1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 INTRODUCTION 16Pin PLASTIC-DIP The S5F329PW02 is an interline transfer CCD area image sensor developed for CCIR 1/3 inch video cameras. It can be used for door phones, surveillance cameras, object detection and pattern recognition FEATURES • High Sensitivity • Optical Size: 1/3 inch Format • Horizontal Register: 5V Drive • 16pin Plastic DIP Package • Field Integration Read Out System • No DC Bias on Reset Gate ORDERING INFORMATION Device Package Operating S5F329PW02-DAB0 16Pin PLASTIC-DIP -10 °C −+55 °C STRUCTURE • 537(H) × 597(V) Number of Total Pixels: • Number of Effective Pixels: 500(H) × 582(V) • Chip Size: 6.00mm(H) × 5.10mm(V) • Unit Pixel Size: 9.80 µm(H) × 6.30 µm(V) • Optical Blacks & Dummies: Refer to Figure Below Vertical 1 Line (Even Field Only) 16 7 500 30 1 582 V-CCD Effective Imaging Area Dummy Pixels Optical Black Pixels Effective Pixels 14 OUTPUT H-CCD 1 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA BLOCK DIAGRAM (Top View) 8 VDD 7 GND 6 VL 5 4 SUB ΦV1 3 ΦV2 2 1 ΦV3 ΦV4 Vertical Shift Register CCD Vertical Shift Register CCD Vertical Shift Register CCD Vertical Shift Register CCD Horizontal Shift Register CCD 9 VOUT 10 VGG 11 VSS 12 GND 13 VRD 14 ΦRG 15 ΦH1 16 ΦH2 Figure 1. Block Diagram PIN DESCRIPTION Table 1. Pin Description 2 Pin Symbol 1 ΦV4 2 Description Pin Symbol Description Vertical CCD transfer clock 4 9 VOUT Signal output ΦV3 Vertical CCD transfer clock 3 10 VGG Output AMP gate voltage 3 ΦV2 Vertical CCD transfer clock 2 11 VSS Output AMP source voltage 4 SUB Substrate voltage 12 GND Ground 5 ΦV1 Vertical CCD transfer clock 1 13 VRD Reset drain voltage 6 VL Protection bias voltage 14 ΦRG Charge reset clock 7 GND Ground 15 ΦH1 Horizontal CCD transfer clock 1 8 VDD Output AMP drain voltage 16 ΦH2 Horizontal CCD transfer clock 2 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 ABSOLUTE MAXIMUM RATINGS (NOTE) Table 2. Absolute Maximum Ratings Characteristics Symbols Min. Max. Unit Substrate voltage SUB - GND -0.3 55 V Supply voltage VDD, VOUT, VOUT - GND -0.3 17 V Vertical clock input voltage ΦV1, ΦV2, ΦV3, ΦV4 - GND -10 20 V ΦV1, ΦV2, ΦV3, ΦV4 - V L -0.3 30 V Horizontal clock input voltage ΦH1, ΦH2 - GND -0.3 17 V Voltage difference between vertical and ΦV1, ΦV2, ΦV3, ΦV4 -0.3 15 V horizontal clock input pins ΦH1, ΦH2 -0.3 17 V ΦH1, ΦH2 - ΦV4 -17 17 V Output clock input voltage ΦRG, ΦGG - GND -0.3 15 V Protection circuit bias voltage VL - SUB -65 0.3 V Operating temperature TOPR -10 55 °C Storage temperature TSTG -30 80 °C NOTE: The device can be destroyed, if the applied voltage or temperature is higher than the absolute maximum rating voltage or temperature. 3 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA DC CHARACTERISTICS Table 3. DC Characteristics Item Symbol Min. Typ. Max. Unit Output amp drain voltage VDD 14.55 15.0 15.45 V Output amp gate voltage VGG 1.75 2.0 2.25 V Output amp source voltage VSS Substrate voltage adjustment range SUB 7.0 14.5 V ∆VSUB -3 3 % Fluctuation range after substrate voltage adjusted Protection circuit bias voltage VL Output stage drain current IDD Ground through 680Ω Remark ±5% V VVL voltage of the vertical clock waveform 2.5 mA CLOCK VOLTAGE CONDITIONS Table 4. Clock Voltage Conditions Item Read-out clock voltage Vertical transfer clock voltage Horizontal transfer clock