索尼正式发布背照式ToF图像传感器IMX456QL

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本相機更詳細的使用說明包含在提供的（PDF格式）SQT0914F0515KD0親愛的顧客，我們很高興能藉此機會感謝您購買Panasonic數位相機。

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電源插座應安裝在設備附近並應易於觸及。

∫產品標識產品位置數位相機底部電池充電器底部僅對於新加坡2SQT0914 (TCH)3(TCH) SQT0914∫關於電池•請勿將電池加熱或接觸明火。

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只要電源線和電源插座相連，原電路就會始終“帶電”。

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•請使用帶HDMI標誌的“High Speed HDMI micro電纜”。

IO-Link手册第三版请访问：/CN目录引言第4页第1部分：IO-Link简介第5页◆老派传感器第5页◆微型开关量传感器驱动第5页◆I O-Link：开放式低成本传感器接口第5页◆I O-Link节点第5页◆I O-Link系统第6页◆I O-Link接口在IEC 61131-9中被标准化为SDCI第6页◆物理层IO-Link标准化接口第6页◆物理层电气规范第7页◆自动化体系中的IO-Link第7页◆I O-Link：实现智能传感器第7页◆工业传感器生态系统第8页第6部分：提高系统性能第24页◆散热第24页◆测试A第24页◆测试B第24页◆测试C第24页◆热性能第24页◆分立解决方案第25页◆集成解决方案第25页◆选择TVS二极管第25页◆I O-Link保护电路第25页◆65 V（绝对最大值）如何帮助提供保护（对比40 V）第25页◆65 V绝对最大值的保护优势第25页◆小结第26页◆I O-Link信号摆率如何影响IO-Link电缆辐射？第26页引言当今的无风扇可编程逻辑控制器(PLC)和IO-Link®网关系统须消耗大量功率，具体取决于I/O配置（IO-Link、数字输入/输出、模拟输入/输出）。

随着这些PLC演变成新的工业4.0智能工厂，我们必须深谋远虑，实现更智能、更快速、更低功耗的解决方案。

这场革命的核心是一项名为“IO-Link”的新技术，能帮助实现灵活制造，从而改善工厂吞吐量，提高运营效率。

这项激动人心的新技术正使传统传感器转变为智能传感器。

ADI公司提供一系列先进的工厂自动化解决方案，并通过我们的IO-Link技术产品系列进一步改进性能，为实现工业4.0铺路架桥。

MAX22513是该产品系列的最新成员，这是一款微型双通道IO-Link收发器，集成了浪涌保护和DC-DC转换器，可减少热耗散并提高工厂车间传感器的稳定性。

为了帮助我们的客户缩短上市时间，我们与来自IO-Link联盟的软件协议栈供应商合作开发了一系列经过全面验证和测试的参考设计，本手册对此进行了详细说明。

ACV系列全线产品资料参数ACV-IR日夜两用系列热成像系统将先进的热成像能力和高清晰１６倍，18倍，２２倍，２３倍，２６倍，３０倍，３５倍，３６倍．光学一体化摄象机及ACV高速云台精准结合在一起，制造了一个完全一体化，独一无二的日夜两用型热成像定位系统。

ACV-IR 的核心是一个非制冷微型热辐射测量计，长波红外(LWIR) 摄像机。

它可生成320 x 240 辨论率的热成像视频,每个像素大小为38 μm。

ACV-IR 系列提供杰出的低于40mK 的灵敏度。

它具有多种显示模式，包括热量呈白色，黑色，和彩色系列。

ACV-IR有三种不同的镜头配置14.25 mm, 35 mm 和50 mm 焦距为了更有效地在各种环境下应用。

产品特性：解码器集成了多种协议( RS-485Pelco D 协议和P 协议)一体化红外(IR) 摄像机防护罩变速范畴0.1-80°/ 秒360°连续水平转动垂直范畴+88°至-87°可在90 英里/ 小时风速下正常工作，能承担风速达到130 英里/ 小时在风速50英里/小时的水平预置速度为每秒80°，在90 英里/小时风速时为每秒60°符合IP66 标准—云台和防护罩变速扫描速度(0.1-60°/ 秒)译码卡支持其它品牌协议易于安装- 快速简捷的电气连接最少爱护设计，无需调整齿轮满负荷连续工作128 个可编程带标识预置位自动，和随机扫描可编程停止位可编程的手动云台限位( 水平)可编程的自动扫描限位( 水平)自动巡视模式一体化防护罩，预装配热成像摄像机遮阳罩，加热器，隔热衬垫均是标准配置AC 线性锁定NTSC/PAL电气指标输入电压AC 24V, 50/60 Hz .输入电压范畴±10%功耗最大70 V A加热器温控器操纵电气连接在安装位置有两芯电源连接头和一个地线端子；一个BNC 头和四芯接头用于RS-485 Pelco D 或P 协议；两芯接线端子用,于集电极开路输出.Aux 2 2 秒触发的电极开路输出；连接的继电器鼓舞线圈的电压不得超过32 VDC 和40 mA ；ACV-IR和继电器间的线长度必须小于100 英尺(30 m)视频同输电缆最大长度电缆型号RG59/U 750 英尺(229 m)RG6/U 1,000 英尺(305 m)RG11/U 1,500 英尺(457 m)最低线缆需求：75欧姆阻抗；全铜线芯；屏蔽层覆盖率95%机械构造参数水平转动360°连续的水平转动垂直移动+88°至-87°无阻碍变速云台速度水平0.1°至60°/ 秒变速操作，加速模式下80°/ 秒垂直每秒0.1°至40°变速操作预置位速度水平80°/ 秒垂直60°/ 秒摄像机安装一体化的摄像机安装组件热成像摄像机参数成像器非制冷微型热辐射测量计，氧化钒(VOx)辨论率320x240像素大小38 μm光谱响应7.5 至13.5 μm，长波红外(LWIR)视频输出NTSC/PAL标准化来源内部快门( 补偿) ，快门动作期间冻结视频0.7 秒成像时刻小于2 秒不带热电制冷器(TEC)串行命令兼容RS-232场景温度范畴( 取决于镜头) 150°C 标准；可选的自动增益模式扩展范畴到560°C镜头选项14.25 mm, F1.3 镜头35 mm, F1.4 镜头50 mm, F1.7 镜头目标像素(POT)以下性能值基于在正常大气环境下，安装在25 英尺(8m) 高的设备与一个单人大小的目标间的距离。

水星二代（MERCURY2）USB3.0数字相机应用说明书版本：V2.0.1发布日期：2023-07-28本手册中所提及的其它软硬件产品的商标与名称，都属于相应公司所有。

