SSB1205680MZF中文资料

12-Bit RDCwith Reference OscillatorAD2S1205 Rev. AInformation furnished by Analog Devices is believed to be accurate and reliable. However, noresponsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. T rademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, M A 02062-9106, U.S.A. Tel: 781.329.4700 Fax: 781.461.3113 ©2007–2010 Analog Devices, Inc. All rights reserved.FEATURESComplete monolithic resolver-to-digital converter (RDC) Parallel and serial 12-bit data portsSystem fault detection±11 arc minutes of accuracyInput signal range: 3.15 V p-p ± 27%Absolute position and velocity outputs1250 rps maximum tracking rate, 12-bit resolution Incremental encoder emulation (1024 pulses/rev) Programmable sinusoidal oscillator on boardSingle-supply operation (5.00 V ± 5%)−40°C to +125°C temperature rating44-lead LQFP4 kV ESD protectionQualified for automotive applications APPLICATIONSAutomotive motion sensing and controlHybrid-electric vehiclesElectric power steeringIntegrated starter generator/alternatorIndustrial motor controlProcess control FUNCTIONAL BLOCK DIAGRAMFigure 1.GENERAL DESCRIPTIONThe AD2S1205 is a complete 12-bit resolution tracking resolver-to-digital converter that contains an on-board programmable sinusoidal oscillator providing sine wave excitation for resolvers.The converter accepts 3.15 V p-p ± 27% input signals on the Sin and Cos inputs. A Type II tracking loop is employed to track the inputs and convert the input Sin and Cos information into a digital representation of the input angle and velocity. The maximum tracking rate is a function of the external clock frequency. The performance of the AD2S105 is specified across a frequency range of 8.192 MHz ± 25%, allowing a maximum tracking rate of 1250 rps. PRODUCT HIGHLIGHTS1.Ratiometric Tracking Conversion. The Type II trackingloop provides continuous output position data withoutconversion delay. It also provides noise immunity andtolerance of harmonic distortion on the reference andinput signals.2.System Fault Detection. A fault detection circuit can senseloss of resolver signals, out-of-range input signals, inputsignal mismatch, or loss of position tracking.3.Input Signal Range. The Sin and Cos inputs can acceptdifferential input voltages of 3.15 V p-p ± 27%.4.Programmable Excitation Frequency. Excitation frequencyis easily programmable to 10 kHz, 12 kHz, 15 kHz, or 20 kHz by using the frequency select pins (the FS1 and FS2 pins).5.Triple Format Position Data. Absolute 12-bit angular positiondata is accessed via either a 12-bit parallel port or a 3-wire serial interface. Incremental encoder emulation is in standard A-quad-B format with direction output available.6.Digital Velocity Output. 12-bit signed digital velocity accessedvia either a 12-bit parallel port or a 3-wire serial interface.AD2S1205Rev. A | Page 2 of 20TABLE OF CONTENTSFeatures .............................................................................................. 1 Applications ....................................................................................... 1 Functional Block Diagram .............................................................. 1 General Description ......................................................................... 1 Product Highlights ........................................................................... 1 Revision History ............................................................................... 2 Specifications ..................................................................................... 3 Absolute Maximum Ratings ............................................................ 5 ESD Caution .................................................................................. 5 Pin Configuration and Function Descriptions ............................. 6 Resolver Format Signals ................................................................... 8 Theory of Operation ........................................................................ 9 Fault Detection Circuit ................................................................ 9 Monitor Signal .............................................................................. 9 Loss of Signal Detection .............................................................. 9 Signal Degradation Detection .................................................. 10 Loss of Position Tracking Detection ........................................ 10 Responding to a Fault Condition ............................................. 10 False Null Condition .................................................................. 10 On-Board Programmable Sinusoidal Oscillator .................... 