voltage Charge reset clock voltage Symbol Min. Typ. Max. Unit Remark VVT 14.55 15.0 15.45 V High level VVH1 ~ VVH4 -0.05 0.0 0.05 V VVH = (VVH1 + VVH2)/2 VVL1 ~ VVL4 -9.5 -9.0 -8.5 V VVL = (VVL3 + VVL4)/2 VΦH 4.75 5.0 5.25 V High VHL -0.05 0.0 0.05 V Low VΦRG 4.75 5.0 5.25 V High 0.8 V Low 25.0 V Shutter VRGLH - VRGLL Substrate clock voltage 4 VΦSUB 20.0 23.0 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 DRIVE CLOCK WAVEFORM CONDITIONS Read Out Clock Waveform 100% 90% VVH 1, VVH3 10% 0% tr twh 0V tf Vertical Transfer Clock Waveform ¥Õ V 1 ¥Õ V 3 V VH V VH V V HL VVHL VVHH V VH H V VHH VVHH VVH1 V VH L VVHL V VH3 V VL H V VL 1 V VL 3 V VL ¥Õ V 2 V VH H V VL H V VL L V VHH V VL L V VL ¥Õ V 4 V VH V V HH V VH V VH H V VHL V VH2 V VHL V VHL V VL 2 V VL L V VL 4 = ( V V H 1 + V V H 2)/ 2 V V L = (V V L 3 + V V L 4)/ 2 V ¥Õ V = V V H n - V V L n V VHL V VL H V VL H V VL V VH V VH 4 (n =1~4) V VH H V VL L V VL = V V H + 0. 3V V V H L = V V H - 0. 3 V V V L H = V V L + 0. 3V V V L L = V V L - 0. 3 V 5 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA Horizontal Transfer Clock Waveform Diagram tr twh tf 90% V¥ÕH twl 10% VH L Reset Gate Clock Waveform Diagram tr twh tf VR GH twl V¥ÕRG Point A RG waveform VRGL + 0.5V VRGLH VRGLL VRGL ¥ÕH1 waveform 10% VRGLH is the maximum value and VRGLL is the minimum value of the coupling waveform in the period from Point A in the diagram about to RG rise VRGL = (VRGLH + VRGLL)/2, VFRG = VRGH - VRGL Substrate Clock Waveform 100% 90% V¥ÕSU B 10% VSU B 6 0% tr twh tf 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 CLOCK EQUIVALENT CIRCUIT CONSTANT Table 5. Clock Equivalent Circuit Constant twh Item Vertical clock tr tf Unit Min. Read-out clock twl Symbol ΦVH Typ. Max. Min. Typ. 2.5 Max. Min. Typ. Max. Min. 0.5 Typ. Max. µs 0.5 ΦV1, ΦV2 ΦV3, ΦV4 15 250 ns ΦH1 37 41 38 42 12 15 10 15 ns ΦH2 37 41 38 42 12 15 10 15 ns Reset clock ΦRG 11 15 75 79 6.5 Substrate clock ΦSUB 1.5 2.0 Horizontal clock 4.5 0.5 ns 0.5 µs 7 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA EQUIVALENT CIRCUIT PARAMETERS Table 6. Equivalent Circuit Parameters Item Symbol Typ. Unit C ΦV1, CΦV3 1,300 pF C ΦV2, CΦV4 1,300 pF CΦV12, CΦV34 600 pF CΦV23, CΦV41 230 pF CΦV13 120 pF CΦV24 90 pF CΦH1, CΦH2 38 pF Capacitance between horizontal transfer clocks CΦH12 38 pF Capacitance between reset gate clock and GND CΦRS 10 pF Capacitance between substrate clock and GND CΦSUB 1120 pF RΦV1 ~ RΦV4 40 Ω Vertical transfer clock ground resistor RGND 15 Ω Horizontal transfer clock serial resistor RΦH1, RΦH2 10 Ω RΦRS 100 Ω Capacitance between vertical transfer clock and GND Capacitance between vertical transfer clocks Capacitance between horizontal transfer clock and GND Vertical transfer clock serial resistor Reset gate clock serial resistor ¥ÕV1 ¥ÕV2 R ¥ÕV1 R ¥ÕV2 C ¥ÕV12 C ¥ÕV1 R ¥ÕH1 C ¥ÕH12 ¥ÕH2 ¥ÕH1 C ¥ÕV2 C ¥ÕH1 C ¥ÕV41 C ¥ÕV24 C ¥ÕV13 R ¥ÕH2 C ¥ÕH2 C ¥ÕV23 R GND R ΦRS C ¥ÕV3 C ¥ÕV4 Φ RS C ¥ÕV34 R ¥ÕV4 ¥ÕV4 8 R ¥ÕV3 ¥ÕV3 C ΦRS Remark 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 OPERATING CHARACTERISTICS Device Temperature = 25 °C Table 7. Operating Characteristics Item Sensitivity Saturation signal Symbol Min. Typ. S 55 65 YSAT 600 Smear SM Blooming margin BM 0.005 Max. 0.012 1,000 Unit Remark mV/lux 1 mV 2 % 3 times 4 Uniformity U 20 % 5 Dark signal (NOTE) D 2 mV 6 ∆D 2 mV 7 Image lag YLAG 0.5 % 8 Flicker Y FY 2 % 9 Dark shading (NOTE) NOTE: Test Temperature = 55 °C TEST CONDITION 1. Use a light source with color temperature of 3,200K hallogen lamp and CM-500S for IR cut filter. The light source is adjusted in accordance with the average value of Y signals indicated in each item. 2. Through the following tests the substrate voltage should be set to the value while the device condition should be kept within the range of the bias and clock conditions. 