 |
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
| Datasheet File OCR Text: |
| High-performance video signal Switcher Series Video Drivers with Built-in Low Voltage operation Single Video Switchers High-performance System video Driver Series Video Drivers with Built-in Input Selection SW BH76330FVM, BH76331FVM, BH76360FV, BH76361FV Wide Band Low Voltage operation Single Video Switchers BH76332FVM, BH76333FVM, BH76362FV, BH76363FV No.09065EAT01 High-performance video signal Switcher Series INDEX Video Drivers with Built-in Low Voltage operation Single Video Switchers BH76330FVM (3input 1output Video Switch)P2 BH76331FVM (3input 1output Video Switch)P2 BH76360FV BH76361FV (6input 1output Video Switch)P17 (6input 1output Video Switch)P17 Wide Band Low Voltage operation Single Video Switchers BH76332FVM (3input 1output Video Switch)P2 BH76333FVM (3input 1output Video Switch)P2 BH76362FV BH76363FV (6input 1output Video Switch)P17 (6input 1output Video Switch)P17 www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 1/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note Line-up of products with built-in video amplifier and video driver 3-input, 1-output video switch BH76330FVM, BH76331FVM, BH76332FVM, BH76333FVM General BH76330FVM, BH76331FVM, BH76332FVM, and BH76333FVM are video signal switching ICs, each with three inputs and one circuit input, which feature wide dynamic range and frequency response. Since these ICs can be used with low voltage starting at VCC = 2.8 V, they are applicable not only in stationary devices but also in mobile devices. This product line-up supports a broad range of input signals, depending on whether or not a 6-dB video amplifier and video driver are included and what combination of sync tip clamp type and bias (resistor termination) type inputs are used. Features 1) Able to use a wide range of power supply voltage, from 2.8 V to 5.5 V 2) Wide output dynamic range 3) Excellent frequency response (BH76330FVM and BH76331FVM: 100 kHz/10 MHz 0 dB [Typ.], BH76332FVM and BH76333FVM: MHz 0 dB [Typ.]) 4) No crosstalk between channels (Typ. -65 dB, f = 4.43 MHz) 5) Built-in standby function, circuit current during standby is 0 A (Typ.) 6) Sync tip clamp input (BH76330FVM, BH76332FVM) 7) Bias input (Zin = 150 k) (BH76331FVM, BH76333FVM) 8) 6-dB amp and 75 driver are built in (BH76330FVM, BH76331FVM) 9) Enables two load drivers [when using output coupling capacitor] (BH76330FVM, BH76331FVM) 10) Able to be used without output coupling capacitor (BH76330FVM) 11) MSOP8 compact package Applications Input switching in car navigation systems, TVs, DVD systems, etc. Line-up BH76330FVM Supply voltage Amp gain Video driver Frequency response Input type BH76331FVM BH76332FVM BH76333FVM 2.8 V to 5.5 V 6 dB -0.1 dB Included 100 kHz/10 MHz, 0 dB (Typ.) 100 kHz/30 MHz, 0 dB (Typ.) Sync tip Bias Sync tip Bias clamp (Zin = 150 k) clamp (Zin = 150 k) 100 kHz/30 Absolute maximum ratings (Ta = 25) Parameter Symbol Limits Unit Supply voltage VCC 7.0 V Power dissipation Pd 470 1 mW Input voltage range VIN 0 to VCC+0.2 V Operating temperature -40 to +85 Topr range Storage temperature -55 to +125 Tstg range *1 When used while Ta = 25, 4.7 mW is dissipated per 1 Mounted on 70 mm x 70 mm x 1.6 mm glass epoxy board Operation range (Ta = 25) Parameter Supply voltage Symbol VCC Min. 2.8 Typ. 5.0 Max 5.5 Unit V www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 2/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Electrical characteristics 1 (unless otherwise specified, Ta = 25, VCC = 5 V) Typ. Parameter Symbol 76330 76331 76332 76333 Circuit current 1 ICC1 10 9 Circuit current 2 ICC2 0.0 ICC3-1 11 10 Circuit current 3 ICC3-2 17 Maximum output level Voltage gain Frequency response Crosstalk between channels Mute attenuation CTL pin switch level CTL pin inflow current Input impedance Differential gain Differential phase Y-related S/N C-related S/N [AM] C-related S/N [PM] VOM GV GF1 GF2 CT MT VTHH VTHL ITHH Zin DG DP-1 DP-2 SNY SNCA SNCP 4.6 6.0 0 -65 -65 1.2 Min 0.45 Max 50 Max 150 0.3 0.7 0.0 +75 +75 +65 +78 0.3 deg. dB dB 3.8 -0.1 0 3.4 Technical Note Unit mA A mA Vpp dB dB dB dB dB V V A k % Conditions When no signal During standby During output of color bar signal During output of color bar signal (no C in output) f = 10 kHz, THD = 1% Vin = 1.0 Vpp, f = 100 kHz Vin = 1.0 Vpp, f = 10 MHz/100 kHz Vin = 1.0 Vpp, f = 30 MHz/100 kHz Vin = 1.0 Vpp, f = 4.43 MHz Vin = 1.0 Vpp, f = 4.43 MHz High level threshold voltage Low level threshold voltage CTL pin = 2.0 V applied Vin = 1.0 Vpp Standard stair step signal Same condition as above (no C in output) Vin = 1.0 Vpp, bandwidth: 100 k to 6 MHz 150 100% white video signal Vin = 1.0 Vpp, bandwidth: 100 to 500 kHz 100% chroma voltage signal Electrical characteristics 2 (unless otherwise specified, Ta = 25, VCC = 3 V) Typ. Parameter Symbol 76330 76331 76332 76333 Circuit current 1 ICC1 8.5 8.0 Circuit current 2 ICC2 0.0 ICC3-1 9.5 9.0 Circuit current 3 ICC3-2 15.5 Maximum output level Voltage gain Frequency response Crosstalk between channels Mute attenuation CTL pin switch level CTL pin inflow current Input impedance Differential gain Differential phase Y-related S/N C-related S/N [AM] C-related S/N [PM] VOM GV GF1 GF2 CT MT VTHH VTHL ITHH Zin DG DP-1 DP-2 SNY SNCA SNCP 2.7 6.0 0 -65 -65 1.2 Min 0.45 Max 50 Max 150 0.7 1.0 0.5 +75 +75 +65 +78 2.8 1.8 -0.1 0 1.9 Unit mA A mA Conditions When no signal During standby During output of color bar signal During output of color bar signal (no C in output) f = 10 kHz, THD = 1% Vin = 1.0 Vpp, f = 100 kHz Vin = 1.0 Vpp, f = 10 MHz/100 kHz Vin = 1.0 Vpp, f = 30 MHz/100 kHz Vin = 1.0 Vpp, f = 4.43 MHz Vin = 1.0 Vpp, f = 4.43 MHz High level threshold voltage Low level threshold voltage CTL pin = 2.0 V applied Vin = 1.0 Vpp Standard stair step signal Same condition as above (no C in output) Vin = 1.0 Vpp, bandwidth: 100 k to 6 MHz Vpp dB dB dB dB dB V V A k % deg. dB dB dB 0.3 150 0.3 0.3 100% white video signal Vin = 1.0 Vpp, bandwidth: 100 to 500 kHz 100% chroma video signal (Note) Re: ICC3, VOM, GV, GF, CT, MT, DG, DP, SNY, SNCA, and SNCP parameters BH76330FVM and BH76331FVM: RL = 150 BH76332FVM and BH76333FVM: RL = 10 k www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 3/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Control pin settings Technical Note STBY IN1 IN2 IN3 CTL A B L(OPEN) L(OPEN) L(OPEN) H H L(OPEN) H H Block diagram IN1 Sync_Tip Clamp GND IN1 BIAS GND 1 CTLA 8 OUT 6dB Sync_Tip Clamp 1 CTLA 8 OUT 6dB BIAS 2 IN2 75 7 VCC 2 IN2 75 7 VCC 3 logic 6 Sync_Tip Clamp 3 logic 6 BIAS CTLB IN3 CTLB IN3 4 Fig.1 BH76330FV 5 4 Fig.2 BH76331FV 5 IN1 Sync_Tip Clamp GND IN1 BIAS GND 1 CTLA 8 OUT 0dB Sync_Tip Clamp 1 CTLA 8 OUT 0dB BIAS 2 IN2 7 VCC 2 IN2 7 VCC 3 logic 6 Sync_Tip Clamp 3 logic 6 BIAS CTLB IN3 CTLB IN3 4 Fig. 3 BH76332FV 5 4 Fig. 4 BH76333FV 5 www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 4/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV I/O equivalent circuit diagrams Input pins Sync tip clamp input BH76330FVM/BH76332FVM Pin No. Name Bias input BH76331FVM/BH76333FVM Pin No. Name Technical Note Equivalent circuit Equivalent circuit 1 3 5 IN1 IN2 IN3 IN 100 1 3 5 IN1 IN2 IN3 IN 100 150k Video signal input pin is used for sync tip clamp input. DC potential BH76330FVM: 1.5 V BH76332FVM: 1.0 V Video signal input pin is used for bias type input. Input impedance is 150 k. DC potential BH76331FVM: 3.1 V BH76333FVM: 2.5 V Control pins Pin No. Name Equivalent circuit 200k 2 4 CTLA CTLB CTL 50k 250k 200k Switches operation mode [active or standby] and input pin. Threshold level is 0.45 V to 1.2 V. Output pin With video driver BH76330FVM/BH76331FVM Pin No. Name Without video driver BH76332FVM/BH76333FVM Pin No. Name Equivalent circuit OUT 7 OUT 7 OUT 3.0mA OUT 14k Video signal output pin. Able to drive loads up to 75 (dual drive). DC potential BH76330FVM: 0.16 V BH76331FVM: 2.5 V Video signal output pin. DC potential BH76332FVM: 0.3 V BH76333FVM: 1.8 V Note 1) The above DC potential is only when VCC = 5 V. This value is a reference value and is not guaranteed. Note 2) Numerical values shown in these figures are design values, and compliance to standards is not guaranteed. www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 5/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Test Circuit Diagrams Technical Note 0.01F 50 IN1 Sync_Tip Clamp GND 0.01F 50 IN1 Sync_Tip Clamp GND 1 CTLA 8 OUT 6dB Sync_Tip Clamp 1 CTLA 75 75 A 10F VCC V V 8 OUT 0dB Sync_Tip Clamp A 2 IN2 75 7 VCC A 2 IN2 7 10F 10F 0.01F 0.01F 50 A 0.01F 50 A VCC 10k A 10F V V 3 logic 6 Sync_Tip Clamp 3 logic 6 Sync_Tip Clamp 0.01F CTLB IN3 CTLB VCC IN3 4 5 4 5 0.01F 50 0.01F 50 Fig. 5 BH76330FV/BH76331FV Test Circuit Diagram Fig. 6 BH76332FV/BH76333FV Test Circuit Diagram Test circuit diagrams are used for shipment inspections, and differ from application circuits. Application circuit examples When used without output capacitor 7 75 VIDEO_OUT IN1 VIDEO_IN BIAS GND IN1 VIDEO_IN 0.1F Sync_Tip Clamp 1 4.7F 8 OUT 6dB BIAS GND 1 CTLA 8 OUT 6dB Sync_Tip Clamp CTLA 