11 Synthetic Reference Generation ............................................... 11 Charge-Pump Output ................................................................ 11 Connecting the Converter ........................................................ 11 Clock Requirements ................................................................... 12 Absolute Position and Velocity Output ................................... 12 Parallel Interface ......................................................................... 12 Serial Interface ............................................................................ 14 Incremental Encoder Outputs .................................................. 16 Supply Sequencing and Reset ................................................... 16 Circuit Dynamics ........................................................................... 17 Loop Response Model ............................................................... 17 Sources of Error .......................................................................... 18 Connecting to the DSP .............................................................. 19 Outline Dimensions ....................................................................... 20 Ordering Guide .......................................................................... 20 Automotive Products .. (20)REVISION HISTORY5/10—Rev. 0 to Rev. AChanges to Features Section............................................................ 1 Changes to Input Bias Current Parameter and InputImpedance Parameter ...................................................................... 3 Changes to Table 2 ............................................................................ 5 Changes to Loss of Signal Detection Section ................................ 9 Changes to Connecting the Converter Section and Figure 5 ... 11 Change to t 6 Max Value in Table 6 ............................................... 13 Changes to t 9 and t 10 Max Values Table 7 .................................... 15 Changes to Ordering Guide .......................................................... 20 Added Automotive Products Section .......................................... 20 1/07—Revision 0: Initial VersionAD2S1205SPECIFICATIONSAV DD = DV DD = 5.0 V ± 5% at −40°C to +125°C, CLKIN = 8.192 MHz ± 25%, unless otherwise noted.Rev. A | Page 3 of 20AD2S12051 The voltages for Sin, SinLO, Cos, and CosLO relative to AGND must be between 0.2 V and AV DD.Rev. A | Page 4 of 20AD2S1205Rev. A | Page 5 of 20ABSOLUTE MAXIMUM RATINGSTable 2.Parameter RatingSupply Voltage (V DD ) −0.3 V to +7.0 VSupply Voltage (AV DD ) −0.3 V to +7.0 VInput Voltage −0.3 V to V DD + 0.3 VOutput Voltage Swing −0.3 V to V DD + 0.3 VInput Current to Any Pin Except Supplies 1 ±10 mAOperating Temperature Range (Ambient) −40°C to +125°C Storage Temperature Range −65°C to +150°C1Transient currents of up to 100 mA do not cause latch-up.Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stressrating only; functional operation of the device at these or anyother conditions above those indicated in the operationalsection of this specification is not implied. Exposure to absolutemaximum rating conditions for extended periods may affectdevice reliability. ESD CAUTIONAD2S1205Rev. A | Page 6 of 2006339-002PIN CONFIGURATION AND FUNCTION DESCRIPTIONSR E F O U T44R E F B Y P43C o s L O40S i n L O38A G N D42A G N D36A V D D39E X C35E X C34C o s41S i n37DV DD 1RD 2CS 3SAMPLE4RDVEL 5SOE 6DB11/SO 7DB10/SCLK8DB99DB810DB71133FS232FS131LOT 30DOS 29AD2S1205TOP VIEW (Not to Scale)DIR 28NM 27B 26A 25CPO 24DGND23DB 612D B 513D B 414D B 315D G N D16D V D D17D B 218D B 119D B 020X T A L O U T21C L K I N22Figure 2. Pin ConfigurationAD2S1205Rev. A | Page 7 of 20AD2S1205Rev. A | Page 8 of 20RESOLVER FORMAT SIGNALS06339-003V b = V s × Sin(ωt) × Sin(θ)(A) CLASSICAL RESOLVERs × Sin(ωt) × Cos(θ)V b = V s × Sin(ωt) × Sin(θ)(B)VARIABLE RELUCTANCE RESOLVERs × Sin(ωt) × Cos(θ)Figure 3. Classical Resolver vs. Variable Reluctance ResolverA classical resolver is a rotating transformer that typically has a primary winding on the rotor and two secondary windings on the stator. A variable reluctance resolver, on the other hand, has the primary and secondary windings on the stator and no windings on the rotor, as shown in Figure 3; however, the saliency in this rotor design provides the sinusoidal variation in the secondary coupling with the angular position. For both designs, the resolver output voltages (S3 − S1, S2 − S4) are as follows:Sinθt Sin E S1S30×ω=−)( (1)Cosθt Sin E S4S20×ω=−)(where:θ is the shaft angle.Sin(ωt) is the rotor excitation frequency. E 0 is the rotor excitation amplitude.The stator windings are displaced mechanically by 90° (see Figure 3). The primary winding is excited with an ac reference. The amplitude of subsequent coupling onto the secondary windings is a function of the position of the rotor (shaft) relative to the stator. The resolver therefore produces two output voltages (S3 − S1, S2 − S4), modulated by the sine and cosine of the shaft angle. Resolver format signals refer to the signals derived from the output of a resolver, as shown in Equation 1. Figure 4 illustrates the output format. 