本手册的版权属于中国大恒（集团）有限公司北京图像视觉技术分公司所有。

未得到本公司的正式许可，任何组织或个人均不得以任何手段和形式对本手册内容进行复制或传播。

本手册的内容若有任何修改，恕不另行通知。

© 2023中国大恒（集团）有限公司北京图像视觉技术分公司版权所有网站：公司总机：************客户服务热线：400-999-7595销售信箱：************************支持信箱：**************************首先感谢您选用大恒图像产品，水星二代（MERCURY2）USB3.0接口数字相机是我公司最新推出的大靶面高分辨率工业数字相机，它具有高分辨率、高清晰度、低噪声等特点。

水星二代USB3.0相机包括标准版（MER2-U3(-L)系列）、Pro版（ME2P-U3系列）、Lite版（ME2L-U3(-L)系列）和Super版（ME2S-U3系列），相机采用了USB3.0标准接口，安装、使用方便。

适用于工业检测、医疗、科研、教育、安防等领域。

本手册详细介绍了水星二代USB3.0接口数字相机的应用。

1. 概述 (1)1.1. 系列概述 (1)1.2. 型号名称说明 (1)1.3. 遵循的标准 (1)1.4. 相关文档及软件下载 (1)2. 注意事项及认证声明 (2)2.1. 安全声明 (2)2.2. 使用注意事项 (2)2.3. EMI、ESD注意事项 (3)2.4. 使用环境注意事项 (3)2.5. 相机机械安装注意事项 (3)2.6. 认证声明 (3)3. 安装指南 (5)3.1. 主机端准备 (5)3.1.1. 用户软件组成 (5)3.1.2. 用户软件接口 (5)3.2. 相机供电 (6)3.2.1. MER2/ME2P/ME2L系列 (6)3.2.2. ME2S系列 (6)3.3. 相机驱动安装 (7)3.3.1. 系统要求 (7)3.3.2. 驱动安装 (7)3.4. 打开相机采集 (7)4. 性能参数 (8)4.1. 重要参数解释 (8)4.1.1. 关于光谱响应图 (8)4.2.1. MER2-041-436U3M/C(-L) (8)4.2.2. MER2-041-528U3M/C(-L) (9)4.2.3. MER2-135-150U3M/C(-L) (11)4.2.4. MER2-135-208U3M/C(-L) (12)4.2.5. MER2-160-227U3M/C(-L) (14)4.2.6. MER2-230-168U3M/C(-L) (15)4.2.7. MER2-231-41U3M/C(-L) (17)4.2.8. MER2-301-125U3M/C(-L) (18)4.2.9. MER2-302-56U3M/C(-L) (20)4.2.10. MER2-502-79U3M/C(-L) (21)4.2.11. MER2-502-79U3M POL (23)4.2.12. MER2-503-36U3M/C(-L) (24)4.2.13. MER2-503-36U3M POL (26)4.2.14. MER2-630-60U3M/C(-L/-W90) (27)4.2.15. MER2-1220-32U3M/C(-L/-W90) (29)4.2.16. MER2-2000-19U3M/C(-L/-W90) (30)4.3. ME2S-U3 系列 (32)4.3.1. ME2S-560-70U3M/C (32)4.3.2. ME2S-1260-28U3M/C (33)4.3.3. ME2S-1610-24U3M/C (35)4.3.4. ME2S-2020-19U3M/C (36)4.3.5. ME2S-2440-16U3M/C (38)4.4. ME2P-U3 系列 (39)4.4.1. ME2P-560-36U3M/C (39)4.4.2. ME2P-900-43U3M/C (41)4.4.3. ME2P-1230-23U3M/C (42)4.4.4. ME2P-1231-32U3M/C (44)4.4.5. ME2P-1840-21U3M/C (45)4.4.6. ME2P-2621-15U3M/C \ ME2P-2622-15U3M/C (47)4.4.7. ME2P-2621-15U3M NIR \ ME2P-2622-15U3M NIR (49)4.5. ME2L-U3(-L) 系列 (51)4.5.1. ME2L-161-61U3M/C(-L) (51)4.5.2. ME2L-203-76U3M/C(-L) (52)4.5.3. ME2L-204-76U3C(-L)-F02 (53)4.5.4. ME2L-505-36U3M/C(-L) (54)4.5.5. ME2L-830-22U3M/C(-L) (56)5. 机械尺寸 (58)5.1. 相机尺寸 (58)5.2. 光学接口 (61)6. 滤光片及镜头 (63)6.1. 滤光片规格参数及响应图 (63)6.2. 镜头选型参考 (64)6.2.1. HN-2M系列定焦镜头 (64)6.2.2. HN-5M 系列定焦镜头 (65)6.2.3. HN-6M 系列定焦镜头 (65)6.2.4. HN-20M 系列定焦镜头 (66)6.2.5. HN-P-6M 系列定焦镜头 (66)6.2.6. HN-P-10M 系列定焦镜头 (67)6.2.7. HN-P-20M 系列定焦镜头 (67)6.2.8. HN-P-25M 系列定焦镜头 (68)6.2.9. HN-P 系列8K~16K线扫镜头 (68)7. 电气接口 (69)7.1. LED灯状态 (69)7.1.1. MER2/ME2P/ME2L系列 (69)7.1.2. ME2S系列 (69)7.2. USB接口 (69)7.3. I/O接口 (70)7.3.1. I/O接口定义 (70)7.3.1.1. MER2/ME2P系列 (70)7.3.1.2. ME2L系列 (70)7.3.1.3. ME2S系列 (71)7.3.2. I/O电气特性 (71)7.3.2.1. Line0（光耦隔离输入）电路 (71)7.3.2.2. Line1（光耦隔离输出）电路 (74)7.3.2.3. Line2/3（双向）电路 (76)8. 功能定义 (83)8.1.1. 配置输入引脚 (83)8.1.2. 配置输出引脚 (84)8.1.3. 读取引脚状态 (89)8.2. 图像采集控制 (89)8.2.1. 开始采集/停止采集 (89)8.2.1.1. 开始采集 (89)8.2.1.2. 停止采集 (90)8.2.2. 采集模式 (91)8.2.3. 触发类型选择 (92)8.2.4. 触发模式切换 (93)8.2.5. 连续采集及其配置 (94)8.2.6. 突发采集功能 (95)8.2.7. 软触发采集及其配置 (96)8.2.8. 外触发采集及其配置 (96)8.2.9. 交叠曝光和非交叠曝光 (97)8.2.10. 设置曝光 (99)8.2.10.1. 设置曝光模式 (99)8.2.10.2. 设置Sensor曝光模式 (101)8.2.10.3. 设置曝光时间模式 (103)8.2.10.4. 设置曝光时间值 (104)8.2.11. 曝光延迟 (104)8.3. 基本属性设置 (106)8.3.1. 增益 (106)8.3.2. Sensor位深 (107)8.3.3. 像素格式 (107)8.3.4. ROI (112)8.3.5. 自动曝光和自动增益 (112)8.3.6. 测试图 (114)8.3.7. 参数组 (116)8.3.9. 时间戳 (118)8.3.10. Binning (118)8.3.11. 像素抽样 (121)8.3.12. 镜像翻转 (123)8.3.13. 数字移位 (125)8.3.14. 采集状态 (127)8.3.15. 黑电平和自动黑电平 (128)8.3.15.1. 黑电平 (128)8.3.15.2. 自动黑电平 (128)8.3.16. 取消参数范围限制 (129)8.3.17. 用户数据区 (137)8.3.18. 定时器 (138)8.3.19. 计数器 (139)8.3.20. 多帧灰度控制 (141)8.4. 图像处理 (142)8.4.1. 环境光源预设 (142)8.4.2. 自动白平衡 (144)8.4.3. 颜色转换 (145)8.4.4. Gamma (147)8.4.5. 查找表 (148)8.4.6. 锐化 (150)8.4.6.1. 锐化 (150)8.4.6.2. 带噪声抑制的锐化 (151)8.4.7. 平场校正 (152)8.4.7.1. 平场校正系数的求取和预览 (154)8.4.7.2. 系数的读取和保存 (155)8.4.7.3. 文件的读取与保存 (155)8.4.7.4. 平场校正使用注意事项 (155)8.4.8. 降噪 (156)8.5. 图像传输 (158)8.5.1. 帧率计算 (158)8.5.2. USB接口带宽 (159)8.5.3. 设备链路带宽限制 (159)8.5.4. 相机采集时间计算 (160)8.6. 事件 (166)8.6.1. 曝光结束事件 (167)8.6.2. 图像帧数据丢弃事件 (167)8.6.3. 帧存不为空事件 (168)8.6.4. 帧开始触发信号溢出事件 (168)8.6.5. 帧高速连拍开始触发信号溢出事件 (168)8.6.6. 帧开始触发信号等待事件 (168)8.6.7. 帧高速连拍开始触发信号等待事件 (168)9. 软件工具 (170)9.1. 查找表生成插件 (170)9.1.1. 界面 (170)9.1.2. 使用说明 (171)9.1.2.1. 使用场景 (171)9.1.2.2. 基准Lut选择 (171)9.1.2.3. 调整Lut (173)9.1.2.4. 保存查找表 (174)9.1.2.5. 读取Lut (174)9.1.3. 注意事项 (175)9.1.3.1. 从设备中读取 (175)9.1.3.2. Lut写入设备 (175)9.1.3.3. 目录结构 (175)9.2. 平场校正插件 (175)9.2.1. 界面 (176)9.2.2.1. 平场校正执行步骤 (177)9.2.2.2. 采集亮场图像 (177)9.2.2.3. 执行平场校正 (178)9.2.2.4. 校正数据从设备读取/写入设备 (178)9.2.2.5. 校正数据从文件加载/保存到文件 (178)9.2.3. 注意事项 (178)9.2.3.1. 平场校正实现方式 (178)9.2.3.2. 预览 (179)9.3. 帧率计算工具 (180)9.4. 静态坏点校正插件 (181)9.4.1. 界面 (181)9.4.2. 使用说明 (183)9.4.2.1. 执行静态坏点校正步骤 (183)9.4.2.2. 捕获图像 (183)9.4.2.3. 静态坏点校正 (183)9.4.2.4. 坏点数据文件使用 (184)10. 常见问题处理 (185)11. 版本说明 (187)12. 联系方式 (192)12.1. 销售联系方式 (192)12.2. 技术支持联系方式 (192)12.3. 总部及各办事处联系方式 (192)1.概述1.概述1.1.系列概述水星二代（MERCURY2）USB3.0数字相机是由大恒图像自主研发的成熟产品，性能出色、价格实惠、安装、使用方便。