9 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA TEST METHODS 1. Measure the light intensities (L) when the averaged illuminance output value (Y) is the standard illuminance output value, 150mV (YA) and when half of 150mV (1/2 YA). 1 Y A – ---Y A 2 S = ---------------------------LY – L 1 A ---Y A 2 2. Adjust the light intensity to 15 times of the value with which Y is YA, then measure the averaged illuminance output value (Y = YSAT). 3. Adjust the light intensity to 500 times of the value with which Y is YA, then remove the read-out clock and drain the signal in photosensors by the electronic shutter operation in all the respective horizontal blanking times with the other clocks unchanged. Measure the maximum illuminance output value (YSM). Y SM 1 1 SM = ----------× ---------- × ------- × 100 ( % ) Y A 500 10 4. Adjust the light intensity to 1,000 times of the value with which Y is YA, then inspect whether there is blooming phenomenon or not. 5. Measure the maximum and minimum illuminance output value (YMAX, YMIN) when the light intensity is adjusted to make Y to be YA. Y MAX – Y MIN - × 100 ( % ) U = ----------------------------------YA 6. Measure YD with the horizontal idling time transfer level as reference, when the device ambient temperature is 55 °C and all of the light sources are shielded. 7. Follow test method 6, measure the maximum (DMAX) and minimum illuminance output (DMIN). ∆D = D MAX – D MIN 10 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 8. Adjust the light intensity of Y signal output value by strobe light to 150mV (YA), calculate by below formula with measuring the image lag signal which is qenerated by below timing diagram. Y LAG = ( Y lag ⁄ 150 ) × 100 ( % ) FLD SG1 Light Strobe Timing Y Signal Output 150mV YLag Output 9. Adjust the light intensity of Y signal average value to 150mV (YA), calculate by below formula with measuring the signal differences (∆Yf [mV]) between fields. F Y = ( ∆Y f ⁄ Y A ) × 100 ( % ) 11 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA SPECTRAL RESPONSE CHARACTERISTICS Excluding Light Source Characteristics 1 Spectral Response 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 400 425 450 475 500 525 550 575 600 Wave Length (nm) Figure 2. Spectral Response Characteristics 12 625 650 675 700 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 APPLICATION CIRCUITS +15V 22uH 103 FH2 FH1 FRG XSUB XV2 XV1 XSG1 XV3 XSG3 XV4 + 10uF/20V 1 2 3 4 5 6 7 8 9 10 13 12 11 5V S5C7221X01 19 18 17 16 15 14 103 MA110 +15V 100K 1 Φ V4 Φ H2 16 2 Φ V3 Φ H1 15 3 Φ V2 Φ RG 14 4 SUB VRD 13 5 Φ V1 GND 12 6 VL VSS 11 7 GND VGG 10 8 VDD VOUT 9 105 103 S5F329PW02 20 103 105 22K + 47/6.3V 680 27K 180K 105 100 3.9K + + 10uF/20V 22uH 10uF/20V KSC2757 22uH CCD Output -9V +15V Figure 3. Application Circuits 13 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA READ-OUT CLOCK TIMING CHART Unit: [µs] HD V1 2.5 Odd Field