2 2 IN2 75 75 7 VIDEO_OUT 470F 0.1F 47F VCC 75 7 470F 75 VIDEO_OUT IN2 VIDEO_IN 4.7F VCC 3 logic 6 BIAS VCC VIDEO_IN 0.1F 3 logic 6 Sync_Tip Clamp 0.1F 47F VCC CTLB IN3 4 5 4.7F VIDEO_IN CTLB IN3 4 5 0.1F VIDEO_IN Fig. 7 BH76330FV Fig. 8 BH76331FV IN1 VIDEO_IN 0.1F Sync_Tip Clamp GND IN1 VIDEO_IN 4.7F BIAS GND 1 CTLA 8 OUT 0dB Sync_Tip Clamp 1 CTLA 8 OUT 0dB BIAS 2 IN2 VIDEO_IN 0.1F 7 VCC 0.1F VIDEO_OUT 2 IN2 VIDEO_IN 7 VCC 0.1F 47F VIDEO_OUT 3 logic 6 Sync_Tip Clamp 3 4.7F logic 6 BIAS 47F VCC CTLB IN3 CTLB VIDEO_IN 0.1F IN3 VCC 4 5 4 5 4.7F VIDEO_IN Fig. 9 BH76332FV Fig. 10 BH76333FV See pages 6/16 to 10/16 for description of how to determine the capacity of I/O coupling capacitors. www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 6/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Cautions for selection and use of application parts When using this IC by itself Capacity of input coupling capacitor (recommended value) 0.1 F 4.7 F Technical Note Input type Input impedance Zin 10 M 150 k Capacity of output coupling capacitor (recommended value) 470 F to 1000 F Sync_Tip_Clamp Bias Method for determining capacity of input coupling capacitor The HPF is comprised of an input coupling capacitor and the internal input impedance Zin of the IC. frequency fc is several Hz. fc = 1 / (2 x C x Zin)(a) When evaluating the sag characteristics and determining the capacity of the capacitor during video signal input, a horizontal stripe signal called "H bar" (shown in Fig. 10) is suitable, and this type of signal is used instead of a color bar signal to evaluate characteristics and determine capacity. Since the fc value of this HPF is Usually, the cutoff determined using the following equation (a), the above recommended capacity for the input capacitor is derived. Fig.11 Example of Screen with Obvious Sag (H-bar Signal) Method for determining capacity of output coupling capacitor The output pins of models with a 75 driver [BH76330FVM and BH76331FVM] have an HPF comprised of an output coupling capacitor and load resistance RL (= 150). When fc is set to approximately 1 Hz or 2 Hz, the capacity of the output coupling capacitor needs to be approximately 470 F to 1000 F. As for models without the 75 driver, an HPF is similarly comprised using the capacity of the output coupling capacitor and the input impedance of the IC connected at the next stage, and the capacitance required for the output coupling capacitor should be estimated using equation (a). When this IC is used as a standalone device In models that include a 75 driver [BH76330FVM and BH76331FVM], up to two monitors (loads) can be connected (a connection example is shown in Fig. 12). When there are multiple loads, the number of output coupling capacitors must be increased or a larger capacitance must be used, based on the table shown below. 470F OUT monitor OUT (470x2)F monitor 7 7 75 75 75 75 470F 75 monitor 75 monitor 75 75 Fig. 12 (a) Application Circuit Example 1 (Two Drives) Fig. 12 (b) Application Circuit Example 2 (Two Drives) Application circuit example Fig. 12 (a) Fig. 12 (b) No. of output capacitors No. of drives required 1 Capacitance per output capacitor (recommended values) 470 F to 1000 F (same as with one drive) (No. of drive x 470 F to 1000) uF When this IC is used as a standalone device The BH76330FVM is the only model that can be used without an output coupling capacitor. This use method not only enables reductions in board space and part-related costs, but it is able to improve the sag characteristics by improving low-range frequency response. However, when the output coupling capacitor is omitted, a direct current flows to the connected set, so the specifications of the connected set should be noted carefully before starting use. Note also that only one load can be connected when the output coupling capacitor is omitted. monitor OUT 7 75 75 Voltage at output 0.16V When this voltage load resistance is applied, 0 2V a direct current is generated. BH76330FV Fig.13 www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. Application Example without Output Coupling Capacitor 7/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note When using several of these ICs When several of these ICs are used, it enables applications in which separate images are output to the car navigation system's front and rear monitors. VIDEO IN IN1 Clamp /Bias IN1 Clamp /Bias 1 Clamp /Bias IN2 470F 1 Front monitor VIDEO IN IN2 Clamp /Bias 470F Rear monitor 3 IN3 7 Clamp /Bias OUT 75 75 3 IN3 7 Clamp /Bias OUT 75 75 VIDEO IN 5 5 Fig.14 Application Example when Using Several ICs When several ICs are used at the same time, the number of parallel connections of input impedance equals the number of ICs being used, which reduces the input impedance. This also raises the fc value of the HPF formed at the input pin block, so the capacitance of the input coupling capacitor must be increased according to equation (a). The recommended values for calculation results are listed in the table below. When a clamp is used as the input type, the original input impedance becomes much greater, and if two or three are used at the same time there is no need to change the capacitance of the input coupling capacitor. Capacitance of input coupling capacitor (recommended values) 0.1 F 0.1 F 6.8 F~ 10 F~ Input type Input impedance per IC Number of ICs used 2 3 2 3 Total input impedance Approx. 5 M Approx. 3 M 75 k 50 k Sync_Tip_Clamp Bias Approx. 10 M 150 k When using several of these ICs When three bias input type models (BH76331FVM or BH76333FVM) are used in parallel, they can be used for RGB signal switching applications. Likewise, when one clamp input type model (BH76330FVM or BH76332FVM) is connected in parallel with two bias input type models (a total of three ICs used in parallel), they can be used for component signal switching applications. The same method can be used to determine the capacitance of I/O coupling capacitors of these applications. Bias VIDEO IN[R1] 4.7F IN1 Clamp BH76331FV or BH76333FV VIDEO IN[Py1] 0.1uF IN1 1 Bias VIDEO IN[R2] 4.7F IN2 1 Clamp IN2 BH76330FV or BH76332FV OUT VIDEO IN[Py2] 0.1uF OUT 3 Bias IN3 7 R_OUT VIDEO IN[Py3] 0.1uF 3 Clamp IN3 7 Py_OUT VIDEO IN[R3] 4.7F 5 5 Bias VIDEO IN[G1] 4.7F IN1 Bias BH76331FV or BH76333FV VIDEO IN[Pb1] 4.7uF IN1 1 Bias VIDEO IN[G2] 4.7F VIDEO IN[G3] 4.7F IN3 IN2 1 Bias IN2 BH76331FV or BH76333FV OUT VIDEO IN[Pb2] 4.7uF VIDEO IN[Pb3] 4.7uF OUT 3 Bias 7 G_OUT 3 Bias IN3 7 Pb_OUT 5 5 Bias VIDEO IN[B1] 4.7F IN1 Bias BH76331FV or BH76333FV VIDEO IN[Pr1] 4.7uF IN1 1 Bias VIDEO IN[B2] 4.7F IN2 1 Bias IN2 BH76331FV or BH76333FV OUT VIDEO IN[Pr2] 4.7uF OUT 3 Bias VIDEO IN[B3] 4.7F IN3 7 B_OUT VIDEO IN[Pr3] 4.7uF 3 Bias IN3 7 Pr_OUT 5 SW select 5 SW select Fig. 15 (a). RGB Signal Switching Application Example (using three bias input type models in parallel) www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. Fig. 15 (b). Component Signal Switching Application Example (using one clamp input type model and two bias input type models in parallel) 8/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note Cautions for use 1. The numerical values and data shown here are typical design values, not guaranteed values. 2. The application circuit examples show recommended circuits, but characteristics should be checked carefully before using these circuits. If any external part constants are modified before use, factors such as variation in all external parts and ROHM LSI ICs, including not only static characteristics but also transient characteristics, should be fully considered to set an ample margin. 3. Absolute maximum ratings If the absolute maximum ratings for applied voltage and/or operation temperature are exceeded, LSI damage may result. Therefore, do not apply voltage or use in a temperature that exceeds these absolute maximum ratings. If it is possible that absolute maximum ratings will be exceeded, use a physical safety device such as a fuse and make sure that no conditions that might exceed the absolute maximum ratings will be applied to the LSI IC. 4. GND potential Regardless of the operation mode, the voltage of the GND pin should be at least the minimum voltage. Actually check whether or not the voltage at each pin, including transient phenomena, is less than the GND pin voltage. 5. Thermal design The thermal design should be done using an ample margin that takes into consideration the allowable dissipation under actual use conditions. 6. Shorts between pins and mounting errors When mounting LSI ICs onto the circuit board, make sure each LSI's orientation and position is correct. The ICs may become damaged if they are not mounted correctly when the power is turned on. Similarly, damage may also result if a short occurs, such as when a foreign object is positioned between pins in an IC, or between a pin and a power supply or GND connection. 7. Operation in strong electromagnetic field When used within a strong electromagnetic field, evaluate carefully to avoid the risk of operation faults. 8. Place the power supply's decoupling capacitor as close as possible to the VCC pin (PIN 6) and GND pin (PIN 8). 