光电传感器Subject to change –2018/102→Internet:/catalogue/...光电传感器SOOD,SOOE主要特性和产品范围一览产品范围一览派生型SOOD LEDSOOD 激光SOOE LED SOOE 激光→页码/Internet 漫反射式传感器，带背景抑制⏹⏹⏹⏹12,24对射式传感器⏹⏹⏹⏹18,28反射式传感器⏹⏹⏹⏹21,32反射式传感器，用于透明物体––⏹–35漫反射式传感器––⏹–38激光，对比传感器–––⏹42激光，距离传感器––⏹⏹46检测方法漫反射式传感器SOOE-DS这些传感器有时候被称为能量传感器，发射器和接收器同处一个壳体内。

发射出的光束直接被物体反射到接收器，计算反射光束的强度。

通过改变接收器（用IO-Link®、电位计或示教方法）的灵敏度可调节工作距离。

漫反射式传感器是成本效益最高的解决方案之一，安装也十分快捷。

不过，这些传感器不适用于一些应用场合，例如在强反射背景下检测轻微反光的物体。

此外，采用多种不同表面的物体（从材料、颜色或表面光洁度的角度出发）因为不同表面的反射特性不同，所以需要在不同的距离进行测量。

漫反射式传感器的优点在于强度区分。

•工作距离更长•经济性更佳•检测轻微反光的物体时更可靠-V-新产品光电传感器SOOD,SOOE 主要特性漫反射式传感器，带背景抑制工作距离并非通过能量来设定，而是通过光学三角测量。

全新且高精度的多像素技术(SOOE)有着优异的灵活性，通过IO-Link®设置。

带160x16像素的信号预处理的集成接收器是精确检测与距离测量的关键。

该接收器具备高分辨率和线性化，在检测范围上限有着独特的设定性能。

因此，物体检测几乎独立于背景中的其它物体之外，也与颜色、大小或表面光洁度无关。

这些设备仅要求有非常少量的漫反射。

带背景抑制的漫反射式传感器的优点•工作距离实际上与颜色和表面光洁度无关•还可用于闪光或反光的背景•检测距离的小差异•调节方便反射式传感器这些传感器的发射器和接收器也同处一个壳体内。