V2 V3 V4 38.5 1.2 1.5 2.5 2.0 0.3 V1 V2 Even Field V3 V4 Figure 4. Read-out Clock Timing Chart 14 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 CLOCK TIMING CHART (VERTICAL SYNC.) FLD VD BLK 340 335 330 325 320 315 310 25 20 15 10 625 1 2 3 4 5 620 HD SG1 SG2 V1 V2 V3 V4 CCD OUT 582 581 246 135 246 135 582 581 2468 135 7 2468 1357 CLP1 Figure 5. Clock Timing Chart (Vertical Sync.) 15 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA CLOCK TIMING CHART (HORIZONTAL SYNC.) 5 3 2 1 7 5 3 2 1 16 15 10 5 3 2 1 30 25 20 15 10 5 3 2 1 500 495 Figure 6. Clock Timing Chart (Horizontal Sync.) 16 SUB CLP1 V4 V3 V2 V1 XSHD XSHP RS H2 H1 BLK HD 490 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA S5F329PW02 PACKAGE DIMENSIONS Unit: m m t = 0.25¡¾0.02 8.00¡¾0.10 10.20¡¾0.10 12.40¡¾0.12 2.50 2-R0.50 8.00¡¾0.10 10.20¡¾0.10 14.00¡¾0.12 1.30¡¾0.15 3.20¡¾0.15 1.27¡¾0.25 3.00¡¾0.50 0.46¡¾0.10 1.78¡¾0.50 12.46¡¾0.10 13.60¡¾0.12 NOTE: 1. Optical center deviation from mechanical center = ± 0.15mm for X and Y direction. 2. Optical surface height from glass lid surface = 1.3 ± 0.15mm 3. Optical surface height from package backside bottom = 1.9 ± 0.10mm Figure 7. Package Dimensions 17 S5F329PW02 1/3 INCH CCD IMAGE SENSOR FOR CCIR CAMERA HANDLING INSTRUCTIONS • Static Charge Prevention CCD image sensors can be easily damaged by static discharge. Before handling, be sure to take the following protective measures. — Use non chargeable gloves, clothes or material. Also use conductive shoes. — When handling directly, use an earth band. — Install a conductive mat on the floor or working table to prevent generation of static electricity. — Ionized air is recommended for discharging when handling CCD image sensor. — For the shipment of mounted substrates, use boxes treated for the prevention of static charges. • Soldering — Make sure the package temperature does not exceed 80 °C. — Solder dipping in a mounting furnace causes damage to the glass and other defects. Use a grounded 30W soldering iron and solder each pin in less than 2 seconds. For repairs and remount, cool sufficiently. — To dismount an imaging device, do not use a solder suction equipment. When using an electronic disoldering tool, use a thermal controller of the zero cross on/off type and connect to ground. • Dust and Dirt Protection — Operate in the clean environments (around class 1000 will be appropriate). — Do not either touch glass plates by hand or have object come in contact with glass surface. Should dirt stick to a glass surface blow it off with an air blow (for dirt stuck through static electricity ionized air is recommended). — Clean with a cotton bud and ethyl alcohol if the glass surface is grease stained. Be careful not to scratch the glass. — Keep in case to protect from dust and dirt. To prevent dew condensation, preheat or precool when moving to a room with great temperature differences. — When a protective tape is applied before shipping, just before use remove the tape applied electrostatic protection. Do not reuse the tape. • Do not expose to strong light (sun rays) for long period, color filter are discolored. • Exposure to high temperature or humidity will affect the characteristics. accordingly avoid storage or usage in such conditions. • CCD image sensors are precise optical equipment that should not be subject to mechanical shocks. 18