9. With a clamp input type model (BH76330FVM or BH76332FVM), if any unused input pins are left open they will oscillate, so unused input pins should instead be connected to GND via a capacitor or else directly connected to VCC. 10. With models that do not include a 75driver (BH76332FVM or BH76333FVM), in some cases the capacitance added to the set board may cause the peak frequency response to occur at a high frequency. To lower the peak frequency, connect in series resistors having resistance of several dozen to several hundred as close as possible to the output pin. Output pin OUT 7 Resistors (several dozen to several hundred) to lower peak frequency Fig.16 Positions where Resistors are Inserted to Lower Peak Frequency Response in BH76332FV or BH76333FV 11. Frequency response in models that do not include a 75- driver (BH76332FVM and BH76333FVM) was measured as 100 kH/30 MHz: 0 dB (Typ.) in the application circuit examples (shown in Fig. 9 and Fig. 10), and when resistance of about 1 or 2 k is applied from the IC's output pin to GND, this frequency response can be improved (the lower limit of the applied resistance should be 1 k). In such cases, gain is reduced, since the output voltage is divided by the added resistance and the output resistance of the IC. 1 0 -0.10 -0.12 GAIN@f=100kHz[dB] -1 Voltage gain [dB] -2 -3 -4 -5 R=1k R=2k No resistance -0.14 OUT 3mA 7 -0.16 -0.18 Resistance to improve frequency response (R: 1-2 k) -6 -7 1M 10M 100M Frequency [Hz] 1000M -0.20 0.5 1 1.5 2 2.5 Resistance added to output pin [k] [k] (a) Resistor insertion points (b) Frequency response changes when resistance is inserted Input amplitude: 1 Vpp, Output load resistance: 10 k Other constants are as in application examples (Figs. 9 & 10) (c) Voltage gain fluctuation when resistance is inserted [f = 100 kHz] (Voltage gain without inserted resistance: -0.11 dB) Fig.17 www.rohm.com Result of Resistance Inserted to Improve BH76332FVM/BH76333FVM Frequency Response (c) 2009 ROHM Co., Ltd. All rights reserved. 9/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note 12. With clamp input type models (BH76330FVM and BH76332FVM), if the termination impedance of the video input pin becomes higher, sync contractions or oscillation-related problems may occur. Evaluate temperature and other characteristics carefully and use at 1 k or less. 6 Amount of sync contraction at input pin [%] sync[%] 5 4 3 2 1 0 0 1k 2k Rin[] Input termination resistance Rin [] 3k Fig. 18. Relation between Input Pin Termination Impedance and Amount of Sync Contraction Evaluation board pattern diagram and circuit diagram Fig. 19. Evaluation Board Circuit Diagram Fig. 20. Parts list Symbol R1 R3 R5 Function Input terminating resistor Input coupling capacitor Output resistor Output coupling capacitor Decoupling capacitor Evaluation Board Pattern Diagram Recommended value 75 Comments C1 R71 C7 C01 C02 C3 C5 See pages 6/16 to 7/16 to determine 75 See pages 6/16 to 7/16 to determine 10 F 0.1 F B characteristics recommended B characteristics recommended B characteristics recommended www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 10/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note Reference data (1) BH76330FVM/BH76331FVM [unless otherwise specified, output capacitance C: 470 F, RL = 150 BH76330FV 20 Ta=25 20 BH76330FV VCC=5V 20 BH76331FV Ta=25 20 BH76331FV VCC=5V Circuit current [mA] [mA] Circuit current [mA] [mA] [mA] Circuit current [mA] 10 10 10 Circuit current [mA] [mA] 2 3 4 5 Supply Voltage [V] [V] 6 15 15 15 15 10 5 Output capacitance C: 470 F C470uF 5 5 5 C No output capacitance 0 2 3 4 5 Supply Voltage [V] [V] 6 0 -50 0 50 Ambient Temperature [] [] 100 0 0 -50 0 50 Ambient Temperature [] [] 100 Fig. 21 ICC1 vs. Supply Voltage Fig. 22 ICC1 vs. Ambient Temperature Fig. 23 ICC1 vs. Supply Voltage Fig.24 ICC1 vs. Ambient Temperature BH76330/31FV 2.0 Ta=25 2.0 BH76330/31FV VCC=5V 6.0 Maximum [Vpp] output level [ Vpp] BH76330FV Ta=25 3.0 Maximum output [Vpp] level [ Vpp] BH76360FV VCC=3V Circuit current (STBY) [A] (STBY)[A] Circuit current (STBY) A] STBY)[ [A] 1.5 1.0 0.5 0.0 -0.5 2 3 4 5 6 1.5 1.0 0.5 0.0 -0.5 -50 5.0 4.0 2.8 2.6 2.4 2.2 2.0 3.0 2.0 Supply Voltage [V] [V] 0 50 Ambient Temperature [] [] 100 2 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 100 Ambient Temperature [] [] Fig.25 ICC2 vs. Supply Voltage Fig.26 ICC2 vs. Ambient Temperature Fig.27 Vom vs. Supply Voltage Fig.28 Vom vs. Ambient Temperature BH76331FV 6.0 Maximum output level [ Vpp] [Vpp] Ta=25 3.0 BH76331FV VCC=3V 6.3 6.2 [dB] Voltage gain [dB] BH76330FV Ta=25 6.3 6.2 Voltage gain [dB] [dB] BH76330FV VCC=5V Maximum output level [ Vpp] [Vpp] 5.0 4.0 3.0 2.8 2.6 2.4 2.2 2.0 -50 0 50 100 6.1 6.0 5.9 5.8 5.7 2 3 4 5 6 6.1 6.0 5.9 5.8 5.7 -50 0 50 100 2.0 2 3 4 5 6 Supply Voltage [V] [V] Ambient Temperature [] [] Supply Voltage [V] [V] [] Ambient Temperature [] Fig.29 Vom vs. Supply Voltage Fig.30 Vom vs. Ambient Temperature Fig.31 GV vs. Supply Voltage Fig.32 GV vs. Ambient Temperature BH76331FV 6.3 6.2 [dB] Voltage gain [dB] Ta=25 6.3 6.2 Voltage gain [dB] [dB] BH76331FV VCC=5V (100k/10MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 BH76330FV Ta=25 (100k/10MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 -50 BH76330FV VCC=5V 6.1 6.0 5.9 5.8 5.7 2 3 4 5 6 6.1 6.0 5.9 5.8 5.7 -50 Supply Voltage [V] [V] 0 50 100 [] Ambient Temperature [] 3 4 5 6 0 50 100 Supply Voltage [V] [V] Ambient Temperature [] [] Fig.33 GV vs. Supply Voltage Fig.34 GV vs. Ambient Temperature Fig.35 GF vs. Supply Voltage Fig.36 GF vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 11/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note Frequency response (100 kHz/10 MHz) [dB] (100k/10MHz)[dB] 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 3 4 5 6 (100k/10MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] BH76331FV Ta=25 BH76331FV 1.0 0.5 VCC=5V 5 BH76330FV VCC=5V, Ta=25 BH76331FV 5 VCC=5V, Ta=25 0 Gain[dB] Gain[dB] 1M 10M Frequency[Hz] 100M 0 0.0 -0.5 -1.0 -5 -5 -10 -10 -1.5 -2.0 -50 0 50 100 Ambient Temperature [] [] -15 -15 1M 10M Frequency[Hz] 100M Supply Voltage [V] [V] Fig.37 GF vs. Supply Voltage Fig.38 GF vs. Ambient Temperature Fig. 39 Frequency Response Fig. 40 Frequency Response BH76330/31FV Crosstalk between channels (worst) [dB] (worst)[dB] -65 -67 -69 -71 -73 -75 2 Ta=25 Crosstalk between channels (worst) [dB] (worst)[dB] BH76330/31FV -65 VCC=5V -70 Mute attenuation (worst) [dB] (worst)[dB] BH76330/31FV Ta=25 -70 (worst)[dB] Mute attenuation (worst) [dB] -72 -74 -76 -78 -80 -50 BH76330/31FV VCC=5V -67 -69 -71 -73 -75 -50 0 50 Ambient Temperature [] [] 100 -72 -74 -76 -78 -80 2 3 4 5 6 Supply Voltage [V] [V] 3 4 5 Supply Voltage [V] [V] 6 0 50 100 [] Ambient Temperature [] Fig.41 CT(worst) vs. Supply Voltage Fig.42 CT(worst) vs. Ambient Temperature Fig.43 MT(worst) vs. Supply Voltage Fig.44 MT(wrost) vs. Ambient Temperature BH76330/31FV 20 Circuit current [mA] [mA] VCC=5V, Ta=25 70 CTL[uA] CTL pin influx current [A] BH76330/31FV 60 VCC=5V 2.0 Differential gain [%] [%] BH76330FV Ta=25 2.0 Differential gain [%] [%] BH76330FV VCC=5V CTL_A0[V] 15 10 5 0 0 0.5 1 1.5 CTL_B pin voltage [V] CTL_D 2 50 40 30 20 10 0 -50 0 50 Ambient[] [] Temperature 100 1.5 1.5 1.0 0.5 0.0 1.0 0.5 0.0 2 3 4 5 [V] Supply Voltage [V] 6 -50 0 50 100 [V] Ambient Temperature [] Fig. 45 CTLb pin voltage vs Circuit Current (CLT threshold ) Fig.46 ITHH vs. Ambient Temperature (Voltage applied to CTL pin = 2V) Fig.47 DG vs. Supply Voltage Fig.48 DG vs. Ambient Temperature BH76331FV 2.0 1.5 Ta=25 2.0 BH76331FV VCC=5V 2.0 Differential phase.][deg.] [deg BH76330FV Ta=25 2.0 Differential phase.][deg.] [deg BH76330FV VCC=5V C470uF Output capacitance C: 470 F 1.5 1.0 0.5 0.0 No output capacitance C Output C470uFF capacitance C: 470 Differential gain [%] [%] 1.0 0.5 0.0 2 4 5 Supply Voltage [V] [V] 3 6 Differential gain [%] [%] 1.5 1.5 No output capacitance C 1.0 0.5 0.0 -50 0 50 Ambient Temperature [] [V] 100 1.0 0.5 0.0 2 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 100 Ambient Temperature [] [V] Fig.49 DG vs. Supply Voltage Fig.50 DG vs. Ambient Temperature Fig.51 DP vs. Supply Voltage Fig.52 DP vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 12/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note BH76331FV 2.0 [deg.] Differential phase [deg.] Ta=25 2.0 Differential phase [deg.] [deg.] BH76331FV VCC=5V 80 78 YS/N[dB] Y S/N [dB] BH76330/31FV Ta=25 80 78 BH76330/31FV VCC=5V 1.5 1.5 Y S/N [dB] YS/N[dB] 76 74 72 70 76 74 72 70 1.0 0.5 0.0 2 3 4 5 [V] Supply Voltage [V] 6 1.0 0.5 0.0 -50 0 50 Ambient[V] [] Temperature 100 2 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 Ambient Temperature [] [] 100 Fig.53 DP vs. Supply Voltage Fig.54 DP vs. Ambient Temperature Fig.55 SNY vs. Supply Voltage Fig.56 SNY vs. Ambient Temperature BH76330/31FV 80 78 Ta=25 80 78 C S/N (AM) [dB] CS/N(AM)[dB] BH76330/31FV VCC=5V 70 69 C S/N (PM) [dB] CS/N(PM)[dB] BH76330/31FV Ta=25 70 69 C S/N (PM) [dB] CS/N(PM)[dB] BH76330/31FV VCC=5V C S/N/N(AM[dB] ] C S (AM) )[dB 76 74 72 70 2 