© 2007 OmniVision Technologies, Inc.VarioPixel, OmniVision, and the OmniVision logo are registered trademarks of OmniVision Technologies, Inc.Version 1.1, March 30, 2007OmniPixel2 and CameraChip are trademarks of OmniVision Technologies, Inc.These specifications are subject to change without notice.Advanced Information Preliminary DatasheetOV7725 Color CMOS VGA (640x480) C AMERA C HIP TM SensorO mniision®with OmniPixel2TM TechnologyGeneral DescriptionThe OV7725 C AMERA C HIP ™ image sensor is a low voltage CMOS device that provides the full functionality of a single-chip VGA camera and image processor in a small footprint package. The OV7725 provides full-frame,sub-sampled or windowed 8-bit/10-bit images in a wide range of formats, controlled through the Serial CameraApplications•Cellular and picture phones •Toys•PC Multimedia•Digital still camerasKey SpecificationsOV7725Color CMOS VGA OmniPixel2™C AMERA C HIP™ Sensor OFunctional DescriptionFigure2 shows the functional block diagram of the OV7725 image sensor. The OV7725 includes:•Image Sensor Array (total array of 656 x 488 pixels, with active pixels 640 x 480 in YUV mode)•Analog Signal Processor•A/D Converters•Test Pattern Generator•Digital Signal Processor (DSP)•Image Scaler•Timing Generator2Proprietary to OmniVision Technologies, Inc.Version 1.1, March 30, 2007Functional DescriptionVersion 1.1, March 30, 2007Proprietary to OmniVision Technologies, Inc.3OImage Sensor ArrayThe OV7725 sensor has an image array of 656x 488pixels for a total of 320,128 pixels, of which 640x 480pixels are active (307,200 pixels). Figure 3 shows a cross-section of the image sensor array.Figure 3 Image Sensor Arrayoperates at speeds up to 12 MHz and is fully synchronous to the pixel rate (actual conversion rate is related to the frame rate).In addition to the A/D conversion, this block also has the following functions:•Digital Black-Level Calibration (BLC)•Optional U/V channel delay •Additional A/D range controls In general, the combination of the A/D Range Multiplier and A/D Range Control sets the A/D range and maximum value to allow the user to adjust the final image brightness as a function of the individual application.Test Pattern GeneratorOL /I OH drive currentthe C AMERA C HIP sensor operation. Refer to OmniVision Technologies Serial Camera Control Bus (SCCB)Specification for detailed usage of the serial control port.4Proprietary to OmniVision Technologies, Inc.Version 1.1, March 30, 2007OV7725Color CMOS VGA OmniPixel2™ C AMERA C HIP ™ SensorOPin DescriptionTable 1Pin DescriptionPin NumberName Pin Type Function/DescriptionA1ADVDD Power ADC power supplyA2RSTB Input System reset input, active lowA3VREFH Reference Reference voltage - connect to ground using a 0.1 µF capacitor A4FSIN Input Frame synchronize input A5SCL Input SCCB serial interface clock input A6D0a a. D[9:0] for 10-bit Raw RGB data (D[9] MSB, D[0] LSB)Output Data output bit[0]B1ADGND Power ADC groundB2VREFN Reference Reference voltage - connect to ground using a 0.1 µF capacitor B3AVDD Power Analog power supply B4AGND Power Analog groundB5SDA I/O SCCB serial interface data I/O B6HREF Output HREF outputC1PWDN Input (0)b b. Input (0) represents an internal pull-down resistor.Power Down Mode Selection0:Normal mode1:Power down mode C6VSYNC Output Vertical sync output D1D5Output Data output bit[5]D6D4Output Data output bit[4]E1D7Output Data output bit[7]E2D1Output Data output bit[1]E3DVDD Power Power supply (+1.8 VDC) for digital logic core E4PCLK Output Pixel clock outputE5DOVDD Power Digital power supply for I/O (1.7V ~ 3.3V)E6D6Output Data output bit[6]F1D9c c. D[9:2] for 8-bit YUV or RGB565/RGB555 (D[9] MSB, D[2] LSB)Output Data output bit[9]F2D3Output Data output bit[3]F3XCLK Input System clock input F4DOGND Power Digital ground F5D2Output Data output bit[2]F6D8OutputData output bit[8]Electrical CharacteristicsVersion 1.1, March 30, 2007Proprietary to OmniVision Technologies, Inc.5OElectrical CharacteristicsNOTE:Exceeding the Absolute Maximum ratings shown above invalidates all AC and DC electrical specifications and may result in permanent device damage.Table 2Operating ConditionsParameterMin Max Operating temperature -20°C +70°C Storage temperature a a.Exceeding the stresses listed may permanently damage the device. This is a stress rating only and functional operation of the sensor at these and any other condition above those indicated in this specification is not implied. Exposure to absolute maximum rating conditions for any extended period may affect reliability.-40°C+125°CTable 3 Absolute Maximum RatingsAmbient Storage Temperature-40ºC to +95ºCSupply Voltages (with respect to Ground)V DD-A4.5 V V DD-C 3 V V DD-IO4.5 VAll Input/Output Voltages (with respect to Ground)-0.3V to V DD-IO +0.5V Lead-free Temperature, Surface-mount process 245ºCTable 4DC Characteristics (-20°C < T A < 70°C)Symbol ParameterConditionMin Typ Max Unit V DD-A DC supply voltage – analog – 3.0 3.3 3.6V V DD-C DC supply voltage – digital core – 1.62 1.8 1.98V V DD-IO DC supply voltage – I/O – 2.5– 3.3V I DDA Active (operating) current See Note a a.At 25ºC, V DD-A = 3.3V, V DD-C = 1.8V, V DD-IO = 3.3VI DDA = {I DD-IO + I DD-C + I DD-A }, f CLK = 24MHz at 30 fps YUV output, no I/O loading 10 + 8bb. I DD-C = 10mA, I DD-A = 8mA, without loadingmA I DDS-SCCB Standby current See Note c c. At 25ºC, V DD-A = 3.3V, V DD-C = 1.8V, V DD-IO = 3.3VI DDS-SCCB refers to a SCCB-initiated Standby, while I DDS-PWDN refers to a PWDN pin-initiated Standby 1mA I DDS-PWDN Standby current 1020µA V IH Input voltage HIGH CMOS0.7 x V DD-IOV V IL Input voltage LOW 0.3 x V DD-IOV V OH Output voltage HIGH CMOS0.9 x V DD-IOV V OL Output voltage LOW 0.1 x V DD-IOV I OH Output current HIGH See Note dd. Standard Output Loading = 25pF, 1.2K 8mA I OL Output current LOW 15mA I L Input/Output leakageGND to V DD-IO ± 1µAOV7725Color CMOS VGA OmniPixel2™C AMERA C HIP™ Sensor OTable 5 Functional and AC Characteristics (-20°C < T A < 70°C)Symbol Parameter Min Typ Max Unit Functional CharacteristicsA/D Differential non-linearity+ 1/2LSBA/D Integral non-linearity+1LSBAGC Range30dBRed/Blue adjustment range12dB Inputs (PWDN, CLK, RESET#)f CLK Input clock frequency102448MHzt CLK Input clock period2142100ns t CLK:DC Clock duty cycle455055% t S:RESET Setting time after software/hardware reset1ms t S:REG Settling time for register change (10 frames required)300ms SCCB Timing (see Figure4)f