 Unit MSDL3 output delay time tTX_OUT_INV XSD hold time tTX_XSD_VDD 10 - - µs Core power off time tTX_VDD_IOV 0.0 - 2 ms www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 15/19 Conditions µs 2010.04 - Rev.A Technical Note BU7963GUW Frequency Change Sequence Fig.14 shows the frequency change sequence of BU7963GUW. DVDD, MSVDD of Tx and Rx tTX_XSD_OUT XSD of Tx PCLK of Tx tTX_IN_XSD Frequency1 Frequency2 tTX_XSD_CTL PLL_BW of Tx tTX_CTL_XSD State1 State2 XSD of Rx tRX_XSD_CTL PLL_BW[1:0] of Rx tRX_CTL_XSD State1 State2 Tx:BU7963GUW Rx:BU7964GUW Fig.14. Frequency Change Sequence Table 17. Frequency Change Sequence Ta=25°C, DVDD=MSVDD=1.80V, and DGND=MSGND=0.00V, unless otherwise noted. Parameter Symbol Limits Unit Min Typ Max tTX_XSD_OUT 1.0 - - µs tTX_IN_XSD 1.0 - - µs Control Signal Hold Time tTX_XSD_CTL 2.0 - - µs Control Signal Setup Time tTX_CTL_XSD 2.0 - - µs PCLK Clock Input Suspend Time PCLK Clock Input Restart Time www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 16/19 Conditions 2010.04 - Rev.A Technical Note BU7963GUW ●High-speed Channel Characteristic Table 18. High-speed channel characteristic Ta=25°C, DVDD=MSVDD=1.80V and DGND=MSGND=0.00V, unless otherwise noted. Parameter Limits Symbol Min Typ Max 100 150 200 Unit Differential Voltage Range Vdiff_tx Common Mode Voltage Range Vcm_tx 0.8 0.9 1.0 V tr_tx 200 - 500 ps Vdiff_tx Rise Time Vdiff_tx Fall Time TX Hi-Z State Leak Current mVpp tf_tx 200 - 500 ps fopr_tx - - 225 MHz ILEAK_TX -3 - 3 µA Operating Frequency Conditions Shutdown mode or standby mode fopr_tx Single-ended OutP(D0+,D1+,D2+) Vcm_tx OutN(D0-,D1-,D2-) 20% Vdiff_tx Differential (OutP-OutN) 0 60% 20% tr_tx tf_tx Fig.15. High-Speed Channel Electrical Characteristics Fig.16 shows high-speed channel equivalent schematic. MSDL3 TX MSVDD MSDL3 RX Transmission line VO+ ILEAK_RX ILEAK_TX MSVDD Logical input to MSDL3 TX RTX/ 2 RRX/ 2 RTX/ 2 RRX/ 2 VO- I LEAK_TX VI+ Logical output from MSDL3 RX VI- MSGND MSVDD ILEAK_RX IPULL_RX MSGND MSGND V CM VLINK_RX Link detection comparator output MSGND Fig.16. high-speed channel equivalent schematic. www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 17/19 2010.04 - Rev.A Technical Note BU7963GUW ●Application Circuit Example 1.8V CLK- D0+ D0- D0+ D1+ D1- D1+ D1- D2+ D2- D2+ D2- D0- Pixel clock DVDD PCLK 27 PD[26:0] CPO R[7:0],G[7:0],B[7:0], HS,VS,DE DVDD PLLBW1 PLLBW0 PLLBW POL_PCLK LS1 LS0 DRVR RVS WVGA LCD panel LS1 LS0 DRVR XSD TEST[1:0] DGND MSVDD MSGND CLK+ CLK- BU7964GUW (Rx device) CKD CLK+ Video Mode LCD Controller Reset Reset DVD D GND F_XS TEST[1:0] XSD PD[26:0] 1.8V 10KΩ±5% 27 1.8V GND 10KΩ±5% DVDD PCLK BU7963GUW (Tx device) R[7:0],G[7:0],B[7:0], HS,VS,DE MSVDD DGND Pixel clock 100p×3 100p×2 DGND 100p×2 100p×3 MPU 1.8V 1.8V 0.1μ×3 0.1μ×2 0.1μ×2 MSGND 1.8V 0.1μ×3 MSGND MSGND DGND Fig.17. Application circuit ●PCB Layout for MSDL3 The following points should be considered about the wiring for PCB of MSDL3. ・ ・ ・ ・ Wire for the PCB wiring pattern of high-speed channel (CLK, D0+/-, D1+/-, D2+/-) as short as possible. The PCB wiring for high-speed channel must not use the through-hole. Do not bend the wiring for high-speed channel squarely. Make the wiring length of each high-speed channel the same length (within 0.5mm). www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 18/19 2010.04 - Rev.A Technical Note BU7963GUW ●Ordering Part Number B U 7 Part No. 9 6 3 G Part No. U W Package GUW: VBGA063W050 - E 2 Packaging and forming specification E2: Embossed tape and reel VBGA063W050 <Tape and Reel information> 5.0 ± 0.1 5.0±0.1 0.08 S 63- φ 0.295±0.05 φ 0.05 M S AB P=0.5×7 0.5 0.1 0.9MAX 1PIN MARK Tape Embossed carrier tape (with dry pack) Quantity 2500pcs Direction of feed S E2 The direction is the 1pin of product is at the upper left when you hold ( reel on the left hand and you pull out the tape on the right hand ) 0.75±0.1 0.5 B 12345678 0.75± 0.1 H G F E D C B A P=0.5× 7 A www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. 1pin (Unit : mm) Reel 19/19 Direction of feed ∗ Order quantity needs to be multiple of the minimum quantity. 2010.04 - Rev.A Notice Notes No copying or reproduction of this document, in part or in whole, is permitted without the consent of ROHM Co.,Ltd. The content specified herein is subject to change for improvement without notice. The content specified herein is for the purpose of introducing ROHM's products (hereinafter "Products"). If you wish to use any such Product, please be sure to refer to the specifications, which can be obtained from ROHM upon request. Examples of application circuits, circuit constants and any other information contained herein illustrate the standard usage and operations of the Products. The peripheral conditions must be taken into account when designing circuits for mass production. Great care was taken in ensuring the accuracy of the information specified in this document. However, should you incur any damage arising from any inaccuracy or misprint of such information, ROHM shall bear no responsibility for such damage. The technical information specified herein is intended only to show the typical functions of and examples of application circuits for the Products. ROHM does not grant you, explicitly or implicitly, any license to use or exercise intellectual property or other rights held by ROHM and other parties. ROHM shall bear no responsibility whatsoever for any dispute arising from the use of such technical information. The Products specified in this document are intended to be used with general-use electronic equipment or devices (such as audio visual equipment, office-automation equipment, communication devices, electronic appliances and amusement devices). The Products specified in this document are not designed to be radiation tolerant. While ROHM always makes efforts to enhance the quality and reliability of its Products, a Product may fail or malfunction for a variety of reasons. Please be sure to implement in your equipment using the Products safety measures to guard against the possibility of physical injury, fire or any other damage caused in the event of the failure of any Product, such as derating, redundancy, fire control and fail-safe designs. ROHM shall bear no responsibility whatsoever for your use of any Product outside of the prescribed scope or not in accordance with the instruction manual. The Products are not designed or manufactured to be used with any equipment, device or system which requires an extremely high level of reliability the failure or malfunction of which may result in a direct threat to human life or create a risk of human injury (such as a medical instrument, transportation equipment, aerospace machinery, nuclear-reactor controller, fuelcontroller or other safety device). ROHM shall bear no responsibility in any way for use of any of the Products for the above special purposes. If a Product is intended to be used for any such special purpose, please contact a ROHM sales representative before purchasing. If you intend to export or ship overseas any Product or technology specified herein that may be controlled under the Foreign Exchange and the Foreign Trade Law, you will be required to obtain a license or permit under the Law. Thank you for your accessing to ROHM product informations. More detail product informations and catalogs are available, please contact us. ROHM Customer Support System http://www.rohm.com/contact/ www.rohm.com © 2010 ROHM Co., Ltd. All rights reserved. R1010A