4 5 Supply Voltage [V] [V] 3 6 76 74 72 70 -50 0 50 100 Ambient Temperature [] [] 68 67 66 65 2 3 4 5 6 Supply Voltage [V] [V] 68 67 66 65 -50 [] Ambient Temperature [] 0 50 100 Fig.57 SNCA vs. Supply Voltage Fig.58 SNCA vs. Ambient Temperature Fig.59 SNCP vs. Supply Voltage Fig.60 SNCP vs. Ambient Temperature Reference data (2) BH76332FVM/BH76333FVM [unless otherwise specified, output capacitance C: 470 F, RL = 10 k] BH76332FV 20 15 10 5 0 2 3 4 5 6 Supply Voltage [V] [V] Ta=25 20 Circuit current [mA] [mA] BH76332FV VCC=5V 20 15 10 5 0 BH76333FV Ta=25 20 15 10 5 0 BH76333FV VCC=5V Circuit current [mA] [mA] Circuit current [mA] [mA] 10 5 0 -50 0 50 Ambient Temperature [] [] 100 2 3 4 5 6 Circuit current [mA] [mA] 15 -50 0 50 100 Supply Voltage [V] [V] [] Ambient Temperature [] Fig.61 ICC1 vs. Supply Voltage Fig.62 ICC1 vs. Ambient Temperature Fig.63 ICC1 vs. Supply Voltage Fig.64 ICC1 vs. Ambient Temperature BH76332/33FV 2.0 Ta=25 2.0 BH76332/33FV Circuit current (STBY) [A] STBY)[A] VCC=5V 5.0 Maximum output[Vpp] level [ Vpp] BH76332FV Ta=25 2.5 BH76332FV level [ Maximum output[Vpp]Vpp] VCC=3V Circuit current (STBY) [A] (STBY)[A] 1.5 1.0 0.5 0.0 -0.5 2 3 4 5 6 1.5 1.0 0.5 0.0 -0.5 -50 0 50 100 4.0 2.3 2.1 1.9 1.7 1.5 3.0 2.0 1.0 2 Ambient Temperature [] [] Supply Voltage [V] [V] 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 100 Ambient Temperature [] [] Fig.65 ICC2 vs. Supply Voltage Fig.66 ICC2 vs. Ambient Temperature Fig.67 Vom vs. Supply Voltage Fig.68 Vom vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 13/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note BH76333FV 5.0 Maximum output[Vpp] level [ Vpp] Ta=25 2.5 BH76333FV Maximum output[Vpp]Vpp] level [ VCC=3V 0.4 0.2 BH76332FV Ta=25 0.4 0.2 Voltage gain [dB] BH76332FV VCC=5V Voltage gain [dB] [dB] 4.0 2.3 2.1 1.9 1.7 1.5 [dB ] 0.0 -0.2 -0.4 -0.6 0.0 3.0 2.0 -0.2 -0.4 -0.6 1.0 2 3 4 5 6 Supply Voltage [V] [V] -50 0 50 100 2 3 4 5 6 -50 0 50 100 Ambient Temperature [] [] Supply Voltage [V] [V] Ambient Temperature [] [] Fig.69 Vom vs. Supply Voltage Fig.70 Vom vs. Ambient Temperature Fig.71 GV vs. Supply Voltage Fig.72 GV vs. Ambient Temperature Frequency response (100 kHz/10 MHz) [dB] (100k/30MHz)[dB] BH76333FV 0.4 0.2 Ta=25 0.4 0.2 Voltage gain [dB] [dB] BH76333FV VCC=5V BH76332FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 Frequency response (100 kHz/10 MHz) [dB] (100k/30MHz)[dB] Ta=25 BH76332FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 -50 0 VCC=5V Voltage gain [dB] [dB ] 0.0 0.0 -0.2 -0.4 -0.6 -0.2 -0.4 -0.6 2 4 5 Supply Voltage [V] [V] 3 6 -50 Fig.73 GV vs. Supply Voltage Fig.74 0 50 100 Ambient Temperature [] [] GV vs. Ambient Temperature 4 5 Supply Voltage [V] [V] 3 6 50 100 Fig.75 GF vs. Supply Voltage Fig.76 GF vs. Ambient Temperature Ambient Temperature [] [] Frequency response (100 kHz/10 MHz) [dB] (100k/30MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] (100 k/30MHz)[dB] BH76333FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 Ta=25 BH76333FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 -50 0 VCC=5V 2 1 0 Gain[dB] BH76332FV VCC=5V ,Ta=25 BH76333FV 2 1 0 Gain[dB] -1 -2 -3 -4 -5 VCC=5V ,Ta=25 -1 -2 -3 -4 -5 3 4 5 Supply Voltage [V] [V] 6 50 100 1M Ambient Temperature [] [] 10M Frequency[Hz] 100M 1M 10M Frequency[Hz] 100M Fig.77 GF vs. Supply Voltage Fig.78 GF vs. Ambient Temperature Fig. 79 Frequency Response Fig. 80 Frequency Response BH76332/33FV Crosstalk between channels (worst) [dB] (worst)[dB] -65 -67 -69 -71 -73 -75 2 Ta=25 (worst)[dB] Crosstalk between channels (worst) [dB] -65 BH76332/33FV VCC=5V -70 Mute attenuation (worst) [dB] (worst)[dB] BH76332/33FV Ta=25 -70 attenuation (worst) [dB] Mute (worst)[dB] -72 -74 -76 -78 -80 -50 BH76332/33FV VCC=5V -67 -69 -71 -73 -75 -50 0 50 100 Ambient Temperature [] [] -72 -74 -76 -78 -80 2 3 4 5 6 Supply Voltage [V] [V] 4 5 [V] Supply Voltage [V] 3 6 0 50 100 [] Ambient Temperature [] Fig.81 CT(worst) vs. Supply Voltage Fig.82 CT(worst) vs. Ambient Temperature Fig.83 MT(worst) vs. Supply Voltage Fig.84 MT(wrost) vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 14/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note BH76332/33FV 20 Circuit current [mA] [mA] VCC=5V, Ta=25 70 BH76332/33FV VCC=5V 2.0 [%] Differential gain [%] 1.5 1.0 0.5 0.0 2 BH76332FV Ta=25 2.0 [%] Differential gain [%] 1.5 BH76332FV VCC=5V 15 10 5 0 0 CTL_A0[V] CTL pin influx current [A] CTL[uA] 60 50 40 30 20 10 0 1.0 0.5 0.0 0.5 1 1.5 2 -50 CTL_B pin voltage [V] CTL_D 0 50 100 [] Ambient Temperature [] 4 5 Supply Voltage [V] [V] 3 6 -50 0 50 100 Ambient Temperature [] [V] Fig.85 CTLb pin voltage vs Circuit Current (CLT threshold ) Fig.86 ITHH vs. Ambient Temperature (Voltage applied to CTL pin = 2V) Fig.87 DG vs. Supply Voltage Fig.88 DG vs. Ambient Temperature BH76333FV 2.0 Ta=25 2.0 BH76333FV VCC=5V 2.0 [deg.] Differential phase [deg.] BH76332FV Ta=25 2.0 [deg.] Differential phase [deg.] 1.5 BH76332FV VCC=5V Differential gain [%] [%] 1.5 Differential gain [%] [%] 1.5 1.5 1.0 0.5 0.0 1.0 0.5 0.0 2 3 4 5 [V] Supply Voltage [V] 6 1.0 0.5 0.0 -50 0 50 [V] Ambient Temperature [] 100 1.0 0.5 0.0 2 3 4 5 [V] Supply Voltage [V] 6 -50 0 50 [V] Ambient Temperature [] 100 Fig.89 DG vs. Supply Voltage Fig.90 DG vs. Ambient Temperature Fig.91 DP vs. Supply Voltage Fig.92 DP vs. Ambient Temperature BH76333FV 2.0 Differential [deg .] phase [deg.] Ta=25 2.0 Differential [deg .] phase [deg.] BH76333FV VCC=5V 80 78 BH76332/33FV Ta=25 80 78 Y S/N [dB] YS/ N[dB] BH76332/33FV VCC=5V 1.5 1.0 0.5 0.0 2 4 5 Supply Voltage [V] [V] 3 6 1.5 Y S/N [dB] YS/N[dB] 76 74 72 70 76 74 72 70 1.0 0.5 0.0 -50 0 50 [V] Ambient Temperature [] 100 2 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 100 [] Ambient Temperature [] Fig.93 DP vs. Supply Voltage Fig.94 DP vs. Ambient Temperature Fig.95 SNY vs. Supply Voltage Fig.96 SNY vs. Ambient Temperature BH76332/33FV 80 78 Ta=25 80 78 C S/N (AM) [dB] CS/N(AM)[dB] BH76332/33FV VCC=5V 70 69 C S/N (PM) [dB] CS/N(PM)[dB] BH76332/33FV Ta=25 70 69 BH76332/33FV VCC=5V C S/N (AM) [dB] C S /N(AM )[dB ] CS/N(PM)[dB] C S/N (PM) [dB] 76 74 72 70 2 4 5 Supply Voltage [V] [V] 3 6 76 74 72 70 -50 0 50 100 Ambient Temperature [] [] 68 67 66 65 2 3 4 5 6 Supply Voltage [V] [V] 68 67 66 65 -50 Ambient Temperature [] 0 50 [] 100 Fig.97 SNCA vs. Supply Voltage Fig.98 SNCA vs. Ambient Temperature Fig.99 SNCP vs. Supply Voltage Fig.100 SNCP vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 15/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV External dimensions and label codes Max 3.25 (include . BURR) Technical Note 763 3 0 Model BH76330FV BH76331FV BH76332FV Code 76330 76331 76332 76333 Lot. No. BH76333FV MSOP8 (unit: mm ) Fig. 101 External Dimensions of BH7633xFVM Series Package When used with 6-input, 1-output video switch BH7636xFV Fig. 14 above shows an application example in which two of these ICs are used. When the similar IC models BH7636xFV and BH7633xFVM are used at the same time, the type of configuration shown below can be combined. In such cases, input coupling capacitors can be used, as in the application example in Fig. 14. 1 IIN1 Clamp BH76360FV External input 2 2 IIN2 Clamp Front TV 4 IIN3 Clamp 16 OUT monitor 75 75 DVD 6 IIN4 Clamp 1 Input coupling capacitor can be used with this. Output coupling capacitors can be omitted when using BH76330FVM or BH76360FV, and this helps reduce the number of parts. Any inputs that are not used should be connected directly to VCC or shorted with GND via a capacitor. Navigation screen 8 IIN5 Clamp 2 Rear camera 9 IIN6 Clamp 3 3 11 BH76330FVM IIN1 Clamp 1 2 IIN2 Clamp Rear 3 IIN3 Clamp 16 OUT monitor 75 75 5 Fig. 102 Application Example in which BH76330FVM and BH76360FV Are Used Concurrently For details of BH7636xFV, see the BH7636xFV Series Application Notes. www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 16/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note Line-up of products with built-in video amplifier and video driver 6-input, 1-output video switch BH76360FV, BH76361FV, BH76362FV, BH76363FV General BH76360FV, BH76361FV, BH76362FV, and BH76363FV are video signal switching ICs, each with six inputs and one circuit input, which feature wide dynamic range and frequency response. Since these ICs can be used with low voltage starting at VCC = 2.8 V, they are applicable not only in stationary devices but also in mobile devices. This product line-up supports a broad range of input signals, depending on whether or not a 6-dB video amplifier and video driver are included and what combination of sync tip clamp type and bias (resistor termination) type inputs are used. Features 1) Able to use a wide range of power supply voltage, from 2.8 V to 5.5 V 2) Wide output dynamic range 3) Excellent frequency response (BH76360FV, BH76361FV100kHz/10MHz 0dB[Typ.]BH76362FV, BH76363FV100kHz/30MHz 0dB[Typ.]) 4) No crosstalk between channels (Typ.-65dB, f=4.43MHz) 5) Built-in mute function (Typ.