SCL Clock frequency400KHzt LOW Clock low period 1.3µs t HIGH Clock high period600ns t AA SCL low to data out valid100900ns t BUF Bus free time before new START 1.3µs t HD:STA START condition hold time600ns t SU:STA START condition setup time600ns t HD:DAT Data in hold time0µs t SU:DAT Data in setup time100ns t SU:STO STOP condition setup time600ns t R, t F SCCB rise/fall times300ns t DH Data out hold time50ns Outputs (VSYNC, HREF, PCLK, and D[9:0] (see Figure5, Figure6, Figure7, and Figure8)t PDV PCLK[ ] to data out Valid5ns t SU D[9:0] setup time15ns t HD D[9:0] Hold time8ns t PHH PCLK[ ] to HREF[ ]05ns t PHL PCLK[ ] to HREF[ ]05nsAC Conditions: V DD: V DD-C = 1.8V, V DD-A = 3.3V, V DD-IO = 3.3V Rise/Fall Times: I/O: 5ns, MaximumSCCB: 300ns, MaximumInput Capacitance: 10pfOutput Loading: 25pF, 1.2K to 3.3Vf CLK: 24MHz6Proprietary to OmniVision Technologies, Inc.Version 1.1, March 30, 2007Timing SpecificationsVersion 1.1, March 30, 2007Proprietary to OmniVision Technologies, Inc.7OTiming SpecificationsFigure 4SCCB Timing DiagramOV7725Color CMOS VGA OmniPixel2™C AMERA C HIP™ Sensor OFigure 6 VGA Frame Timing8Proprietary to OmniVision Technologies, Inc.Version 1.1, March 30, 2007Timing SpecificationsVersion 1.1, March 30, 2007Proprietary to OmniVision Technologies, Inc.9OFigure 9 RGB 565 Output Timing DiagramFigure 10OV7725Color CMOS VGA OmniPixel2™C AMERA C HIP™ Sensor OFigure 11 RGB 444 Output Timing Diagram10Proprietary to OmniVision Technologies, Inc.Version 1.1, March 30, 2007Register Set Table6 provides a list and description of the Device Control registers contained in the OV7725. For all register Enable/Disable bits, ENABLE = 1 and DISABLE = 0. The device slave addresses are 42 for write and 43 for read.Table 6 Device Control Register List (Sheet 1 of 13)Address (Hex)RegisterNameDefault(Hex)R/W Description00GAIN00RW AGC – Gain control gain setting Bit[7:0]:AGC[7:0]•Range: [00] to [FF]01BLUE80RW AWB – Blue channel gain setting •Range: [00] to [FF]02RED80RW AWB – Red channel gain setting •Range: [00] to [FF]03GREEN00RW AWB – Green channel gain setting •Range: [00] to [FF]04RSVD XX–Reserved05BAVG00RW U/B Average LevelAutomatically updated based on chip output format06GAVG00RW Y/Gb Average LevelAutomatically updated based on chip output format07RAVG00RW V/R Average LevelAutomatically updated based on chip output format08AECH00RW Exposure Value – AEC MSBsBit[7:0]:AEC[15:8] (see register AEC for AEC[7:0]} Automatically updated based on chip output format09COM201RW Common Control 2Bit[7:5]:ReservedBit[4]:Soft sleep modeBit[3:2]:ReservedBit[1:0]:Output drive capability00:1x01:2x10:3x11:4x0A PID77R Product ID Number MSB (Read only) 0B VER21R Product ID Number LSB (Read only)0C COM310RW Common Control 3Bit[7]:Vertical flip image ON/OFF selectionBit[6]:Horizontal mirror image ON/OFF selectionBit[5]:Swap B/R output sequence in RGB output modeBit[4]:Swap Y/UV output sequence in YUV output modeBit[3]:Swap output MSB/LSBBit[2]:Tri-state option for output clock at power-down period 0:Tri-state at this period1:No tri-state at this periodBit[1]:Tri-state option for output data at power-down period 0:Tri-state at this period1:No tri-state at this periodBit[0]:Sensor color bar test pattern output enable0D COM441RW Common Control 4Bit[7:6]:PLL frequency control00:Bypass PLL01:PLL 4x10:PLL 6x11:PLL 8xBit[5:4]:AEC evaluate window00:Full window01:1/2 window10:1/4 window11:Low 2/3 window Bit[3:0]:Reserved0E COM501RW Common Control 5Bit[7]:Auto frame rate control ON/OFF selection (night mode) Bit[6]:Auto frame rate control speed selectionBit[5:4]:Auto frame rate max rate control00:No reduction of frame rate01:Max reduction to 1/2 frame rate10:Max reduction to 1/4 frame rate11:Max reduction to 1/8 frame rateBit[3:2]:Auto frame rate active point control00:Not allowed01:Add frame when AGC reaches 4x gain10:Add frame when AGC reaches 8x gain11:Add frame when AGC reaches 16x gain Bit[1]:ReservedBit[0]:AEC max step control0:AEC increase step has limit1:No limit to AEC increase step0F COM643RW Common Control 6Bit[7:1]:ReservedBit[0]:Auto window setting ON/OFF selection when format changes(Hex)Name(Hex)R/W Description10AEC40RW Exposure ValueBit[7:0]:AEC[7:0] (see register AECH for AEC[15:8])11CLKRC80RW Internal ClockBit[7]:ReservedBit[6]:Use external clock directly (no clock pre-scale available)Bit[5:0]:Internal clock pre-scalarF(internal clock) = F(input clock)/(Bit[5:0]+1)/2•Range: [0 0000] to [1 1111]12COM700RW Common Control 7Bit[7]:SCCB Register Reset0:No change1:Resets all registers to default values Bit[6]:Resolution selection0:VGA1:QVGABit[5]:BT.656 protocol ON/OFF selectionBit[4]:Sensor RAWBit[3:2]:RGB output format control00:GBR4:2:201:RGB56510:RGB55511:RGB444Bit[1:0]:Output format control00:YUV01:Processed Bayer RAW10:RGB11:Bayer RAW13COM88F RW Common Control 8Bit[7]:Enable fast AGC/AEC algorithmBit[6]:AEC - Step size limit0:Step size is limited to vertical blank1:Unlimited step sizeBit[5]:Banding filter ON/OFFBit[4]:Enable AEC below banding valueBit[3]:Fine AEC ON/OFF controlBit[2]:AGC EnableBit[1]:AWB EnableBit[0]:AEC Enable(Hex)Name(Hex)R/W Description14COM94A RW Common Control 9Bit[7]:Histogram or average based AEC/AGC selection Bit[6:4]:Automatic Gain Ceiling - maximum AGC value000:2x001:4x010:8x011:16x100:32x101Not allowed110:Not allowed111:Not allowedBit[3]:ReservedBit[2]:Drop VSYNC output of corrupt frameBit[1]:Drop HREF output of corrupt frameBit[0]:Reserved15COM1000RW Common Control 10Bit[7]:Output negative dataBit[6]:HREF changes to HSYNCBit[5]:PCLK output option0:Free running PCLK1:PCLK does not toggle during horizontal blank Bit[4]:PCLK reverseBit[3]:HREF reverseBit[2]:VSYNC option0:VSYNC changes on falling edge of PCLK1:VSYNC changes on rising edge of PCLK Bit[1]:VSYNC negativeBit[0]:Output data range selection0:Full range1:Data from [10] to [F0] (8 MSBs)16REG1600RW Register 16Bit[7]:Bit shift test pattern optionsBit[6:0]:Reserved17HSTART23 (VGA)3F (QVGA)RWHorizontal Frame (HREF column) Start 8 MSBs (2 LSBs are atHREF[5:4])18HSIZEA0 (VGA)50 (QVGA)RW Horizontal Sensor Size (2 LSBs are at HREF[1:0])19VSTRT07 (VGA)03 (QVGA)RW Vertical Frame (row) Start 8 MSBs (1 LSB is at HREF[6])1A VSIZEF0 (VGA)78 (QVGA)RW Vertical Sensor Size (1 LSB is at HREF[2])1B PSHFT40RW Data Format - Pixel Delay Select (delays timing of the D[9:0] data relative to HREF in pixel units)•Range: [00] (no delay) to [FF] (256 pixel delay which accounts