06339-0040°R2 – R4(REFERENCE)90°180°θ270°360°Figure 4. Electrical Resolver RepresentationAD2S1205Rev. A | Page 9 of 20THEORY OF OPERATIONThe AD2S1205’s operation is based on a Type II tracking closed-loop principle. The digitally implemented tracking loop continually tracks the position and velocity of the resolver without the need for external convert and wait states. As the resolver moves through a position equivalent to the least significant bit weighting, the tracking loop output is updated by 1 LSB.The converter tracks the shaft angle (θ) by producing an output angle (ϕ) that is fed back and compared with the input angle (θ); the difference between the two angles is the error, which is driven towards 0 when the converter is correctly tracking the input angle. T o measure the error, S3 − S1 is multiplied by Cosϕ and S2 − S4 is multiplied by Sinϕ to giveS4 S2for )(S1S3for )(00−×−×SinφCosθωt Sin E CosφSinθωt Sin E (2)The difference is taken, giving)()(0SinφCosθCos Sinθωt Sin E −φ× (3)This signal is demodulated using the internally generated synthetic reference, yielding)(0φ−φSin CosθCos SinθE (4)Equation 4 is equivalent to E 0Sin (θ − ϕ), which is approximately equal to E 0(θ − ϕ) for small values of θ − ϕ, where θ − ϕ is the angular error. The value E 0(θ − ϕ) is the difference between the angular error of the rotor and the digital angle output of the converter. A phase-sensitive demodulator, some integrators, and a compen-sation filter form a closed-loop system that seeks to null the error signal. If this is accomplished, ϕ equals the resolver angle, θ, within the rated accuracy of the converter. A Type II tracking loop is used so that constant velocity inputs can be tracked without inherent error.For more information about the operation of the converter, see the Circuit Dynamics section.FAULT DETECTION CIRCUITThe AD2S1205 fault detection circuit can sense loss of resolver signals, out-of-range input signals, input signal mismatch, or loss of position tracking; however, the position indicated by the AD2S1205 may differ significantly from the actual shaft position of the resolver.MONITOR SIGNALThe AD2S1205 generates a monitor signal by comparing the angle in the position register to the incoming Sin and Cos signals from the resolver. The monitor signal is created in a similar fashion to the error signal (described in the Theory of Operation section). The incoming Sinθ and Cosθ signals are multiplied by the Sin and Cos of the output angle, respectively, and then these values are added together:)()(CosφCosθA2SinφSinθA1Monitor ××+××= (5)where:A1 is the amplitude of the incoming Sin signal (A1 × Sinθ). A2 is the amplitude of the incoming Cos signal (A2 × Cosθ).θ is the resolver angle.ϕ is the angle stored in the position register.Note that Equation 5 is shown after demodulation with thecarrier signal Sin(ωt) removed. Also note that for a matchedinput signal (that is, a no fault condition), A1 is equal to A2.When A1 is equal to A2 and the converter is tracking (therefore, θ is equal to ϕ), the monitor signal output has aconstant magnitude of A1 (Monitor = A1 × (Sin 2θ + Cos 2θ) = A1), which is independent of the shaft angle. When A1 does notequal A2, the monitor signal magnitude alternates between A1 and A2 at twice the rate of the shaft rotation. The monitor signal is used to detect degradation or loss of input signals. LOSS OF SIGNAL DETECTIONLoss of signal (LOS) is detected when either resolver input (Sin or Cos) falls below the specified LOS Sin/Cos threshold. The AD2S1205 detects this by comparing the monitor signal to a fixed minimum value. Without the use of external circuitry, the AD2S1205 can detect the loss of up to three of the four connections from the resolver. The addition of two external 68 kΩ resistors, as outlined in Figure 5, ensures that the loss of all 4 connections, that is, complete removal of the resolver, may also be detected. LOS is indicated by both DOS and LOT latching as logic low outputs. The DOS and LOT pins are reset to the no fault state by a rising edge of SAMPLE . The LOS condition has priority over both the DOS and LOT conditions, as shown in . LOS is indicated within 57° of the angular output error (worst case).Table 4AD2S1205Rev. A | Page 10 of 20SIGNAL DEGRADATION DETECTIONDegradation of signal (DOS) is detected when either resolver input (Sin or Cos) exceeds the specified DOS Sin/Cos threshold. The AD2S1205 detects this by comparing the monitor signal to a fixed maximum value. In addition, DOS is detected when the amplitudes of the Sin and Cos input signals are mismatched by more than the specified DOS Sin/Cos mismatch. This is identified because the AD2S1205 continuously stores the minimum and maximum magnitude of the monitor signal in internal registers and calculates the difference between these values. DOS is indicated by a logic low on the DOS pin and is not latched when the input signals exceed the maximum input level. When DOS is indicated due to mismatched signals, the output is latched low until a rising edge of SAMPLE resets the stored minimum and maximum values. The DOS condition has priority over the LOT condition, as shown in . DOS is indicated within 33° of the angular output error (worst case).Table 4LOSS OF POSITION TRACKING DETECTIONLoss of tracking (LOT) is detected when • The internal error signal of the AD2S1205 exceeds 5°. • The input signal exceeds the maximum tracking rate. •The internal position (at the position integrator) differs from the external position (at the position register) by more than 5°.LOT is indicated by a logic low on the LOT pin and is not latched. LOT has a 4° hysteresis and is not cleared until the internal error signal or internal/external position mismatch is less than 1°. When the maximum tracking rate is exceeded, LOT is cleared only if the velocity is less than the maximum tracking rate and the internal/external position mismatch is less than 1°. LOT can be indicated for step changes in position (such as after a RESET signal is applied to the AD2S1205), or for accelerations of >~65,000 rps 2. It is also useful as a built-in test to indicate that the tracking converter is functioningproperly. The LOT condition has lower priority than both the DOS and LOS conditions, as shown in . The LOT and DOS conditions cannot be indicated at the same time. Table 4Table 4. Fault Detection DecodingConditionDOS Pin LOT Pin Order of Priority Loss of Signal (LOS)0 0 1 Degradation of Signal (DOS) 0 1 2 Loss of Tracking (LOT) 1 0 3 No Fault1 1RESPONDING TO A FAULT CONDITIONIf a fault condition (LOS, DOS, or LOT) is indicated by the AD2S1205, the output data is presumed to be invalid. Even if a RESET or SAMPLE pulse releases the fault condition and is not immediately followed by another fault, the output data may be corrupted. As discussed previously, there are some fault conditions with inherent latency. If the device fault is cleared, there may be some latency in the resolver’s mechanical position before the fault condition is reindicated.When a fault is indicated, all output pins still provide data, although the data may or may not be valid. The fault condition does not force the parallel, serial, or encoder outputs to a known state. Response to specific fault conditions is a system-level requirement. The fault outputs of the AD2S1205 indicate that the device has sensed a potential problem with either the internal or external signals of the AD2S1205. It is the responsibility of the system designer to implement the appropriate fault-handling schemes within the control hardware and/or algorithm of a given appli-cation based on the indicated fault(s) and the velocity or position data provided by the AD2S1205.FALSE NULL CONDITIONResolver-to-digital converters that employ Type II tracking loops based on the previously stated error equation (see Equation 4 in the Theory of Operation section) can suffer from a condition known as a false null. This condition is caused by a metastable solution to the error equation when θ − ϕ = 180°. The AD2S1205 is not susceptible to this condition because its hysteresis is implemented external to the tracking loop. As a result of the loop architecture chosen for the AD2S1205, the internal error signal constantly has some movement (1 LSB per clock cycle); therefore, in a metastable state, the converter moves to anunstable condition within one clock cycle. This causes the tracking loop to respond to the false null condition as if it were a 180° step change in input position (the response time is the same, as specified in the Dynamic Performance section of Table 1). Therefore, it is impossible to enter the metastable condition after the start-up sequence if the resolver signals are valid.分销商库存信息:ANALOG-DEVICESAD2S1205WSTZ AD2S1205YSTZ ADW71205WSTZ-RL ADW71205WSTZ ADW71205YSTZ EVAL-AD2S1205SDZ。