-65dB, f=4.43MHz) 6) Built-in standby function, circuit current during standby is 0 A (Typ.) 7) Sync tip clamp input BH76360FV, BH76362FV 8) Bias input (Zin=150k) BH76361FV, BH76363FV 9) 6-dB amp and 75 driver are built in BH76360FV, BH76361FV 10) Enables two load drivers [when using output coupling capacitor]BH76360FV, BH76361FV 11) Able to be used without output coupling capacitor (BH76360FV) 12) SSOP-B16 compact package Applications Input switching in car navigation systems, TVs, DVD systems, etc. Line-up BH76360FV Supply voltage Amp gain Video driver Frequency response Input type BH76361FV BH76362FV BH76363FV 2.8 V to 5.5 V 6dB -0.1dB Included 100kHz/10MHz 0dB (Typ.) 100kHz/30MHz 0dB (Typ.) Sync tip Bias Sync tip Bias clamp (Zin = 150 k) clamp (Zin = 150 k) Absolute maximum ratings (Ta = 25) Parameter Symbol Limits Unit Supply voltage VCC 7.0 V Power dissipation Pd 450 1 mW Input voltage range VIN 0 to VCC+0.2 V Operating temperature -40 to +85 Topr range Storage temperature -55 to +125 Tstg range *1 When used while Ta = 25, 4.7 mW is dissipated per 1 Mounted on 70 mm x 70 mm x 1.6 mm glass epoxy board Operation range (Ta = 25) Parameter Supply voltage Symbol VCC Min. 2.8 Typ. 5.0 Max 5.5 Unit V www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 17/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Electrical characteristics 1 (unless otherwise specified, Ta=25VCC=5V Typ. Parameter Symbol 76360 76361 76362 76363 Circuit current 1 ICC1 12 11 Circuit current 2 ICC2 0.0 ICC3-1 13 12 Circuit current 3 ICC3-2 19 Maximum output level Voltage gain Frequency response Crosstalk between channels Mute attenuation CTL pin switch level CTL pin inflow current Input impedance Differential gain Differential phase Y-related S/N C-related S/N [AM] C-related S/N [PM] VOM GV GF1 GF2 CT MT VTHH VTHL ITHH Zin DG DP-1 DP-2 SNY SNCA SNCP 4.6 6.0 0 -65 -65 1.2 Min 0.45 Max 50 Max 150 0.3 0.7 0.0 +75 +75 +65 +78 0.3 3.8 -0.1 0 3.4 Technical Note Unit mA uA mA Vpp dB dB dB dB dB V V uA k % deg. dB dB Conditions When no signal During standby During output of color bar signal During output of color bar signal (no C in output) f=10kHz, THD=1% Vin=1.0Vpp, f=100kHz Vin=1.0Vpp, f=10MHz/100kHz Vin=1.0Vpp, f=30MHz/100kHz Vin=1.0Vpp, f=4.43MHz Vin=1.0Vpp, f=4.43MHz High Level threshold voltage Low Level threshold voltage CTL pin = 2.0 V applied Vin=1.0Vpp Standard stair step signal Same condition as above (no C in output) Vin = 1.0 Vpp, bandwidth: 100 k to 6 MHz 100% white video signal Vin = 1.0 Vpp, bandwidth: 100 to 500 kHz 100% chroma voltage signal 150 Electrical characteristics 2 (unless otherwise specified, Ta = 25, VCC = 3 V) Typ. Parameter Symbol 76360 76361 76362 76363 Circuit current 1 ICC1 10 Circuit current 2 ICC2 0.0 ICC3-1 11 10 Circuit current 3 ICC3-2 17 Maximum output level Voltage gain Frequency response Crosstalk between channels Mute attenuation CTL pin switch level CTL pin inflow current Input impedance Differential gain Differential phase Y-related S/N C-related S/N [AM] C-related S/N [PM] VOM GV GF1 GF2 CT MT VTHH VTHL ITHH Zin DG DP-1 DP-2 SNY SNCA SNCP 2.7 6.0 0 -65 -65 1.2 Min 0.45 Max 50 Max 150 0.3 1.0 0.5 +75 +75 +65 +78 0.3 2.8 1.8 -0.1 0 1.9 Unit mA uA mA Conditions When no signal During standby During output of color bar signal During output of color bar signal (no C in output) f=10kHz, THD=1% Vin=1.0Vpp, f=100kHz Vin=1.0Vpp, f=10MHz/100kHz Vin=1.0Vpp, f=30MHz/100kHz Vin=1.0Vpp, f=4.43MHz Vin=1.0Vpp, f=4.43MHz High Level threshold voltage Low Level threshold voltage CTL pin = 2.0 V applied Vin=1.0Vpp Standard stair step signal Same condition as above (no C in output) Vin = 1.0 Vpp, bandwidth: 100 k to 6 MHz 100% white video signal Vin = 1.0 Vpp, bandwidth: 100 to 500 kHz Vpp dB dB dB dB dB V V uA k % deg. dB dB dB 150 100% chroma video signal (Note) Re: ICC3, VOM, GV, GF, CT, MT, DG, DP, SNY, SNCA, SNCP parameters BH76360FV, BH76361FV: RL = 150 BH76362FV, BH76363FV: RL = 10 k www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 18/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Control pin settings IN1 IN2 IN3 IN4 IN5 IN6 MUTE STBY CTLA L(OPEN) H L(OPEN) H L(OPEN) H CTLB L(OPEN) L(OPEN) H H L(OPEN) L(OPEN) H CTLC CTLD L(OPEN) H L(OPEN) H L(OPEN) H L(OPEN) H H H H H H H L(OPEN) L(OPEN) or H either is possible Technical Note Block diagram IN4 GND IN3 GND IN2 VCC IN1 PVCC IN4 GND IN3 GND IN2 VCC IN1 PVCC 8 7 Sync_Tip Clamp 6 5 Sync_Tip Clamp 4 3 Sync_Tip Clamp 2 1 Sync_Tip Clamp 8 BIAS 7 6 BIAS 5 4 BIAS 3 2 BIAS 1 6dB 75 6dB 75 logic Sync_Tip Clamp Sync_Tip Clamp BIAS BIAS logic 9 IN5 10 CTLA 11 IN6 12 CTLB 13 CTLC 14 CTLD 15 PGND 16 OUT 9 IN5 10 CTLA 11 IN6 12 CTLB 13 CTLC 14 CTLD 15 PGND 16 OUT Fig.1 BH76360FV Fig.2 BH76361FV IN4 GND IN3 GND IN2 VCC IN1 PVCC IN4 GND IN3 GND IN2 VCC IN1 PVCC 8 7 Sync_Tip Clamp 6 5 Sync_Tip Clamp 4 3 Sync_Tip Clamp 2 1 Sync_Tip Clamp 8 BIAS 7 6 BIAS 5 4 BIAS 3 2 BIAS 1 0dB 0dB logic Sync_Tip Clamp Sync_Tip Clamp BIAS BIAS logic 9 IN5 10 CTLA 11 IN6 12 CTLB 13 CTLC 14 CTLD 15 PGND 16 OUT 9 IN5 10 CTLA 11 IN6 12 CTLB 13 CTLC 14 CTLD 15 PGND 16 OUT Fig.3 BH76362FV Fig.4 BH76363FV www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 19/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV I/O equivalent circuit diagrams Input pins Sync tip clamp input BH76360FV / BH76362FV PIN No. Name Bias input BH76361FV / BH76363FV PIN No. Name Technical Note Equivalent circuit Equivalent circuit 2 4 6 8 9 11 IN1 IN2 IN3 IN4 IN5 IN6 IN 100 2 4 6 8 9 11 IN1 IN2 IN3 IN4 IN5 IN6 IN 100 150k Video signal input pin is used for sync tip clamp input. DC potential BH76360FV1.5V BH76362FV1.0V Video signal input pin is used for bias type input. Input impedance is 150 k. DC potential BH76361FV3.1V BH76363FV2.5V Control pins PIN No. Name Equivalent circuit 200k CTL 50k 250k 200k 10 12 13 14 CTLA CTLB CTLC CTLD Switches operation mode [active or standby] and input pin. Threshold level is 0.45 V to 1.2 V. Output pin With video driver BH76360FV / BH76361FV PIN No. Name Without video driver BH76362FV / BH76363FV PIN No. Name Equivalent circuit OUT 16 OUT 16 OUT 3.0mA OUT 14k Video signal output pin. Able to drive loads up to 75 (dual drive). DC potential BH76360FV0.16V BH76361FV2.5V Video signal output pin. DC potential BH76362FV0.3V BH76363FV1.8V Note 1) The above DC potential is only when VCC = 5 V. This value is a reference value and is not guaranteed. Note 2) Numerical values shown in these figures are design values, and compliance to standards is not guaranteed. www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 20/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Test Circuit Diagrams A VCC 10F 0.01F PVCC OUT 75 10F 0.01F 50 VCC IN1 75 V V 0.01F 50 IN1 A 10F 0.01F PVCC VCC Technical Note OUT 1 Clamp/ Bias 75 16 PGND 1 Clamp/ Bias 16 10F PGND 10k V V 2 15 CTLD 2 VCC 15 CTLD 3 0.01F 50 GND IN2 14 Clamp/ Bias 6dB CTLC A 3 0.01F IN2 0dB Clamp/ Bias 14 CTLC A 4 13 CTLB A 50 4 GND 13 CTLB A 5 0.01F 50 GND IN3 logic Clamp/ Bias Clamp/ Bias 12 IN6 A 5 0.01F 50 GND IN3 logic Clamp/ Bias Clamp/ Bias 12 IN6 A 6 11 CTLA 0.01F 50 6 11 CTLA 0.01F 50 7 0.01F 50 IN4 10 Clamp/ Bias Clamp/ Bias IN5 A 7 0.01F 50 IN4 10 Clamp/ Bias Clamp/ Bias IN5 A 0.01F 50 0.01F 50 8 9 8 9 Fig.5 BH76360FV/BH76361FV Test Circuit Diagram Fig.6 BH76362FV/BH76363FV Test Circuit Diagram Test circuit diagrams are used for shipment inspections, and differ from application circuits. Application circuit examples 10F 0.1F VCC PVCC OUT 470F 75 VIDEO_OUT OUT 16 75 VIDEO_OUT 10F 0.1F VCC PVCC OUT 470F 75 VIDEO_OUT 1 Sync_Tip IN1 Clamp VIDEO_IN 0.1F VCC 16 PGND 1 IN1 VIDEO_IN 4.7F VCC 16 BIAS PGND 2 75 15 CTLD 2 75 15 CTLD 3 Sync_Tip IN2 Clamp VIDEO_IN 0.1F GND 14 6dB CTLC 3 IN2 VIDEO_IN 4.7F GND 14 BIAS 6dB CTLC 4 13 CTLB 4 13 CTLB 5 Sync_Tip IN3 Clamp VIDEO_IN 0.1F GND logic Sync_Tip Clamp 12 IN6 0.1F VIDEO_IN 5 IN3 VIDEO_IN 4.7F GND logic BIAS BIAS 12 IN6 4.7F VIDEO_IN 6 11 CTLA 6 11 CTLA 7 Sync_Tip IN4 Clamp VIDEO_IN 0.1F 10 Sync_Tip Clamp IN5 0.1F VIDEO_IN 7 IN4 VIDEO_IN 4.7F 10 BIAS BIAS IN5 4.7F VIDEO_IN 8 9 8 9 Fig.7 10F 0.1F VCC PVCC BH76360FV 10F 0.1F OUT VCC VIDEO_OUT PGND IN1 VIDEO_IN 4.7F PVCC Fig.8 BH76361FV OUT 1 Sync_Tip IN1 Clamp VIDEO_IN 0.1F VCC 16 1 BIAS 16 VIDEO_OUT PGND 2 15 CTLD 2 VCC 15 CTLD 3 IN2 VIDEO_IN 0.1F GND 0dB Sync_Tip Clamp 14 CTLC 3 IN2 VIDEO_IN 4.7F 0dB BIAS 14 CTLC 4 13 CTLB 4 GND 13 CTLB 5 Sync_Tip IN3 Clamp VIDEO_IN 0.1F GND logic Sync_Tip Clamp 12 IN6 0.1F VIDEO_IN VIDEO_IN 4.7F CTLA 5 IN3 logic BIAS BIAS 12 IN6 4.7F VIDEO_IN 6 11 6 GND 11 CTLA 7 IN4 VIDEO_IN 0.1F 10 Sync_Tip Clamp Sync_Tip Clamp IN5 0.1F VIDEO_IN VIDEO_IN 4.7F 7 IN4 10 BIAS BIAS IN5 4.7F VIDEO_IN 8 9 8 9 Fig.9 BH76362FV Fig.10 BH76363FV See pages 6/16 to 10/16 for description of how to determine the capacity of I/O coupling capacitors. www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 21/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Cautions for selection and use of application parts When using this IC by itself Input type Sync_Tip_Clamp Bias Input impedance Zin 10M 150k Capacity of input coupling capacitor (recommended value) 0.1uF 4.7uF Technical Note Capacity of output coupling capacitor (recommended value) 470uF~1000uF Method for determining capacity of input coupling capacitor The