for whole array)(Hex)Name(Hex)R/W Description1C MIDH7F R Manufacturer ID Byte – High(Read only = 0x7F)1D MIDL A2R Manufacturer ID Byte – Low(Read only = 0xA2)1E RSVD XX–Reserved1F LAEC00RW Fine AEC Value - defines exposure value less than one row period20COM1110RW Common Control 11Bit[7:2]:ReservedBit[1]:Single frame ON/OFF selection Bit[0]:Single frame transfer trigger21RSVD XX–Reserved22BDBase FF RW Banding Filter Minimum AEC Value23BDMStep01RW Banding Filter Maximum Step24AEW75RW AGC/AEC - Stable Operating Region (Upper Limit) 25AEB63RW AGC/AEC - Stable Operating Region (Lower Limit)26VPT D4RW AGC/AEC Fast Mode Operating RegionBit[7:4]:High nibble of upper limit of fast mode control zone Bit[3:0]:High nibble of lower limit of fast mode control zone27RSVD XX–Reserved28REG2800RW Register 28Bit[7:1]:ReservedBit[0]:Selection on the number of dummy rows, N29HOutSizeA0 (VGA)50 (QVGA)RW Horizontal Data Output Size MSBs (2 LSBs at register EXHCH[1:0])2A EXHCH00RW Dummy Pixel Insert MSBBit[7:4]: 4 MSB for dummy pixel insert in horizontal direction Bit[3]:ReservedBit[2]:Vertical data output size LSBBit[1:0]:Horizontal data output size 2 LSBs2B EXHCL00RW Dummy Pixel Insert LSB8 LSB for dummy pixel insert in horizontal direction2C VOutSizeF0 (VGA)78 (QVGA)RW Vertical Data Output Size MSBs (LSB at register EXHCH[2])2D ADVFL00RW LSB of Insert Dummy Rows in Vertical Sync (1 bit equals 1 row) 2E ADVFH00RW MSB of Insert Dummy Rows in Vertical Sync2F YAVE00RW Y/G Channel Average Value30LumHTh80RW Histogram AEC/AGC Luminance High Level Threshold31LumLTh60RW Histogram AEC/AGC Luminance Low Level Threshold (Hex)Name(Hex)R/W Description32HREF00RW Image Start and Size ControlBit[7]:Mirror image edge alignmentBit[6]:Vertical HREF window start control LSBBit[5:4]:Horizontal HREF window start control LSBsBit[3]:Data output bit shift test pattern ON/OFF control Bit[2]:Vertical sensor size LSBBit[1:0]:Horizontal sensor size 2 LSBs33DM_LNL00RW Dummy Row Low 8 Bits34DM_LNH00RW Dummy Row High 8 Bits35ADoff_B80RW AD Offset Compensation Value for B Channel36ADoff_R80RW AD Offset Compensation Value for R Channel37ADoff_Gb80RW AD Offset Compensation Value for Gb Channel38ADoff_Gr80RW AD Offset Compensation Value for Gr Channel39Off_B80RW Analog Process B Channel Offset Compensation Value 3A Off_R80RW Analog Process R Channel Offset Compensation Value 3B Off_Gb80RW Analog Process Gb Channel Offset Compensation Value 3C Off_Gr80RW Analog Process Gr Channel Offset Compensation Value3D COM1280RW Common Control 12Bit[7:6]:ReservedBit[5:0]:DC offset compensation for analog process3E COM13E2RW Common Control 13Bit[7]:BLC enableBit[6]:ADC channel BLC ON/OFF controlBit[5]:Analog processing channel BLC ON/OFF control Bit[4:3]:ReservedBit[2]:ABLC gain trigger enableBit[1:0]:Reserved3F COM141F RW Edge Enhancement AdjustmentBit[7:4]:ReservedBit[3:2]:AD offset compensation optionx0:Use R/Gr channel value for B/Gb01:Use B/Gb channel value for R/Gr11:Use B/Gb/R/Gr channel value independently Bit[1:0]:Analog processing offset compensation optionx0:Use R/Gr channel value for B/Gb01:Use B/Gb channel value for R/Gr11:Use B/Gb/R/Gr channel value independently(Hex)Name(Hex)R/W Description40COM15C0RW Common Control 15Bit[7:4]:ReservedBit[3]:AD add 128 bit offsetBit[2:0]:Reserved41COM1608RW Common Control 16Bit[7:2]:ReservedBit[1:0]:BLC target 2 LSBs42TGT_B80RW BLC Blue Channel Target Value 43TGT_R80RW BLC Red Channel Target Value 44TGT_Gb80RW BLC Gb Channel Target Value 45TGT_Gr80RW BLC Gr Channel Target Value46LC_CTR00RW Lens Correction ControlBit[7:3]:ReservedBit[2]:Lens correction control select0:R, G, and B channel compensation coefficient isset by registers LC_COEF (0x49)1:R, G, and B channel compensation coefficient isset by registers LC_COEFB (0x4B), LC_COEF(0x49), and LC_COEFR (0x4C), respectively Bit[1]:ReservedBit[0]:Lens correction enable0:Disable1:Enable47LC_XC00RW X Coordinate of Lens Correction Center Relative to Array Center Bit[7]:Sign bit0:Positive1:NegativeBit[6:0]:X coordinate of lens correction center relative to array center48LC_YC00RW Y Coordinate of Lens Correction Center Relative to Array Center Bit[7]:Sign bit0:Positive1:NegativeBit[6:0]:Y coordinate of lens correction center relative to array center49LC_COEF50RW Lens Correction CoefficientG channel compensation coefficient when LC_CTR[2] (0x46) is 1 R, G, and B channel compensation coefficient when LC_CTR[2] is 04A LC_RADI30RW Lens Correction Radius – radius of the circular section where no compensation applies4B LC_COEFB50RW Lens Correction B Channel Compensation Coefficient (effective only when LC_CTR[2] is high)(Hex)Name(Hex)R/W Description4C LC_COEFR50RW Lens Correction R Channel Compensation Coefficient (effective only when LC_CTR[2] is high)4D FixGain00RW Analog Fix Gain AmplifierBit[7:6]:Gb channel fixed gainBit[5:4]:Gr channel fixed gainBit[3:2]: B channel fixed gainBit[1:0]:R channel fixed gain4E AREF0EF RW Sensor Reference Control •Range: [00] to [FF]4F AREF110RW Sensor Reference Current ControlBit[7:4]:Sensor reference current controlBit[3]:Internal regulator ON/OFF selection Bit[2]:ReservedBit[1:0]:Analog reference control50AREF260RW Analog Reference Control •Range: [00] to [FF]51AREF300RW ADC Reference Control •Range: [00] to [FF]52AREF400RW ADC Reference Control •Range: [00] to [FF]53AREF524RW ADC Reference Control •Range: [00] to [FF]54AREF67A RW Analog Reference Control •Range: [00] to [FF]55AREF7FC RW Analog Reference Control •Range: [00] to [FF]56-5F RSVD XX–Reserved60UFix80RW U Channel Fixed Value Output 61VFix80RW V Channel Fixed Value Output 62AWBb_blk FF RW AWB Option for Advanced AWB63AWB_Ctrl0F0RW AWB Control Byte 0Bit[7]:AWB gain enableBit[6]:AWB calculate enableBit[5]:ReservedBit[4:0]:WBC threshold 2(Hex)Name(Hex)R/W Description64DSP_Ctrl11F RW DSP Control Byte 1Bit[7]:FIFO enable/disable selectionBit[6]:UV adjust function ON/OFF selection Bit[5]:SDE enableBit[4]:Color matrix ON/OFF selectionBit[3]:Interpolation ON/OFF selectionBit[2]:Gamma function ON/OFF selectionBit[1]:Black defect auto correction ON/OFF Bit[0]:White defect auto correction ON/OFF65DSP_Ctrl200RW DSP Control Byte 2Bit[7:4]:ReservedBit[3]:Vertical DCW enableBit[2]:Horizontal DCW enableBit[1]:Vertical zoom out enableBit[0]:Horizontal zoom out enable66DSP_Ctrl310RW DSP Control Byte 3Bit[7]:UV output sequence optionBit[6]:ReservedBit[5]:DSP color bar ON/OFF selectionBit[4]:ReservedBit[3]:FIFO power down ON/OFF selectionBit[2]:Scaling module power down control 1Bit[1]:Scaling module power down control 2Bit[0]:Interpolation module power down control67DSP_Ctrl400RW DSP Control Byte 4Bit[7:3]:ReservedBit[2]:AEC selection0:Before gamma1:After gamma Bit[1:0]:Output selection00:YUV or RGB01:YUV or RGB10:RAW811:RAW1068AWB_bias00RW AWB BLC Level Clip69AWBCtrl15C RW AWB Control 1Bit[7:4]:ReservedBit[3]:G gain enable0:AWB adjusts R and G gain1:AWB adjusts R, G, and B gain Bit[2]:Max color gain0:Max color gain is 2x1:Max color gain is 4xBit[1:0]:Reserved(Hex)Name(Hex)R/W Description6A AWBCtrl211RW AWB Control 26B AWBCtrl3A2RW AWB Control 3Bit[7]:AWB mode select0:Advanced AWB1:Simple AWB6C AWBCtrl401RW AWB Control 46D AWBCtrl550RW AWB Control 56E AWBCtrl680RW AWB Control 66F AWBCtrl780RW AWB Control 770AWBCtrl80F RW AWB Control 871AWBCtrl900RW AWB Control 972AWBCtrl1000RW AWB Control 1073AWBCtrl110F RW AWB Control 1174AWBCtrl120F RW AWB Control 1275AWBCtrl13FF RW AWB Control 1376AWBCtrl14FF RW AWB Control 1477AWBCtrl15FF RW AWB Control 1578AWBCtrl1610RW AWB Control 1679AWBCtrl1770RW AWB Control 177A AWBCtrl1870RW AWB Control 187B AWBCtrl19F0RW AWB R Gain Range7C AWBCtrl20F0RW AWB G Gain Range7D AWBCtrl21F0RW AWB B Gain Range7E GAM10E RW Gamma Curve 1st Segment Input End Point 0x04 Output Value 7F GAM21A RW Gamma Curve 2nd Segment Input End Point 0x08 Output Value 80GAM331RW Gamma Curve 3rd Segment Input End Point 0x10 Output Value 81GAM45A RW Gamma Curve 4th Segment Input End Point 0x20 Output Value 82GAM569RW Gamma Curve 5th Segment Input End Point 0x28 Output Value 83GAM675RW Gamma Curve 6th Segment Input End Point 0x30 Output Value 84GAM77E RW Gamma Curve 7th Segment Input End Point 0x38 Output Value 85GAM888RW Gamma Curve 8th Segment Input End Point 0x40 Output Value 86GAM98F RW Gamma Curve 9th Segment Input End Point 0x48 Output Value 87GAM1096RW Gamma Curve 10th Segment Input End Point 0x50 Output Value (Hex)Name(Hex)R/W DescriptionRegister SetVersion 1.1, March 30, 2007Proprietary to OmniVision Technologies, Inc.21O88GAM11A3RW Gamma Curve 11th Segment Input End Point 0x60 Output Value 89GAM12AF RW Gamma Curve 12th Segment Input End Point 0x70 Output Value 8A GAM13C4RW Gamma Curve 13th Segment Input End Point 0x90 Output Value 8B GAM14D7RW Gamma Curve 14th Segment Input End Point 0xB0 Output Value 8C GAM15E8RW Gamma Curve 15th Segment Input End Point 0xD0 Output Value 8D SLOP 20RW Gamma Curve Highest Segment Slope - calculated as follows:SLOP[7:0] = (0x100 - GAM15[7:0]) 4/38EDNSTh00RWDe-noise Threshold8F EDGE000RWSharpness (Edge Enhancement) Control 0Bit[7:5]:ReservedBit[4:0]:Sharpness (edge enhancement) strength control90EDGE108RWSharpness (Edge Enhancement) Control 1Bit[7:4]:ReservedBit[3:0]:Sharpness (edge enhancement) threshold detection91DNSOff 10RW Auto De-noise Threshold Control92EDGE21F RW Sharpness (Edge Enhancement) Strength Upper Limit 93EDGE301RW Sharpness (Edge Enhancement) Strength Lower Limit 94MTX12C RW Matrix Coefficient 195MTX224RW Matrix Coefficient 296MTX308RW Matrix Coefficient 397MTX414RW Matrix Coefficient 498MTX524RW Matrix Coefficient 599MTX638RWMatrix Coefficient 69A MTX_Ctrl 9E RWMatrix ControlBit[7]:Matrix double ON/OFF selection Bit[6]:ReservedBit[5]:Sign bit for MTX6Bit[4]:Sign bit for MTX5Bit[3]:Sign bit for MTX4Bit[2]:Sign bit for MTX3Bit[1]:Sign bit for MTX2Bit[0]:Sign bit for MTX19B BRIGHT 00RW Brightness Control 9C CNST 40RW Contrast Gain Gain 0x209DRSVDXX–ReservedTable 6Device Control Register List (Sheet 11 of 13)Address (Hex)Register Name Default (Hex)R/W DescriptionOV7725Color CMOS VGA OmniPixel2™C AMERA C HIP™ Sensor O9E UVADJ011RW Auto UV Adjust Control 0Bit[7:4]:Auto UV adjust offset control 4 LSBs Bit[3:0]:Auto UV adjust threshold control9F UVADJ102RW Auto UV Adjust Control 1Bit[7:3]:Auto UV adjust valueBit[2]:ReservedBit[1]:Auto UV adjust stop controlBit[0]:Auto UV adjust offset control MSBA0SCAL000RW DCW Ratio ControlBit[7:4]:ReservedBit[3:2]:Vertical down sampling select00:Bypass01:1/2 vertical down sampling10:1/4 vertical down sampling11:1/8 vertical down sampling Bit[1:0]:Horizontal down sampling select00:Bypass01:1/2 horizontal down sampling10:1/4 horizontal down sampling11:1/8 horizontal down samplingA1SCAL140RWHorizontal Zoom Out ControlA2SCAL240RWVertical Zoom Out ControlA3FIFOdlyM06RW FIFO Manual Mode Delay Control A4FIFOdlyA00RW FIFO Auto Mode Delay ControlA5RSVD XX–ReservedA6SDE00RW Special Digital Effect ControlBit[7]:ReservedBit[6]:Negative image enableBit[5]:Gray scale image enableBit[4]:V fixed value enableBit[3]:U fixed value enableBit[2]:Contrast/Brightness enableBit[1]:Saturation enableBit[0]:Hue enableA7USAT40RW U Component Saturation Gain Gain 0x40Table 6 Device Control Register List (Sheet 12 of 13)Address (Hex)RegisterNameDefault(Hex)R/W DescriptionHorizontal zoom ratio =0x40SCAL1[7:0]Vertical zoom ratio =0x40SCAL2[7:0]22Proprietary to OmniVision Technologies, Inc.Version 1.1, March 30, 2007Register SetVersion 1.1, March 30, 2007Proprietary to OmniVision Technologies, Inc.23OA8VSAT 40RW V Component Saturation Gain Gain 0x40A9HUECOS 80RW Cosine value 0x80AAHUESIN80RWSine value 0x80AB SIGN 06RWSign Bit for Hue and BrightnessBit[7:4]:ReservedBit[3]:Brightness sign bit Bit[2]:ReservedBit[1]:Sign bit for HueSin (in Cr’ equation)Bit[0]:Sign bit for HueSin (in Cb’ equation)AC DSPAuto FF RWDSP Auto Function ON/OFF ControlBit[7]:AWB auto threshold control Bit[6]:De-noise auto threshold controlBit[5]:Sharpness (edge enhancement) auto strength control Bit[4]:UV adjust auto slope controlBit[3]:Auto scaling factor control (register SCAL0 (0xA0))Bit[2]:Auto scaling factor control (registers SCAL1 (0xA1 and SCAL2 (0xA2))Bit[1:0]:ReservedNOTE: All other registers are factory-reserved. Please contact OmniVision Technologies for reference register settings.Table 6Device Control Register List (Sheet 13 of 13)Address (Hex)Register Name Default (Hex)R/W DescriptionOV7725Color CMOS VGA OmniPixel2™C AMERA C HIP™ Sensor OPackage Specifications The OV7725 uses a 28-ball Chip Scale Package 2 (CSP2). Refer to Figure12 for package information, Table7 for package dimensions and Figure13 for the array center on the chip.Figure 12OV7725-CSP2 Package SpecificationsNote:For OVT devices that are lead-free, all part marking letters are lower case. Underlining the last digit of the lot number indicatesCSP2 is used.24Proprietary to OmniVision Technologies, Inc.Version 1.1, March 30, 2007。

iPhone15系列传感器尺寸终于确认_iPhone15系列iPhone15系列传感器尺寸终于确认，1/1.3英寸，与去年同款iPhone15和iPhone15 Plus的这两个版本，传感器的像素会升级到4800万，相比前代而言有了不少提升。

而且iPhone15和iPhone15 Plus版本相比之前的1200万像素来说，这次的提升还是蛮大的。

在过去的iPhone系列产品中，标准版和Pro版本的摄像头传感器区别不是很大，甚至可能采取一样的配置，只是风格上会有比较明显的不同。

苹果手机的拍摄方面其实很出色，相比国内手机来说可能只是差一个非常好用方便的拍照滤镜，其他都好说。

看到这个参数相信大家也想起了苹果去年推出的iPhone14系列，没错，iPhone15 Pro和iPhone15 Pro Max这次用的1/1.3英寸传感器就是和iPhone14 Pro和iPhone14 Pro Max是一样的，而且像素还是4800万。

由此可见苹果真的在憋iPhone16系列的大招。

但根据苹果手机影像系统的能力，其实是否一英寸大底传感器不是那么致命，对于实际拍摄来说对画面的影响远没有想象中的大，大家还是可以放心。

苹果手机的拍照主打一个真实感，画面永远是清晰感人的。

Pro版本将配置潜望式长焦摄像头，要说长焦摄像头的话拿来拍月亮是检验实力的唯一标准，想必到时候又会有许多的月亮返图。

iPhone15系列8月将量产据外媒7月7日报道，海通国际科技研究中心的分析师Jeff Pu 日前预计，iPhone 15系列将于今年8月进入量产阶段，今年下半年产量有望达到8400万部，相比去年的iPhone 14系列增长了12%。

不过，Jeff Pu也警告称，iPhone 15 Pro Max的售价可能会高于iPhone 14 Pro Max的1099美元起步价，并且iPhone 15 Pro Max将拥有iPhone 15 Pro 机型上没有的独家功能。