一般用途铁素体和马氏体不锈钢无缝和焊接钢管1.范围1.1本标准适用于许多牌号的耐一般腐蚀和高温用的公称壁厚不锈钢钢管。

其中大部份牌号通常称为“纯铬”型并具有铁磁性特点。

其中两个牌号，即牌号TP410和UNS S41500（表1），适合于通过热处理来硬化，高铬铁素体合金钢在缓慢冷却到常温时对缺口脆性会产生敏感。

在使用这些牌号钢管时，应考虑到这些特点，牌号TP439的钢管主要用于热水箱，不要求焊后热处理来防止热影响区的腐蚀。

1.2 1.2本标准提供选择性补充要求，如需要的话，应在订单中注明。

1.3 用英寸—磅单位或SI(公制)单位表示的数值应分别视为标准值。

在正文中，SI单位用括号表示。

每一种单位制所表示的数值实际上并不相等。

因此，每种单位制必须单独使用。

将两种单位制的数值相混同，就会与ASTM标准不相符合。

如果订单中未规定带“M”标准代号，应按英寸一磅单位供货。

2. 适用文件2.1 ASTM标准A480/A480M不锈钢和耐热钢钢板、薄板和带钢的一般要求A763 铁素体不锈钢晶间腐蚀敏感性的测定方法A 1016/A 1016M 铁素体合金钢管，奥氏体合金钢管和不锈钢管的一般要求E213 金属管的超声波检测方法E273 焊管的纵向超声波检测方法3. 专业术语3.1 批次的定义3.1.1 对于卷边试验和扩口试验，批次是指同一炉钢生产的同一公称尺寸和壁厚的尚未切分的全部钢管。

当最终热处理是在批式炉内进行时，一批应仅包括同一尺寸和同一炉号，同一次装炉热处理的那些钢管。

当最终热处理是在连续式炉内进行时，一批中同一尺寸和同一炉号的钢管根数应按3.1.2 对于拉抻试验和硬度试验来说：批是指用同一炉钢生产的同一公称直径和壁厚的尚未切分的全部钢管，当最终热处理是在批式炉内进行时，一批应仅包括同一尺寸和同一炉号、同一次装炉热处理的那些钢管，当最终热处理是在连续式炉内进行时，一批应包括同一尺寸和同一炉号，在同一座炉内以相同温度、相同加热时间和相同加热速度进行热处理的所有钢管。

资料来源：爱购机目录................................................................................................... 错误！未定义书签。

1 外观描述 (2)2 电源键的用法 (3)3 触摸屏 (4)4转接盒 (4)5 SD卡的使用 (5)6开始使用 (5)给设备充电 (5)启动设备 (5)Wi-Fi 网络设置 (5)7桌面 (5)8锁屏界面 (6)9预装程序 (7)10桌面菜单功能 (8)11 程序管理 (10)安装程序 (10)直接从网络上下载程序 (10)卸载程序 (10)12 天气 (10)13 时钟 (11)闹钟 (11)14在线软件安装 (12)菜单功能 (12)15浏览器 (13)16 日历 (13)新建活动 (13)17 相机 (13)拍摄图片 (13)录制视频 (14)18 计算器 (14)19 电子邮件 (14)添加邮件账户 (14)收件箱 (15)编辑邮件账户 (15)删除邮件账户 (16)20 文件浏览器 (16)在电脑和设备之间拷贝文件 (17)删除文件 (17)21 我的音乐 (17)播放音乐 (17)对音乐盒播放列表进行操作 (18)22 我的视频 (18)播放视频 (18)对视频和播放列表进行操作 (19)23 我的相册 (19)涂鸦 (20)24 通讯录 (20)添加新的联系人 (20)添加联系人到收藏 (20)编辑联系人 (20)删除联系人 (20)25 图片截取 (21)26 程序管理器 (21)停止程序 (21)卸载程序 (21)27 YouTube (21)28 土豆视频 (22)29 Wi-Fi设置 (22)30 3G Settings (22)31 连接ADSL上网 (23)32 有线网络 (23)33 设置 (23)常见问题 (25)电池管理 (26)电池充电 (26)重要安全提示 (26)附录.建议可选配件及型号 (27)1 外观描述前视图：右视图：左视图：顶视图：2 电源键的用法开机: 长按电源键2秒。