HPF is comprised of an input coupling capacitor and the internal input impedance Zin of the IC. frequency fc is several Hz. fc = 1 / (2 x C x Zin)(a) When evaluating the sag characteristics and determining the capacity of the capacitor during video signal input, a horizontal stripe signal called "H bar" (shown in Fig. 10) is suitable, and this type of signal is used instead of a color bar signal to evaluate characteristics and determine capacity. Since the fc value of this HPF is Usually, the cutoff determined using the following equation (a), the above recommended capacity for the input capacitor is derived. Fig.11 Example of Screen with Obvious Sag (H-bar Signal) Method for determining capacity of output coupling capacitor The output pins of models with a 75 driver [BH76360FV and BH76361FV] have an HPF comprised of an output coupling capacitor and load resistance RL (= 150). When fc is set to approximately 1 Hz or 2 Hz, the capacity of the output coupling capacitor needs to be approximately 470 F to 1000 F. As for models without the 75 driver, an HPF is similarly comprised using the capacity of the output coupling capacitor and the input impedance of the IC connected at the next stage, and the capacitance required for the output coupling capacitor should be estimated using equation (a). When this IC is used as a standalone device In models that include a 75 driver [BH76360FV and BH76361FV], up to two monitors (loads) can be connected (a connection example is shown in Fig. 12). When there are multiple loads, the number of output coupling capacitors must be increased or a larger capacitance must be used, based on the table shown below. 470F OUT monitor OUT (470x2)F monitor 16 16 75 75 75 75 470F 75 monitor 75 monitor 75 75 Fig. 12 (a) Application Circuit Example 1 (Two Drives) Fig. 12 (b) Application Circuit Example 2 (Two Drives) Application circuit example Fig12(a) Fig12(b) No. of output capacitors No. of drives required 1 Capacitance per output capacitor (recommended values) 470 F to 1000 F (same as with one drive) (No. of drive x 470 F to 1000) uF When this IC is used as a standalone device The BH76360FV is the only model that can be used without an output coupling capacitor. This use method not only enables reductions in board space and part-related costs, but it is able to improve the sag characteristics by improving low-range frequency response. However, when the output coupling capacitor is omitted, a direct current flows to the connected set, so the specifications of the connected set should be noted carefully before starting use. Note also that only one load can be connected when the output coupling capacitor is omitted. monitor OUT 16 Voltage at output 0.16V When this voltage load resistance is applied, a direct current is generated. 75 75 BH76360FV Fig.13 www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. Application Example without Output Coupling Capacitor 22/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV When using several of these ICs Technical Note When several of these ICs are used, it enables applications in which separate images are output to the car navigation system's front and rear monitors. VIDEO IN IN1 Clamp /Bias IN1 Clamp /Bias 2 Clamp /Bias IN2 470F 2 Front monitor VIDEO IN IN2 Clamp /Bias 470F Rear monitor 4 IN3 16 Clamp /Bias OUT 75 75 4 IN3 16 Clamp /Bias OUT 75 75 VIDEO IN 6 6 Fig.14 Application Example when Using Several ICs When several ICs are used at the same time, the number of parallel connections of input impedance equals the number of ICs being used, which reduces the input impedance. below. When a clamp is used as the input type, the original input impedance becomes much greater, and if two or three are used at the same time there is no need to change the capacitance of the input coupling capacitor. Capacitance of input coupling capacitor (recommended values) 0.1uF 0.1uF 6.8uF~ 10uF~ This also raises the fc value of the HPF formed at the input pin block, so the capacitance of the input The recommended values for calculation results are listed in the table coupling capacitor must be increased according to equation (a). Input type Input impedance per IC Number of ICs used 2 3 2 3 Total input impedance Approx. 5 M Approx. 3 M 75k 50k Sync_Tip_Clamp Bias Approx. 10 M 150k When using several of these ICs When three bias input type models (BH76361FV or BH76363FV) are used in parallel, they can be used for RGB signal switching applications. Likewise, when one clamp input type model (BH76360FV or BH76362FV) is connected in parallel with two bias input type The same method can be used models (a total of three ICs used in parallel), they can be used for component signal switching applications. to determine the capacitance of I/O coupling capacitors of these applications. Bias VIDEO IN[R1] 4.7F IN1 Clamp BH76361FV or BH76363FV VIDEO IN[Py1] 0.1uF IN1 2 Bias VIDEO IN[R2] 4.7F IN2 2 Clamp IN2 BH76360FV or BH76362FV OUT VIDEO IN[Py2] 0.1uF OUT 4 Bias VIDEO IN[R3] 4.7F IN3 16 R_OUT VIDEO IN[Py3] 0.1uF 4 Clamp IN3 16 Py_OUT 6 6 Bias VIDEO IN[G1] 4.7F IN1 Bias BH76361FV or BH76363FV VIDEO IN[Pb1] 4.7uF IN1 2 Bias VIDEO IN[G2] 4.7F VIDEO IN[G3] 4.7F IN3 IN2 2 Bias IN2 BH76361FV or BH76363FV OUT VIDEO IN[Pb2] 4.7uF VIDEO IN[Pb3] 4.7uF OUT 4 Bias 16 G_OUT 4 Bias IN3 16 Pb_OUT 6 6 Bias VIDEO IN[B1] 4.7F IN1 Bias BH76361FV or BH76363FV VIDEO IN[Pr1] 4.7uF IN1 2 Bias VIDEO IN[B2] 4.7F IN2 2 Bias IN2 BH76361FV or BH76363FV OUT VIDEO IN[Pr2] 4.7uF OUT 4 Bias VIDEO IN[B3] 4.7F IN3 16 B_OUT VIDEO IN[Pr3] 4.7uF 4 Bias IN3 16 Pr_OUT 6 SW 6 SW Fig. 15 (a). RGB Signal Switching Application Example (using three bias input type models in parallel) www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. Fig. 15 (b). Component Signal Switching Application Example (using one clamp input type model and two bias input type models in parallel) 23/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note Cautions for use 1. The numerical values and data shown here are typical design values, not guaranteed values. 2. The application circuit examples show recommended circuits, but characteristics should be checked carefully before using these circuits. If any external part constants are modified before use, factors such as variation in all external parts and ROHM LSI ICs, including not only static characteristics but also transient characteristics, should be fully considered to set an ample margin. 3. Absolute maximum ratings If the absolute maximum ratings for applied voltage and/or operation temperature are exceeded, LSI damage may result. Therefore, do not apply voltage or use in a temperature that exceeds these absolute maximum ratings. If it is possible that absolute maximum ratings will be exceeded, use a physical safety device such as a fuse and make sure that no conditions that might exceed the absolute maximum ratings will be applied to the LSI IC. 4. GND potential Regardless of the operation mode, the voltage of the GND pin should be at least the minimum voltage. Actually check whether or not the voltage at each pin, including transient phenomena, is less than the GND pin voltage. 5. Thermal design The thermal design should be done using an ample margin that takes into consideration the allowable dissipation under actual use conditions. 6. Shorts between pins and mounting errors When mounting LSI ICs onto the circuit board, make sure each LSI's orientation and position is correct. The ICs may become damaged if they are not mounted correctly when the power is turned on. Similarly, damage may also result if a short occurs, such as when a foreign object is positioned between pins in an IC, or between a pin and a power supply or GND connection. 7. Operation in strong electromagnetic field When used within a strong electromagnetic field, evaluate carefully to avoid the risk of operation faults. 8. Place the power supply's decoupling capacitor as close as possible to the VCC pin (PIN 1,PIN3) and GND pin (PIN 5, PIN7, PIN15). 9. With a clamp input type model (BH76360FV or BH76362FV), if any unused input pins are left open they will oscillate, so unused input pins should instead be connected to GND via a capacitor or else directly connected to VCC. 10. With models that do not include a 75driver (BH76362FV or BH76363FV), in some cases the capacitance added to the set board may cause the peak frequency response to occur at a high frequency. To lower the peak frequency, connect in series resistors having resistance of several dozen to several hundred as close as possible to the output pin. Output pin OUT 16 Resistors (several dozen to several hundred) to lower peak frequency Fig.16 Positions where Resistors are Inserted to Lower Peak Frequency Response in BH76362FV or BH76363FV 11. Frequency response in models that do not include a 75- driver (BH76362FV and BH76363FV) was measured as 100 kH/30 MHz: 0 dB (Typ.) in the application circuit examples (shown in Fig. 9 and Fig. 10), and when resistance of about 1 or 2 k is applied from the IC's output pin to GND, this frequency response can be improved (the lower limit of the applied resistance should be 1 k). In such cases, gain is reduced, since the output voltage is divided by the added resistance and the output resistance of the IC. 1 0 -0.10 OUT 3mA 16 [dB] -2 -3 -4 -5 R=1k R=2k No resistance GAIN@f=100kHz[dB] -1 -0.12 Voltage gain [dB] -0.14 -0.16 -0.18 Resistance to improve frequency response (R: 1-2 k) -6 -7 1M 10M 100M [Hz] Frequency [Hz] 1000M -0.20 0.5 1 1.5 2 [k] Resistance added to output pin [k] 2.5 (a) Resistor insertion points (b) Frequency response changes when resistance is inserted Input amplitude: 1 Vpp, Output load resistance: 10 k Other constants are as in application examples (Figs. 9 & 10) (c) Voltage gain fluctuation when resistance is inserted [f = 100 kHz] (Voltage gain without inserted resistance: -0.11 dB) Fig.17 www.rohm.com Result of Resistance Inserted to Improve BH76362FV/BH76363FV Frequency Response (c) 2009 ROHM Co., Ltd. All rights reserved. 24/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note 12. With clamp input type models (BH76360FV and BH76362FV), if the termination impedance of the video input pin becomes higher, sync contractions or oscillation-related problems may occur. Evaluate temperature and other characteristics carefully and use at 1 k or less. 6 Amount of sync contraction at input pin [%] sync[%] 5 4 3 2 1 0 0 1k 2k Rin[] Input termination resistance Rin [] 3k Fig. 18. Relation between Input Pin Termination Impedance and Amount of Sync Contraction Evaluation board pattern diagram and circuit diagram VCC GND GND GND GND GND C02 0.1u H161 OUT C16 R161 75 OUT-RCA OUT RCA + C01 47u 1 IN1 RCA R2 75 IN1-RCA C2 IN1 16 15 14 2 + + 470u H162 H163 H164 R162 150 R163 150 C03 47u IN2 RCA R4 75 IN2-RCA C4 IN2 C04 0.1u 3 4 5 H1 H2 H3 H4 CTLD CTLD CTLC CTLB CTLA A-13AP H SW14 SW13 SW12 SW10 IN6 RCA IN5 RCA BH7636xFV BH7636xFV 13 12 11 10 9 CTLC CTLB IN3 RCA R6 75 + IN3-RCA C6 IN3 6 7 IN6 C11 IN6-RCA R11 75 CTLA IN4 RCA R8 75 IN4-RCA C8 IN4 8 IN5 C9 IN5-RCA R9 75 Fig.19 GND H OUT L CTLA OUT-RCA R161 C16 SW10 H L CTLB SW12 H L CTLC SW13 H CTLC H3 CTLB H2 CTLD H4 CTLA H1 L CTLD OUT GND R11 IN6 IN6 C11 SW14 Evaluation Board Circuit Diagram CTLC CTLA H161 CTLD CTLB IN6-RCA IN5 H164 H162 H163 U1 R9 IN5 C02 R163 R162 R164 GND IN1 IN1-RCA C01 C9 IN5-RCA C03 C04 BH76360~5FV R4 R6 IN3-RCA IN4-RCA R8 IN3 IN4 GND R2 IN2 IN2-RCA VCC C2 C4 C6 C8 GND IN1 IN2 IN3 IN4 Fig.20 Parts list Symbol R2 R8 C2 C8 R161 C16 C01(C03) C02(C04) R4 R9 C4 C9 R6 R11 C6 C11 Function Input terminating resistor Input coupling capacitor Output resistor Output coupling capacitor Decoupling capacitor Evaluation Board Pattern Diagram Recommended value 75 See pages 6/16 to 7/16 to determine 75 See pages 6/16 to 7/16 to determine 10uF 0.1uF Comments B characteristics recommended B characteristics recommended B characteristics recommended www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. + L + + + + R164 75 25/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note Reference data (1) BH76360FV / BH76361FV [unless otherwise specified, output capacitance C: 470 F, RL = 150 ] BH76360FV 20 Ta=25 20 BH76360FV VCC=5V 20 BH76361FV Ta=25 20 BH76361FV VCC=5V Circuit current [mA] [mA] Circuit current [mA] [mA] [mA] Circuit current [mA] 10 5 10 . 10 Circuit current [mA] [mA] 15 15 15 15 10 C470uF Output capacitance C: 470 F C No output capacitance 5 Output C470uFF capacitance C: 470 5 5 C No output capacitance 0 2 3 4 5 Supply Voltage [V] [V] 6 0 -50 0 50 Ambient Temperature [] [] 100 0 2 3 4 5 6 0 -50 0 50 100 [] Ambient Temperature [] Fig.21 ICC1 vs. Supply Voltage Fig.22 ICC1 vs. Ambient Temperature Fig.23 ICC1 vs. Supply Voltage Supply Voltage [V] [V] Fig.24 ICC1 vs. Ambient Temperature BH76360/61FV 2.0 Ta=25 2.0 Circuit STBY)[ A] current (STBY) [A] BH76360/61FV VCC=5V 6.0 Maximum output [Vpp] level [ Vpp] BH76360FV Ta=25 3.0 [Vpp] 2.8 2.6 2.4 2.2 2.0 BH76360FV VCC=3V Circuit current (STBY) [A] (STBY)[A] 1.5 1.0 0.5 0.0 -0.5 2 3 4 5 6 1.5 1.0 0.5 0.0 -0.5 -50 0 50 100 5.0 4.0 3.0 2.0 2 3 4 5 [V] Supply Voltage [V] 6 -50 0 50 100 Supply Voltage [V] [V] Ambient Temperature [] [] [] Ambient Temperature [] Fig.25 ICC2 vs. Supply Voltage Fig.26 ICC2 vs. Ambient Temperature Fig.27 Vom vs. Supply Voltage Fig.28 Vom vs. Ambient Temperature BH76361FV 6.0 Maximum output level [ Vpp] [Vpp] Ta=25 3.0 BH76361FV Maximum output level [ Vpp] [Vpp] VCC=3V 6.3 6.2 BH76360FV Ta=25 6.3 6.2 [dB] Voltage gain [dB] 6.1 6.0 5.9 5.8 5.7 BH76360FV VCC=5V Voltage gain [dB] [dB] 5.0 4.0 3.0 2.0 2 3 4 5 6 2.8 2.6 2.4 2.2 2.0 -50 0 50 100 6.1 6.0 5.9 5.8 5.7 2 3 4 5 6 -50 Supply Voltage [V] [V] Ambient Temperature [] [] Supply Voltage [V] [V] 0 50 Ambient Temperature [] [] 100 Fig.29 Vom vs. Supply Voltage Fig.30 Vom vs. Ambient Temperature Fig.31 GV vs. Supply Voltage Fig.32 GV vs. Ambient Temperature Frequency(100k/10MHz)[dB] [dB] response (100 kHz/10 MHz) 6.3 6.2 6.3 6.2 Voltage gain [dB] [dB] 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 3 4 5 6 (100k/10MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] BH76361FV Ta=25 BH76361FV VCC=5V BH76360FV Ta=25 BH76360FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 -50 0 50 VCC=5V Voltage gain [dB] [dB] 6.1 6.0 5.9 5.8 5.7 2 3 4 5 6 6.1 6.0 5.9 5.8 5.7 -50 0 50 100 100 Supply Voltage [V] [V] Ambient[] [] Temperature Supply Voltage [V] [V] Ambient Temperature [] [] Fig.33 GV vs. Supply Voltage Fig.34 GV vs. Ambient Temperature Fig.35 GF vs. Supply Voltage Fig.36 GF vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 26/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note (100k/10MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 3 4 5 6 (100k/10MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] BH76361FV Ta=25 BH76361FV 1.0 0.5 VCC=5V 5 BH76360FV VCC=5V, Ta=25 BH76361FV 5 VCC=5V, Ta=25 0 Gain[dB] Gain[dB] 1M 10M Frequency[Hz] 100M 0 0.0 -0.5 -1.0 -5 -5 -10 -10 -1.5 -2.0 -50 0 50 100 Ambient Temperature [] [] -15 -15 1M 10M Frequency[Hz] 100M Supply Voltage [V] [V] Fig.37 GF vs. Supply Voltage Fig.38 GF vs. Ambient Temperature Fig.39 Frequency Response Fig. 40 Frequency Response BH76360/61FV Crosstalk between channels (worst) [dB] (worst)[dB] -65 -67 -69 -71 -73 -75 2 Ta=25 (worst)[dB] -65 BH76360/61FV VCC=5V -70 Mute attenuation (worst) [dB] (worst)[dB] BH76360/61FV Ta=25 -70 (worst)[dB] Mute attenuation (worst) [dB] -72 -74 -76 -78 -80 -50 BH76360/61FV VCC=5V -67 -69 -71 -73 -75 -50 0 50 Ambient Temperature [] [] 100 -72 -74 -76 -78 -80 2 3 4 5 6 Supply Voltage [V] [V] 3 4 5 Supply Voltage [V] [V] 6 0 50 100 [] Ambient Temperature [] Fig.41 CT(worst) vs. Supply Voltage Fig.42 CT(worst) vs. Ambient Temperature Fig.43 MT(worst) vs. Supply Voltage Fig.44 MT(wrost) vs. Ambient Temperature BH76360/61FV 20 Circuit current [mA] [mA] VCC=5V, Ta=25 70 CTL[uA] CTL pin influx current [A] 60 BH76360/61FV VCC=5V 2.0 Differential gain [%] [%] BH76360FV Ta=25 2.0 BH76360FV VCC=5V [%] Differential gain [%] 15 10 5 0 0 0.5 1 1.5 CTL_D pin voltage [V] CTL_D 2 50 40 30 20 10 0 -50 0 50 Ambient[] [] Temperature 100 1.5 1.0 0.5 0.0 2 3 4 5 Supply Voltage [V] [V] 6 1.5 1.0 0.5 0.0 -50 0 50 100 Ambient Temperature [] [] Fig. 45 CTLd pin voltage vs Circuit Current (CLT threshold ) Fig.46 ITHH vs. Ambient Temperature (Voltage applied to CTL pin = 2V) Fig.47 DG vs. Supply Voltage Fig.48 DG vs. Ambient Temperature BH76361FV 2 Ta=25 2 BH76361FV VCC=5V 2.0 BH76360FV Differential phase [deg.] Ta=25 2.0 Differential phase [deg.] [deg] BH76360FV VCC=5V [%] Differential gain [%] [%] Differential gain [%] 1.5 1.5 1.5 C470uF Output capacitance C: 470 F C No output capacitance 1.5 1.0 0.5 0.0 [deg.] Output capacitance C: 470 F C470uF No output capacitance C 1 1 1.0 0.5 0.5 0.5 0 2 3 4 5 Supply Voltage [V] [V] 6 0 -50 0 50 Ambient Temperature [] [] 100 0.0 2 4 5 [V] Supply Voltage [V] 3 6 -50 0 50 Ambient Temperature [] [] 100 Fig.49 DG vs. Supply Voltage Fig.50 DG vs. Ambient Temperature Fig.51 DP vs. Supply Voltage Fig.52 DP vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 27/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note BH76361FV 2 Differential phase [deg.] [deg.] Ta=25 2 BH76361FV VCC=5V 80 78 YS/N[dB] Y S/N [dB] BH76360/61FV Ta=25 80 78 BH76360/61FV VCC=5V 1.5 1 0.5 0 2 4 5 Supply Voltage [V] [V] 3 6 Differential phase [deg.] [deg] 1.5 Y S/N [dB] YS/N[dB] 76 74 72 70 76 74 72 70 1 0.5 0 -50 0 50 100 2 Ambient Temperature [] [] 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 Ambient Temperature [] [] 100 Fig.53 DP vs. Supply Voltage Fig.54 DP vs. Ambient Temperature Fig.55 SNY vs. Supply Voltage Fig.56 SNY vs. Ambient Temperature BH76360/61FV 80 78 Ta=25 80 78 C S/N (AM) [dB] CS/N(AM)[dB] BH76360/61FV VCC=5V 70 69 C S/N (PM) [dB] CS/N(PM)[dB] BH76360/61FV Ta=25 70 69 C S/N (PM) [dB] CS/N(PM)[dB] BH76360/61FV VCC=5V C S/N/N(AM[dB] ] C S (AM) )[dB 76 74 72 70 2 3 4 5 6 Supply Voltage [V] [V] 76 74 72 70 -50 0 50 100 Ambient Temperature [] [] 68 67 66 65 2 3 4 5 6 Supply Voltage [V] [V] 68 67 66 65 -50 [] Ambient Temperature [] 0 50 100 Fig.57 SNCA vs. Supply Voltage Fig.58 SNCA vs. Ambient Temperature Fig.59 SNCP vs. Supply Voltage Fig.60 SNCP vs. Ambient Temperature Reference data (2) BH76362FV/BH76363FV [unless otherwise specified, output capacitance C: 470 F, RL = 10 k] BH76362FV 20 Ta=25 20 BH76362FV VCC=5V 20 BH76363FV Ta=25 20 BH76363FV VCC=5V [mA] Circuit current [mA] Circuit current [mA] [mA] [mA] Circuit current [mA] 10 10 10 5 5 [mA] Circuit current [mA] 2 3 4 5 Supply Voltage [V] [V] 6 15 15 15 15 10 5 5 0 2 3 4 5 6 0 -50 0 50 [] Ambient Temperature [] 0 100 0 -50 0 50 Ambient Temperature [] [] 100 Supply Voltage [V] [V] Fig.61 ICC1 vs. Supply Voltage Fig.62 ICC1 vs. Ambient Temperature Fig.63 ICC1 vs. Supply Voltage Fig.64 ICC1 vs. Ambient Temperature BH76362/63FV 2.0 Ta=25 2.0 BH76362/63FV Circuit current (STBY) [A] STBY)[A] VCC=5V 5.0 Maximum output[Vpp] level [ Vpp] BH76362FV Ta=25 2.5 level [ Maximum output[Vpp]Vpp] 2.3 2.1 1.9 1.7 1.5 BH76362FV VCC=3V Circuit current (STBY) [A] (STBY)[A] 1.5 1.0 0.5 0.0 -0.5 2 3 4 5 6 [V] Supply Voltage [V] 1.5 1.0 0.5 0.0 -0.5 -50 0 50 100 4.0 3.0 2.0 1.0 2 Ambient Temperature [] [] 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 100 Ambient Temperature [] [] Fig.65 ICC2 vs. Supply Voltage Fig.66 ICC2 vs. Ambient Temperature Fig.67 Vom vs. Supply Voltage Fig.68 Vom vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 28/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note BH76363FV 5.0 Maximum output[Vpp] level [ Vpp] Ta=25 2.5 BH76363FV Maximum output[Vpp]Vpp] level [ VCC=3V 0.4 0.2 BH76362FV Ta=25 0.4 0.2 Voltage gain [dB] BH76362FV VCC=5V Voltage gain [dB] [dB] 4.0 2.3 2.1 1.9 1.7 1.5 [dB ] 0.0 -0.2 -0.4 -0.6 0.0 3.0 2.0 -0.2 -0.4 -0.6 1.0 2 3 4 5 6 Supply Voltage [V] [V] -50 0 50 100 2 3 4 5 6 -50 0 50 100 Ambient Temperature [] [] Supply Voltage [V] [V] Ambient Temperature [] [] Fig.69 Vom vs. Supply Voltage Fig.70 Vom vs. Ambient Temperature Fig.71 GV vs. Supply Voltage Fig.72 GV vs. Ambient Temperature Frequency response (100 kHz/10 MHz) [dB] (100k/30MHz)[dB] BH76363FV 0.4 0.2 Ta=25 0.4 0.2 Voltage gain [dB] [dB] BH76363FV VCC=5V BH76362FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 Frequency response (100 kHz/10 MHz) [dB] (100k/30MHz)[dB] Ta=25 BH76362FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 -50 0 VCC=5V Voltage gain [dB] [dB ] 0.0 0.0 -0.2 -0.4 -0.6 -0.2 -0.4 -0.6 2 4 5 Supply Voltage [V] [V] 3 6 -50 Fig.73 GV vs. Supply Voltage Fig.74 0 50 100 Ambient Temperature [] [] GV vs. Ambient Temperature 4 5 Supply Voltage [V] [V] 3 6 50 100 Fig.75 GF vs. Supply Voltage Fig.76 GF vs. Ambient Temperature Ambient Temperature [] [] Frequency response (100 kHz/10 MHz) [dB] (100k/30MHz)[dB] Frequency response (100 kHz/10 MHz) [dB] (100k/30MHz)[dB] BH76363FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 2 Ta=25 BH76363FV 1.0 0.5 0.0 -0.5 -1.0 -1.5 -2.0 -50 0 VCC=5V 2 1 0 Gain[dB] BH76362FV VCC=5V ,Ta=25 BH76363FV 2 1 0 Gain[dB] -1 -2 -3 -4 -5 VCC=5V ,Ta=25 -1 -2 -3 -4 -5 3 4 5 Supply Voltage [V] [V] 6 50 100 1M Ambient Temperature [] [] 10M Frequency[Hz] 100M 1M 10M Frequency[Hz] 100M Fig.77 GF vs. Supply Voltage Fig.78 GF vs. Ambient Temperature Fig. 79 Frequency Response Fig. 80 Frequency Response BH76362/63FV Crosstalk between channels (worst) [dB] (worst)[dB] -65 -67 -69 -71 -73 -75 2 Ta=25 (worst)[dB] Crosstalk between channels (worst) [dB] -65 BH76362/63FV VCC=5V -70 Mute attenuation (worst) [dB] (worst)[dB] BH76362/63FV Ta=25 -70 attenuation (worst) [dB] Mute (worst)[dB] -72 -74 -76 -78 -80 -50 BH76362/63FV VCC=5V -67 -69 -71 -73 -75 -50 0 50 100 Ambient Temperature [] [] -72 -74 -76 -78 -80 2 3 4 5 6 Supply Voltage [V] [V] 4 5 [V] Supply Voltage [V] 3 6 0 50 100 [] Ambient Temperature [] Fig.81 CT(worst) vs. Supply Voltage Fig.82 CT(worst) vs. Ambient Temperature Fig.83 MT(worst) vs. Supply Voltage Fig.84 MT(wrost) vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 29/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Technical Note BH76362/63FV 20 VCC=5V, Ta=25 70 CTL[uA] CTL pin influx current [A] BH76362/63FV VCC=5V 2.0 Differential gain [%] [%] BH76362FV Ta=25 2 BH76362FV VCC=5V 60 50 40 30 20 10 0 Circuit current [mA] [mA] 15 10 5 0 0 0.5 1 1.5 2 CTL_D pin voltage [V] CTL_D 1.5 1.0 0.5 [%] Differential gain [%] 1.5 1 0.5 0.0 -50 0 50 [] Ambient Temperature [] 100 0 2 3 4 5 [V] Supply Voltage [V] 6 -50 0 50 100 Ambient Temperature [] [] Fig.85 CTLd pin voltage vs Circuit Current (CLT threshold ) Fig.86 ITHH vs. Ambient Temperature (Voltage applied to CTL pin = 2V) Fig.87 DG vs. Supply Voltage Fig.88 DG vs. Ambient Temperature BH76363FV 2.0 Ta=25 2.0 BH76363FV VCC=5V 2.0 BH76362FV Ta=25 2.0 [%] Differential phase [deg.] BH76362FV VCC=5V Differential phase [deg.] [deg.] Differential gain [%] [%] Differential gain [%] [%] 1.5 1.5 1.5 1.5 1.0 1.0 1.0 1.0 0.5 0.5 0.5 0.5 0.0 2 3 4 5 Supply Voltage [V] [V] 6 0.0 -50 0 50 100 [] Ambient Temperature [] 0.0 2 3 4 5 6 0.0 -50 Supply Voltage [V] [V] 0 50 Ambient Temperature [] [] 100 Fig.89 DG vs. Supply Voltage Fig.90 DG vs. Ambient Temperature Fig.91 DP vs. Supply Voltage Fig.92 DP vs. Ambient Temperature BH76363FV 2.0 Ta=25 2.0 BH76363FV VCC=5V 80 78 BH76362/63FV Ta=25 80 78 Y S/N [dB] YS/N[dB] BH76362/63FV VCC=5V Differential phase [deg.] [%] 1.5 Differential phase [deg.] [%] 1.5 Y S/N [dB] YS/N[dB] 76 74 72 70 76 74 72 70 1.0 1.0 0.5 0.5 0.0 2 3 4 5 Supply Voltage [V] [V] 6 0.0 -50 0 50 Ambient Temperature [] [] 100 2 3 4 5 Supply Voltage [V] [V] 6 -50 0 50 100 [] Ambient Temperature [] Fig.93 DP vs. Supply Voltage Fig.94 DP vs. Ambient Temperature Fig.95 SNY vs. Supply Voltage Fig.96 SNY vs. Ambient Temperature BH76362/63FV 80 78 C S/N (AM) [dB] C S /N(AM )[dB ] Ta=25 80 78 C S/N (AM) [dB] CS/N(AM)[dB] BH76362/63FV VCC=5V 70 69 C S/N (PM) [dB] CS/N(PM)[dB] BH76362/63FV Ta=25 70 69 BH76362/63FV VCC=5V 76 74 72 70 2 3 4 5 6 Supply Voltage [V] [V] CS/N(PM)[dB] C S/N (PM) [dB] 76 74 72 70 -50 0 50 100 Ambient Temperature [] [] 68 67 66 65 2 3 4 5 6 Supply Voltage [V] [V] 68 67 66 65 -50 Ambient Temperature [] 0 50 [] 100 Fig.97 SNCA vs. Supply Voltage Fig.98 SNCA vs. Ambient Temperature Fig.99 SNCP vs. Supply Voltage Fig.100 SNCP vs. Ambient Temperature www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 30/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV External dimensions and label codes Technical Note Lot.No. Model BH76360FV BH76361FV BH76362FV BH76363FV Code 76360 76361 76362 76363 SSOP-B16 (unit: mm ) Fig.101 External Dimensions of BH7636xFV Series Package When used with 3-input, 1-output video switch BH7633xFVM Fig. 14 above shows an application example in which two of these ICs are used. When the similar IC models BH7633xFVM and BH7636xFV are used at the same time, the type of configuration shown below can be combined. In such cases, input coupling capacitors can be used, as in the application example in Fig. 14. 1 IIN1 Clamp BH76360FV External input 2 2 IIN2 Clamp Front TV 4 IIN3 Clamp 16 OUT monitor 75 75 DVD 6 1 Input coupling capacitor can be used with this. Output coupling capacitors can be omitted when using BH76330FVM or BH76360FV, and this helps reduce the number of parts. Any inputs that are not used should be connected directly to VCC or shorted with GND via a capacitor. Navigation screen IIN4 Clamp 8 IIN5 Clamp 2 Rear camera 9 IIN6 Clamp 3 3 11 BH76330FVM IIN1 Clamp 1 2 IIN2 Clamp Rear monitor Rear 3 IIN3 Clamp 16 OUT monitor 75 75 5 Fig.102 Application Example in which BH76330FVM and BH76360FV Are Used Concurrently For details of BH7633xFVM, see the BH7633xFVM Series Application Notes. www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 31/32 2009.04 - Rev.A BH76330FVM, BH76331FVM, BH76360FV, BH76361FV, BH76332FVM, BH76333FVM, BH76362FV, BH76363FV Selection of order type Technical Note B H 7 6 3 3 0 F V M T R MSOP8 Part No. BH76330FVM BH76332FVM BH76331FVM BH76333FVM BH76360FV BH76362FV BH76361FV BH76363FV Tape Quantity 2.9 0.1 Tape and Reel information TR E2 Embossed carrier tape 3000pcs TR (The direction is the 1pin of product is at the upper right when you hold reel on the left hand and you pull out the tape on the right hand) 4.0 0.2 8 5 2.8 0.1 1 4 0.475 0.9Max. 0.75 0.05 0.08 0.05 0.22 0.65 +0.05 -0.04 0.29 0.15 0.6 0.2 Direction of feed 0.145 +0.05 -0.03 0.08 M 0.08 S XX X X XXX XX X X XXX XX X X XXX XX X X XXX XX X X XXX 1Pin Reel Direction of feed (Unit:mm) When you order , please order in times the amount of package quantity. SSOP-B16 Tape Quantity 5.0 0.2 1.15 0.1 6.4 0.3 0.1 4.4 0.2 16 9 Embossed carrier tape 2500pcs 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) 1 8 0.15 0.1 0.1 0.65 0.22 0.1 0.3Min. Direction of feed 123 Reel 123 Unit:mm) When you order , please order in times the amount of package quantity. 123 1pin 1234 123 Direction of feed 1234 1234 1234 www.rohm.com (c) 2009 ROHM Co., Ltd. All rights reserved. 32/32 2009.04 - 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, fuel-controller 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 (c) 2009 ROHM Co., Ltd. All rights reserved. R0039A |
Price & Availability of BH76360FV
 |
|
|
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
| [Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
|
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |