MAX6316LUK47AW-T中文资料

FM6316FE1A移动电源专用管理IC一、概述FM6316FE是一款应用于移动电源，集成了锂电池充电管理，DC-DC升压及负载检测功能于一体的便携式电源管理IC。

FM6316FE集成了包括涓流充电，恒流充电和恒压充电全过程的充电方式，并含有充电过程及充电结束状态指示灯；恒流充电电流通过外加电阻编程；系统在充电状态下会关闭输出放电路径；当外部输入电源去掉时，FM6316FE由电池向外部设备供电，若没有检测到外部设备的接入，则系统进入待机状态，整个系统待机电流为16uA。

FM6316FE具有多重保护设计，包括充电时防倒灌保护，软启动保护，过温及欠压保护等。

二、特点Ø外围电路简单；Ø内置充电转灯功能；Ø空载检测关断功能；Ø涓流/恒流/恒压三段式充电；ØIC升压效率高达90%；Ø恒流充电电流值可外部编程；FM6316FE1A移动电源专用管理ICFM6316FE1A移动电源专用管理ICØ正常工作参数（除非特别说明，否则Vcc=5V，VBAT=3.8V，T=25℃）符号参数测试条件最小值典型值最大值单位系统参数VCC 输入电源电压-- 4 5 5.5 V VBAT 电池电压-- 3.2 -- 4.3 V Istandby 待机电流No Vcc，No Load 10 16 30 uA 充电参数Vfloal 稳定输出（浮充）电压25℃≤Ta≤85℃ 4.16 4.20 4.24 V BAT PinCurrentBAT倒灌电流Vcc=3.5V，Vbat=4.2V -- ±0.5 ±5 uA Vtrikl 涓流充电门限电流-- 2.8 2.9 3.0 V Vtrhys 涓流充电迟滞电压-- 60 80 100 mV Vuv Vcc欠压闭锁门限Vcc低至高 3.5 3.7 3.9 V Vuvhys Vcc欠压闭锁迟滞-- 150 200 300 mVVcc低至高60 100 140 mV Vasd Vcc-VBAT闭锁门限电压Vcc高至低 5 30 50 mV △Vrechrg 再充电电池门限电压Vfloal-Vrechrg 100 150 200 mV Ron Vcc与BAT之间-- -- 650 -- mΩ放电参数Vout 升压输出电压 5.05 5 5.15 V Vuvlo 欠压锁定-- -- 2.85 -- V Vuvlo_r 欠压锁定迟滞-- -- 0.1 -- VIbat VFB=0.66V，Noswitching0.1 0.19 0.25 mAIbat_w VFB=0.55V，switching 0.6 0.75 0.85 mA Fosc 振荡频率-- 0.8 1.0 1.2 MHzη转换效率Vbat=3.3~4.3V&Vout=5.2V&Iout=0.1~1A-- 80 90 %Tov 过温保护-- -- 160 -- ℃Tov_r 过温保护恢复-- -- 120 -- ℃FM6316FE1A移动电源专用管理ICFM6316FE1A移动电源专用管理IC 十一、注意事项FM6316FE1A移动电源专用管理IC 2、PCB图2、BOM表FM6316FE1A移动电源专用管理IC19 USB母座贴片USB 14MM PCS 1 J2 USB20 贴片母座全贴片迈克5P,引脚需加长PCS 1 J1 MIC 5P21 贴片电阻BE版本贴27K，CE、FE不贴PCS 1 R*。

_______________General DescriptionThe MAX4545/MAX4546/MAX4547 are low-voltage T-switches designed for switching RF and video signals from DC to 300MHz in 50Ωand 75Ωsystems. The MAX4545 contains four normally open single-pole/single-throw (SPST) switches. The MAX4546 contains two dual SPST switches (one normally open, one normally closed.)The MAX4547 contains two single-pole/double-throw (SPDT) switches.Each switch is constructed in a “T” configuration, ensuring excellent high-frequency off isolation and crosstalk of -80dB at 10MHz. They can handle Rail-to-Rail ®analog sig-nals in either direction. On-resistance (20Ωmax) is matched between switches to 1Ωmax and is flat (0.5Ωmax) over the specified signal range, using ±5V supplies.The off leakage current is less than 5nA at +25°C and 50nA at +85°C.These CMOS switches can operate with dual power sup-plies ranging from ±2.7V to ±6V or a single supply between +2.7V and +12V. All digital inputs have 0.8V/2.4V logic thresholds, ensuring both TTL- and CMOS-logic com-patibility when using ±5V or a single +5V supply.________________________ApplicationsRF SwitchingVideo Signal RoutingHigh-Speed Data Acquisition Test Equipment ATE Equipment Networking____________________________Featureso Low 50ΩInsertion Loss: -1dB at 100MHz o High 50ΩOff Isolation: -80dB at 10MHz o Low 50ΩCrosstalk: -80dB at 10MHz o DC to 300MHz -3dB Signal Bandwidth o 20ΩSignal Paths with ±5V Supplies o 1ΩSignal-Path Matching with ±5V Supplies o 0.5ΩSignal-Path Flatness with ±5V Supplies o ±2.7V to ±6V Dual Supplies +2.7V to +12V Single Supply o Low Power Consumption: <1µW o Rail-to-Rail Bidirectional Signal Handling o Pin Compatible with Industry-Standard DG540, DG542, DG643o >2kV ESD Protection per Method 3015.7o TTL/CMOS-Compatible Inputs with Single +5V or ±5VMAX4545/MAX4546/MAX4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches________________________________________________________________Maxim Integrated Products1_____________________Pin Configurations/Functional Diagrams/Truth Tables19-1232; Rev 0; 6/97Ordering Information continued at end of data sheet.For free samples & the latest literature: , or phone 1-800-998-8800Rail-to-Rail is a registered trademark of Nippon Motorola Ltd.M A X 4545/M A X 4546/M A X 4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS—Dual Supplies(V+ = +4.5V to +5.5V, V- = -4.5V to -5.5V, V INL = 0.8V, V INH = 2.4V, V GND_= 0V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.(Voltages Referenced to GND)V+...........................................................................-0.3V, +13.0V V-............................................................................-13.0V, +0.3V V+ to V-...................................................................-0.3V, +13.0V All Other Pins (Note 1)..........................(V- - 0.3V) to (V+ + 0.3V)Continuous Current into Any Terminal..............................±25mA Peak Current into Any Terminal(pulsed at 1ms, 10% duty cycle)..................................±50mA ESD per Method 3015.7..................................................>2000V Continuous Power Dissipation (T A = +70°C) (Note 2)16-Pin Plastic DIP(derate 10.53mW/°C above +70°C)..........................842mW16-Pin Narrow SO(derate 8.70mW/°C above +70°C)............................696mW 16-Pin QSOP (derate 8.3mW/°C above +70°C)..........667mW 20-Pin Plastic DIP (derate 8.0mW/°C above +70°C)...640mW 20-Pin Wide SO (derate 10.00mW/°C above +70°C)..800mW 20-Pin SSOP (derate 8.0mW/°C above +70°C)..........640mW Operating Temperature RangesMAX454_C_ E.....................................................0°C to +70°C MAX454_E_ E..................................................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10sec).............................+300°CNote 1:Voltages on all other pins exceeding V+ or V- are clamped by internal diodes. Limit forward diode current to maximum cur-rent rating.MAX4545/MAX4546/MAX4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS—Dual Supplies (continued)(V+ = +4.5V to +5.5V, V- = -4.5V to -5.5V, V INL = 0.8V, V INH = 2.4V, V GND_= 0V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)M A X 4545/M A X 4546/M A X 4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches 4_______________________________________________________________________________________ELECTRICAL CHARACTERISTICS—Single +5V Supply(V+ = +4.5V to +5.5V, V- = 0V, V INL = 0.8V, V INH = 2.4V, V GND_= 0V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)MAX4545/MAX4546/MAX4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches_______________________________________________________________________________________5ELECTRICAL CHARACTERISTICS—Single +3V Supply(V+ = +2.7V to +3.6V, V- = 0V, V INL = 0.8V, V INH = 2.4V, V GND_ = 0V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)Note 2:The algebraic convention is used in this data sheet; the most negative value is shown in the minimum column.Note 3:Guaranteed by design.Note 4:∆R ON = ∆R ON(MAX)- ∆R ON(MIN).Note 5:Resistance flatness is defined as the difference between the maximum and the minimum value of on-resistance as mea-sured over the specified analog signal range.Note 6:Leakage parameters are 100% tested at the maximum rated hot temperature and guaranteed by correlation at +25°C.Note 7:Off isolation = 20log 10[V COM / (V NC or V NO )], V COM = output, V NC or V NO = input to off switch.Note 8:Between any two switches.Note 9:Leakage testing for single-supply operation is guaranteed by testing with dual supplies.M A X 4545/M A X 4546/M A X 4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches 6_________________________________________________________________________________________________________________________________Typical Operating Characteristics(V+ = +5V, V- = -5V, T A = +25°C, GND = 0V, packages are surface mount, unless otherwise noted.)10010-51234-4-3-2-15ON-RESISTANCE vs. V COM(DUAL SUPPLIES)V COM (V)R O N (Ω)5111315971723192125-5-3-2-4-1012345ON-RESISTANCE vs. V COM AND TEMPERATURE (DUAL SUPPLIES)V COM (V)R O N (Ω)10001010012345678910ON-RESISTANCE vs. V COM(SINGLE SUPPLY)V COM (V)R O N (Ω)102025153040354501.0 1.50.52.0 2.53.0 3.54.0 4.55.0ON-RESISTANCE vs. V COM AND TEMPERATURE (SINGLE SUPPLY)V COM (V)R O N (Ω)050100150200250±2±3±4±5±6±8ON/OFF TIME vs.SUPPLY VOLTAGEM A X 4545 T O C 07V+, V- (V)t O N , t O F F (n s )t ONt OFF0.00010.0010.010.1110-75-50-25257550100125ON/OFF-LEAKAGE CURRENT vs.TEMPERATURETEMPERATURE (°C)L E A K A G E (n A)-20204006010080120-5-3-2-4-1012345CHARGE INJECTION vs. V COMV COM (V)Q j (p C )103050709011020406080100-75-2575125-502550100ON/OFF TIME vs.TEMPERATUREM A X 4545 T O C 08TEMPERATURE (°C)t O N , t O F F (n s )t ONt OFF0.000010.00010.001I-I+0.010.11-75-2575125-502550100POWER-SUPPLY CURRENT vs. TEMPERATUREM A X 4545 T O C 09TEMPERATURE (°C)I +, I - (µA )MAX4545/MAX4546/MAX4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches_______________________________________________________________________________________70.40.20.61.21.41.00.81.601.0 1.52.0 2.50.53.0 3.54.0 4.55.0LOGIC-LEVEL THRESHOLD vs. POSITIVE SUPPLY VOLTAGEM A X 4545 T O C 10V+ (V)L O G I C -L E V E L T H R E S H O L D (V )-1200.11010001001MAX4545FREQUENCY RESPONSE-100-110FREQUENCY (MHz)L O S S (d B )-80-90-60-50-70-40-20-10-30-1001101001000MAX4546FREQUENCY RESPONSE-60-70-80-90-30-40-50-20-10FREQUENCY (MHz)L O S S (d B )100-20-10-1001101000FREQUENCY RESPONSE-70-80-90-30-40-50-601006080-100-40-60-8040200-20FREQUENCY (MHz)S W I T C H L O S S (d B )O N P H A S E (D E G R E E S )1001000.0001101k 100k10k100MAX4547TOTAL HARMONIC DISTORTIONvs. FREQUENCY0.001FREQUENCY (Hz)T H D (%)0.010.1110____________________________Typical Operating Characteristics (continued)(V+ = +5V, V- = -5V, T A = +25°C, GND = 0V, packages are surface mount, unless otherwise noted.)_______________Theory of OperationLogic-Level TranslatorsThe MAX4545/MAX4546/MAX4547 are constructed as high-frequency “T” switches, as shown in Figure 1. The logic-level input, IN_, is translated by amplifier A1 into a V+ to V- logic signal that drives amplifier A2. (Amplifier A2 is an inverter for normally closed switches.)Amplifier A2 drives the gates of N-channel MOSFETs N1 and N2 from V+ to V-, turning them fully on or off.The same signal drives inverter A3 (which drives the P-channel MOSFETs P1 and P2) from V+ to V-, turning them fully on or off, and drives the N-channel MOSFET N3 off and on.The logic-level threshold is determined by V+ and GND_. The voltage on GND_ is usually at ground potential, but it may be set to any voltage between (V+ - 2V) and V-. When the voltage between V+ and GND_ is less than 2V, the level translators become very slow and unreliable. Since individual switches in each package have individual GND_ pins, they may be set to different voltages. Normally, however, they should all be connected to the ground plane.Switch On ConditionWhen the switch is on, MOSFETs N1, N2, P1, and P2are on and MOSFET N3 is off. The signal path is COM_to NO_, and because both N-channel and P-channel MOSFETs act as pure resistances, it is symmetrical(i.e., signals may pass in either direction). The off MOSFET, N3, has no DC conduction, but has a small amount of capacitance to GND_. The four on MOSFETs also have capacitance to ground that,together with the series resistance, forms a lowpass fil-ter. All of these capacitances are distributed evenly along the series resistance, so they act as a transmis-sion line rather than a simple R-C filter. This helps to explain the exceptional 300MHz bandwidth when the switches are on.M A X 4545/M A X 4546/M A X 4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches 8_____________________________________________________________________________________________________________________________________________________Pin Description*All pins have ESD diodes to V- and V+.**NO_ (or NC_) and COM_ pins are identical and interchangeable. Either may be considered as an input or output; signals passequally well in either direction.Figure 1. T-Switch ConstructionTypical attenuation in 50Ωsystems is -1dB and is rea-sonably flat up to 100MHz. Higher-impedance circuits show even lower attenuation (and vice versa), but slightly lower bandwidth due to the increased effect of the internal and external capacitance and the switch’s internal resistance.The MAX4545/MAX4546/MAX4547 are optimized for ±5V operation. Using lower supply voltages or a single supply increases switching time, increases on-resis-tance (and therefore on-state attenuation), and increas-es nonlinearity.Switch Off Condition When the switch is off, MOSFETs N1, N2, P1, and P2 are off and MOSFET N3 is on. The signal path is through the off-capacitances of the series MOSFETs, but it is shunted to ground by N3. This forms a high-pass filter whose exact characteristics are dependent on the source and load impedances. In 50Ωsystems, and below 10MHz, the attenuation can exceed 80dB. This value decreases with increasing frequency and increasing circuit impedances. External capacitance and board layout have a major role in determining over-all performance.__________Applications InformationPower-Supply ConsiderationsOverview The MAX4545/MAX4546/MAX4547 construction is typi-cal of most CMOS analog switches. It has three supply pins: V+, V-, and GND. V+ and V- are used to drive the internal CMOS switches and set the limits of the analog voltage on any switch. Reverse ESD protection diodes are internally connected between each analog signal pin and both V+ and V-. If the voltage on any pin exceeds V+ or V-, one of these diodes will conduct. During normal operation these reverse-biased ESD diodes leak, forming the only current drawn from V-. Virtually all the analog leakage current is through the ESD diodes. Although the ESD diodes on a given sig-nal pin are identical, and therefore fairly well balanced, they are reverse biased differently. Each is biased by either V+ or V- and the analog signal. This means their leakages vary as the signal varies. The difference in the two diode leakages from the signal path to the V+ and V- pins constitutes the analog signal-path leakage cur-rent. All analog leakage current flows to the supply ter-minals, not to the other switch terminal. This explains how both sides of a given switch can show leakage currents of either the same or opposite polarity.There is no connection between the analog signal paths and GND. The analog signal paths consist of an N-channel and P-channel MOSFET with their sources and drains paralleled and their gates driven out of phase with V+ and V- by the logic-level translators.V+ and GND power the internal logic and logic-level translators, and set the input logic thresholds. The logic-level translators convert the logic levels to switched V+ and V- signals to drive the gates of the analog switches. This drive signal is the only connec-tion between the logic supplies and the analog sup-plies. All pins have ESD protection to V+ and to V-. Increasing V- has no effect on the logic-level thresh-olds, but it does increase the drive to the P-channel switches, reducing their on-resistance. V- also sets the negative limit of the analog signal voltage.The logic-level thresholds are CMOS and TTL compati-ble when V+ is +5V. As V+ is raised, the threshold increases slightly; when V+ reaches +12V, the level threshold is about 3.1V, which is above the TTL output high-level minimum of 2.8V, but still compatible with CMOS outputs.Bipolar-Supply Operation The MAX4545/MAX4546/MAX4547 operate with bipolar supplies between ±2.7V and ±6V. The V+ and V- sup-plies need not be symmetrical, but their sum cannot exceed the absolute maximum rating of 13.0V. Do not connect the MAX4545/MAX4546/MAX4547 V+ pin to +3V and connect the logic-level input pins to TTL logic-level signals. TTL logic-level outputs can exceed the absolute maximum ratings, causing damage to the part and/or external circuits.CAUTION:The absolute maximum V+ to V- differential voltage is 13.0V. Typical “±6-Volt” or “12-Volt”supplies with ±10% tolerances can be as high as 13.2V. This voltage can damage the MAX4545/MAX4546/MAX4547. Even ±5% toler-ance supplies may have overshoot or noise spikes that exceed 13.0V.Single-Supply Operation The MAX4545/MAX4546/MAX4547 operate from a sin-gle supply between +2.7V and +12V when V- is con-nected to GND. All of the bipolar precautions must be observed. Note, however, that these parts are opti-mized for ±5V operation, and most AC and DC charac-teristics are degraded significantly when departing from ±5V. As the overall supply voltage (V+ to V-) is lowered, switching speed, on-resistance, off isolation, and distortion are degraded. (See Typical Operating Characteristics.) MAX4545/MAX4546/MAX4547Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches _______________________________________________________________________________________9M A X 4545/M A X 4546/M A X 4547Single-supply operation also limits signal levels and interferes with grounded signals. When V- = 0V, AC sig-nals are limited to -0.3V. Voltages below -0.3V can be clipped by the internal ESD-protection diodes, and the parts can be damaged if excessive current flows.Power OffWhen power to the MAX4545/MAX4546/MAX4547 is off (i.e., V+ = 0V and V- = 0V), the Absolute Maximum Ratings still apply. This means that neither logic-level inputs on IN_ nor signals on COM_, NO_, or NC_ can exceed ±0.3V. Voltages beyond ±0.3V cause the inter-nal ESD-protection diodes to conduct, and the parts can be damaged if excessive current flows.GroundingDC Ground ConsiderationsSatisfactory high-frequency operation requires that careful consideration be given to grounding. For most applications, a ground plane is strongly recom-mended, and all GND_ pins should be connected to it with solid copper.While the V+ and V- power-supply pins are common to all switches in a given package,each switch has separate ground pins that are not internally connected to each other. This contributes to the overall high-frequency performance and provides added flexibility in some applications, but it can cause problems if it is overlooked. All the GND_ pins have ESD diodes to V+ and V-.In systems that have separate digital and analog (sig-nal) grounds, connect these switch GND_ pins to ana-log ground. Preserving a good signal ground is much more important than preserving a digital ground.Ground current is only a few nanoamps.The logic-level inputs, IN_, have voltage thresholds determined by V+ and GND_. (V- does not influence the logic-level threshold.) With +5V and 0V applied to V+ and GND_, the threshold is about 1.6V, ensuring compatibility with TTL- and CMOS-logic drivers.The various GND_ pins can be connected to separate voltage potentials if any or all of the logic-level inputs is not a normal logic signal. (The GND_ voltages cannot exceed (V+ - 2V) or V-.) Elevating GND_ reduces off isolation. For example, using the MAX4545, if GND2–GND6 are connected to 0V and GND1 is connected to V-, then switches 2, 3, and 4 would be TTL/CMOS com-patible, but switch 1 (IN1) could be driven with the rail-to-rail output of an op amp operating from V+ and V-.Note, however, that IN_ can be driven more negative than GND_, as far as V-. GND_ does not have to be removed from 0V when IN_ is driven from bipolar sources, but the voltage on IN_ should never exceed V-.GND_ should be separated from 0V only if the logic-level threshold has to be changed.Any GND_ pin not connected to 0V should be bypassed to the ground plane with a surface-mount 10nF capacitor to maintain good RF grounding. DC current in the IN_ and GND_ pins is less than 1nA, but increases with switching frequency.On the MAX4545 only, two extra ground pins—GND5and GND6—are provided to improve isolation and crosstalk. They are not connected to the logic-level cir-cuit. These pins should always be connected to the ground plane with solid copper.AC Ground and BypassingA ground plane is mandatory for satisfactory high-frequency operation.(Prototyping using hand wiring or wire-wrap boards is strongly discouraged.) Connect all 0V GND_ pins to the ground plane with solid copper.(The GND_ pins extend the high-frequency ground through the package wire-frame, into the silicon itself,thus improving isolation.) The ground plane should be solid metal underneath the device, without interruptions.There should be no traces under the device itself. For DIP packages, this applies to both sides of a two-sided board. Failure to observe this will have a minimal effect on the “on” characteristics of the switch at high frequen-cies, but it will degrade the off isolation and crosstalk.All V+ and V- pins should be bypassed to the ground plane with surface-mount 10nF capacitors. For DIP packages, they should be mounted as close as possi-ble to the pins on the same side of the board as the device. Do not use feedthroughs or vias for bypass capacitors. For surface-mount packages, the pins are so close to each other that the bypass capacitors should be mounted on the opposite side of the board from the device. In this case, use short feedthroughs or vias, directly under the V+ and V- pins. Any GND_ pin not connected to 0V should be similarly bypassed. If V-is 0V, connect it directly to the ground plane with solid copper. Keep all leads short.The MAX4547 has two V+ and V- pins. Make DC con-nections to only one of each to minimize crosstalk. Do not route DC current into one of the V+ or V- pins and out the other V+ or V- pin to other devices. The second set of V+ and V- pins is for AC bypassing only.For dual-supply operation, the MAX4547 should have four 10nF bypass capacitors connected to each V+and V- pin, as close to the package as possible. For single-supply operation, the MAX4547 should have two 10nF bypass capacitors connected (one to each V+pin), as close to the package as possible.Quad/Dual, Low-Voltage,Bidirectional RF/Video Switches 10______________________________________________________________________________________MAX4545/MAX4546/MAX4547Bidirectional RF/Video Switches______________________________________________________________________________________11On the MAX4545, GND5 and GND6 should always be connected to the ground plane with solid copper to improve isolation and crosstalk.Signal RoutingKeep all signal leads as short as possible. Separate all signal leads from each other and other traces with the ground plane on both sides of the board. Where possi-ble, use coaxial cable instead of printed circuit board traces.Board LayoutIC sockets degrade high-frequency performance and should not be used if signal bandwidth exceeds 5MHz.Surface-mount parts, having shorter internal lead frames, provide the best high-frequency performance.Keep all bypass capacitors close to the device, and separate all signal leads with ground planes. Such grounds tend to be wedge-shaped as they get closer to the device. Use vias to connect the ground planes on each side of the board, and place the vias in the apex of the wedge-shaped grounds that separate signal leads.Logic-level signal lead placement is not critical.Impedance MatchingThe typical on-resistances of the switches in the MAX4545/MAX4546/MAX4547 are 14Ω, but the off-state impedances are approximately equal to a 6pF capacitor. In coaxial systems, therefore, it is impossible to match any impedance for both the on and off state. If impedance matching is critical, the MAX4546 is best suited, since its two sections can be configured as a single on/off switch, as shown in Figure 2. This circuit “wastes” switches and has higher losses, but has bet-ter off isolation and maintains good impedance match-ing in both the on and off states. The resistance values shown in Figure 3 are optimized with ±5V supplies for both 50Ωand 75Ωsystems at room temperature.MultiplexerWith its excellent off isolation, the MAX4545 is ideal for use in high-frequency video multiplexers. Figure 3shows such an application for switching any one of four video inputs to a single output. The same circuit may be used as a demultiplexer by simply reversing the sig-nal direction.Stray capacitance of traces and the output capacitance of switches placed in parallel reduces bandwidth, so the outputs of no more than four individual switches should be placed in parallel if high bandwidth is to be main-tained. If more than four mux channels are needed, the 4-channel circuit should be duplicated and cascaded.Figure 2. Impedance Matching On/Off SwitchM A X 4545/M A X 4546/M A X 4547Bidirectional RF/Video Switches 12______________________________________________________________________________________Figure 3. 4-Channel MultiplexerMAX4545/MAX4546/MAX4547Bidirectional RF/Video Switches______________________________________________________________________________________13Figure 4. Switching Time______________________________________________Test Circuits/Timing DiagramsFigure 5. Break-Before-Make Interval (MAX4546/MAX4547 only)M A X 4545/M A X 4546/M A X 4547Bidirectional RF/Video Switches 14______________________________________________________________________________________Figure 6. Charge InjectionFigure 7. On Loss, Off Isolation, and Crosstalk_________________________________Test Circuits/Timing Diagrams (continued)MAX4545/MAX4546/MAX4547Bidirectional RF/Video Switches______________________________________________________________________________________15N.C. = NO INTERNAL CONNECTIONTRANSISTOR COUNT: 253SUBSTRATE INTERNALLY CONNECTED TO V-GND2GND5GND4NO4V-NO1COM30.101"(2.565mm)0.085"(2.159mm)COM4IN4IN3GND6V+NO2N.C.NO3GND3COM1IN1IN2COM2GND1N.C.MAX4545GND2GND4N.C.COM1N.C.N.C.NC20.101"(2.565mm)0.085"(2.159mm)V+NC1IN2COM2N.C.N.C.V-N.C.GND3GND1V-MAX4547GND2N.C.N.C.NC4V-NO1GND30.101"(2.565mm)MAX4546GND4COM4COM3N.C.V+NO2N.C.NC30.085"(2.159mm)GND1N.C.Figure 8. NO_, NC_, COM_ Capacitance_________________Chip TopographiesMaxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.16__________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 (408) 737-7600©1997 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.M A X 4545/M A X 4546/M A X 4547Bidirectional RF/Video Switches___________________________________________Ordering Information (continued)*Contact factory for dice specifications.。

___________________________________________________________________Selector Guide________________General DescriptionThe MAX6316–MAX6322 family of microprocessor (µP)supervisory circuits monitors power supplies and microprocessor activity in digital systems. It offers sev-eral combinations of push/pull, open-drain, and bidirec-tional (such as Motorola 68HC11) reset outputs, along with watchdog and manual reset features. The Selector Guide below lists the specific functions available from each device. These devices are specifically designed to ignore fast negative transients on V CC . Resets are guaranteed valid for V CC down to 1V.These devices are available in 26 factory-trimmed reset threshold voltages (from 2.5V to 5V, in 100mV incre-ments), featuring four minimum power-on reset timeout periods (from 1ms to 1.12s), and four watchdog timeout periods (from 6.3ms to 25.6s). Thirteen standard ver-sions are available with an order increment requirement of 2500 pieces (see Standard Versions table); contact the factory for availability of other versions, which have an order increment requirement of 10,000 pieces.The MAX6316–MAX6322 are offered in a miniature 5-pin SOT23 package.________________________ApplicationsPortable Computers Computers ControllersIntelligent InstrumentsPortable/Battery-Powered Equipment Embedded Control Systems____________________________Features♦Small 5-Pin SOT23 Package♦Available in 26 Reset Threshold Voltages2.5V to 5V, in 100mV Increments ♦Four Reset Timeout Periods1ms, 20ms, 140ms, or 1.12s (min)♦Four Watchdog Timeout Periods6.3ms, 102ms, 1.6s, or 25.6s (typ) ♦Four Reset Output StagesActive-High, Push/Pull Active-Low, Push/Pull Active-Low, Open-Drain Active-Low, Bidirectional♦Guaranteed Reset Valid to V CC = 1V♦Immune to Short Negative V CC Transients ♦Low Cost♦No External ComponentsMAX6316–MAX63225-Pin µP Supervisory Circuits withWatchdog and Manual Reset________________________________________________________________Maxim Integrated Products 119-0496; Rev 7; 11/07_______________Ordering InformationOrdering Information continued at end of data sheet.*The MAX6318/MAX6319/MAX6321/MAX6322 feature two types of reset output on each device.Typical Operating Circuit and Pin Configurations appear at end of data sheet.For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,or visit Maxim’s website at .Specify lead-free by replacing “-T” with “+T” when ordering.ELECTRICAL CHARACTERISTICS(V CC = 2.5V to 5.5V, T A = -40°C to +125°C, unless otherwise noted. Typical values are at T A = +25°C.) (Note 1)M A X 6316–M A X 63225-Pin µP Supervisory Circuits with Watchdog and Manual Reset 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSStresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Voltage (with respect to GND)V CC ......................................................................-0.3V to +6V RESET (MAX6320/MAX6321/MAX6322 only)...... -0.3V to +6V All Other Pins.........................................-0.3V to (V CC + 0.3V)Input/Output Current, All Pins.............................................20mAContinuous Power Dissipation (T A = +70°C)SOT23-5 (derate 7.1mW/°C above +70°C)...............571mW Operating Temperature Range..........................-40°C to +125°C Junction Temperature......................................................+150°C Storage Temperature Range..............................-65°C to +160°C Lead Temperature (soldering, 10s).................................+300°CTH available in 100mV increments from 2.5V to 5V (see Table 1 at end of data sheet).Note 3:Guaranteed by design.MAX6316–MAX63225-Pin µP Supervisory Circuits withWatchdog and Manual Reset_______________________________________________________________________________________3Note 5:Measured from RESET V OL to (0.8 x V CC ), R LOAD = ∞.Note 6:WDI is internally serviced within the watchdog period if WDI is left unconnected.Note 7:The WDI input current is specified as the average input current when the WDI input is driven high or low. The WDI input is designed for a three-stated-output device with a 10µA maximum leakage current and capable of driving a maximum capac-itive load of 200pF. The three-state device must be able to source and sink at least 200µA when active.ELECTRICAL CHARACTERISTICS (continued)M A X 6316–M A X 63225-Pin µP Supervisory Circuits with Watchdog and Manual Reset 4_________________________________________________________________________________________________________________________________Typical Operating Characteristics(T A = +25°C, unless otherwise noted.)021*********-4020-20406080100MAX6316/MAX6317/MAX6318/MAX6320/MAX6321SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)S U P P L Y C U R R E N T (μA )302010504090807060100-40-20020406080100V CC FALLING TO RESET PROPAGATIONDELAY vs. TEMPERATURETEMPERATURE (°C)R E S E T P R O P A G A T I O N D E L A Y (μs )140180160240220200300280260320-40020-20406080100MAX6316/MAX6317/MAX6319/MAX6320/MAX6322MANUAL RESET TO RESETPROPAGATION DELAY vs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E L A Y (n s )0.950.980.970.961.000.991.041.031.021.011.05-40-2020406080100NORMALIZED RESET TIMEOUT PERIOD vs. TEMPERATUREM A X 6316t o c 04TEMPERATURE (°C)N O R M A L I Z E D R E S E T T I M E O U T P E R I O D0.950.980.970.961.000.991.041.031.021.011.05-40-2020406080100MAX6316/MAX6317/MAX6318/MAX6320/MAX6321NORMALIZED WATCHDOG TIMEOUTPERIOD vs. TEMPERATUREM A X 6316t o c 05TEMPERATURE (°C)N O R M A L I Z E D W A T C H D O G T I M E O U T P E R I O D800101001000MAXIMUM V CC TRANSIENT DURATION vs. RESET THRESHOLD OVERDRIVE2010RESET THRESHOLD OVERDRIVE (mV) V RST - V CCT RA N S I E N T D U R A T I O N (μs )3050604070200ns/divMAX6316M/6318MH/6319MHBIDIRECTIONALPULLUP CHARACTERISTICSMAX6316–MAX63225-Pin µP Supervisory Circuits withWatchdog and Manual Reset_______________________________________________________________________________________5______________________________________________________________Pin DescriptionM A X 6316–M A X 63225-Pin µP Supervisory Circuits with Watchdog and Manual Reset 6______________________________________________________________________________________________________Detailed DescriptionA microprocessor’s (µP) reset input starts or restarts the µP in a known state. The reset output of the MAX6316–MAX6322 µP supervisory circuits interfaces with the reset input of the µP, preventing code-execution errors during power-up, power-down, and brownout condi-tions (see the Typical Operating Circuit ). The MAX6316/MAX6317/MAX6318/MAX6320/MAX6321 are also capa-ble of asserting a reset should the µP become stuck in an infinite loop.Reset OutputThe MAX6316L/MAX6318LH/MAX6319LH feature an active-low reset output, while the MAX6317H/MAX6318_H/MAX6319_H/MAX6321HP/MAX6322HP feature an active-high reset output. RESET is guaran-teed to be a logic low and RESET is guaranteed to be a logic high for V CC down to 1V.The MAX6316–MAX6322 assert reset when V CC is below the reset threshold (V RST ), when MR is pulled low (MAX6316_/MAX6317H/MAX6319_H/MAX6320P/MAX6322HP only), or if the WDI pin is not serviced withinthe watchdog timeout period (t WD ). Reset remains assert-ed for the specified reset active timeout period (t RP ) after V CC rises above the reset threshold, after MR transitions low to high, or after the watchdog timer asserts the reset (MAX6316_/MAX6317H/MAX6318_H/MAX6320P/MAX6321HP). After the reset active timeout period (t RP )expires, the reset output deasserts, and the watchdog timer restarts from zero (Figure 2).Figure 1. Functional DiagramFigure 2. Reset Timing DiagramMAX6316–MAX63225-Pin µP Supervisory Circuits withWatchdog and Manual Reset_______________________________________________________________________________________7Bidirectional R E S E T OutputThe MAX6316M/MAX6318MH/MAX6319MH are designed to interface with µPs that have bidirectional reset pins,such as the Motorola 68HC11. Like an open-drain output,these devices allow the µP or other devices to pull the bidirectional reset (RESET ) low and assert a reset condi-tion. However, unlike a standard open-drain output, it includes the commonly specified 4.7k Ωpullup resistor with a P-channel active pullup in parallel.This configuration allows the MAX6316M/MAX6318MH/MAX6319MH to solve a problem associated with µPs that have bidirectional reset pins in systems where sev-eral devices connect to RESET (F igure 3). These µPs can often determine if a reset was asserted by an exter-nal device (i.e., the supervisor IC) or by the µP itself (due to a watchdog fault, clock error, or other source),and then jump to a vector appropriate for the source of the reset. However, if the µP does assert reset, it does not retain the information, but must determine the cause after the reset has occurred.The following procedure describes how this is done in the Motorola 68HC11. In all cases of reset, the µP pulls RESET low for about four external-clock cycles. It then releases RESET , waits for two external-clock cycles,then checks RESET ’s state. If RESET is still low, the µP concludes that the source of the reset was external and, when RESET eventually reaches the high state, it jumps to the normal reset vector. In this case, stored-state information is erased and processing begins fromscratch. If, on the other hand, RESET is high after a delay of two external-clock cycles, the processor knows that it caused the reset itself and can jump to a different vector and use stored-state information to determine what caused the reset.A problem occurs with faster µPs; two external-clock cycles are only 500ns at 4MHz. When there are several devices on the reset line, and only a passive pullup resis-tor is used, the input capacitance and stray capacitance can prevent RESET from reaching the logic high state (0.8✕V CC ) in the time allowed. If this happens, all resets will be interpreted as external. The µP output stage is guaran-teed to sink 1.6mA, so the rise time can not be reduced considerably by decreasing the 4.7k Ωinternal pullup resistance. See Bidirectional Pullup Characteristics in the Typical Operating Characteristics .The MAX6316M/MAX6318MH/MAX6319MH overcome this problem with an active pullup FET in parallel with the 4.7k Ωresistor (F igures 4 and 5). The pullup transistor holds RESET high until the µP reset I/O or the supervisory circuit itself forces the line low. Once RESET goes below V PTH , a comparator sets the transition edge flip-flop, indi-cating that the next transition for RESET will be low to high. When RESET is released, the 4.7k Ωresistor pulls RESET up toward V CC . Once RESET rises above V PTH but is below (0.85 x V CC ), the active P-channel pullup turns on. Once RESET rises above (0.85 x V CC ) or the 2µs one-shot times out, the active pullup turns off. The parallel combination of the 4.7k Ωpullup and theFigure 3. MAX6316M/MAX6318MH/MAX6319MH Supports Additional Devices on the Reset BusM A X 6316–M A X 63225-Pin µP Supervisory Circuits with Watchdog and Manual Reset 8_______________________________________________________________________________________Figure 4. MAX6316/MAX6318MH/MAX6319MH Bidirectional Reset Output Functional DiagramMAX6316–MAX63225-Pin µP Supervisory Circuits withWatchdog and Manual Reset_______________________________________________________________________________________9P-channel transistor on-resistance quickly charges stray capacitance on the reset line, allowing RESET to transition from low to high within the required two elec-tronic-clock cycles, even with several devices on the reset line. This process occurs regardless of whether the reset was caused by V CC dipping below the reset threshold, the watchdog timing out, MR being asserted,or the µP or other device asserting RESET . The parts do not require an external pullup. To minimize supply cur-rent consumption, the internal 4.7k Ωpullup resistor dis-connects from the supply whenever the MAX6316M/MAX6318MH/MAX6319MH assert reset.Open-Drain R E S E T OutputThe MAX6320P/MAX6321HP/MAX6322HP have an active-low, open-drain reset output. This output struc-ture will sink current when RESET is asserted. Connect a pullup resistor from RESET to any supply voltage up to 6V (Figure 6). Select a resistor value large enough toregister a logic low (see Electrical Characteristics ), and small enough to register a logic high while supplying all input current and leakage paths connected to the RESET line. A 10k Ωpullup is sufficient in most applications.Manual-Reset InputThe MAX6316_/MAX6317H/MAX6319_H/MAX6320P/MAX6322HP feature a manual reset input. A logic low on MR asserts a reset. After MR transitions low to high, reset remains asserted for the duration of the reset timeout peri-od (t RP ). The MR input is connected to V CC through an internal 52k Ωpullup resistor and therefore can be left unconnected when not in use. MR can be driven with TTL-logic levels in 5V systems, with CMOS-logic levels in 3V systems, or with open-drain or open-collector output devices. A normally-open momentary switch from MR to ground can also be used; it requires no external debouncing circuitry. MR is designed to reject fast, negative-going transients (typically 100ns pulses). A 0.1µF capacitor from MR to ground provides additional noise immunity.The MR input pin is equipped with internal ESD-protection circuitry that may become forward biased. Should MR be driven by voltages higher than V CC , excessive current would be drawn, which would damage the part. F or example, assume that MR is driven by a +5V supply other than V CC . If V CC drops lower than +4.7V, MR ’s absolute maximum rating is violated [-0.3V to (V CC + 0.3V)], and undesirable current flows through the ESD structure from MR to V CC . To avoid this, use the same supply for MR as the supply monitored by V CC . This guarantees that the voltage at MR will never exceed V CC .Watchdog InputThe MAX6316_/MAX6317H/MAX6318_H/MAX6320P/MAX6321HP feature a watchdog circuit that monitors the µP’s activity. If the µP does not toggle the watchdog input (WDI) within the watchdog timeout period (t WD ),reset asserts. The internal watchdog timer is cleared by reset or by a transition at WDI (which can detect pulses as short as 50ns). The watchdog timer remains cleared while reset is asserted. Once reset is released, the timer begins counting again (Figure 7).The WDI input is designed for a three-stated output device with a 10µA maximum leakage current and the capability of driving a maximum capacitive load of 200pF.The three-state device must be able to source and sink at least 200µA when active. Disable the watchdog function by leaving WDI unconnected or by three-stating the driver connected to WDI. When the watchdog timer is left open circuited, the timer is cleared internally at intervals equal to 7/8 of the watchdog period.Figure 6. MAX6320P/MAX6321HP/MAX6322HP Open-Drain RESET Output Allows Use with Multiple SuppliesFigure 5. Bidirectional RESET Timing DiagramM A X 6316–M A X 63225-Pin µP Supervisory Circuits with Watchdog and Manual Reset 10______________________________________________________________________________________Applications InformationWatchdog Input CurrentThe WDI input is internally driven through a buffer and series resistor from the watchdog counter. For minimum watchdog input current (minimum overall power con-sumption), leave WDI low for the majority of the watch-dog timeout period. When high, WDI can draw as much as 160µA. Pulsing WDI high at a low duty cycle will reduce the effect of the large input current. When WDI is left unconnected, the watchdog timer is serviced within the watchdog timeout period by a low-high-low pulse from the counter chain.Negative-Going V CC TransientsThese supervisors are immune to short-duration, nega-tive-going V CC transients (glitches), which usually do not require the entire system to shut down. Typically,200ns large-amplitude pulses (from ground to V CC ) on the supply will not cause a reset. Lower amplitude puls-es result in greater immunity. Typically, a V CC transient that goes 100mV under the reset threshold and lasts less than 4µs will not trigger a reset. An optional 0.1µF bypass capacitor mounted close to V CC provides addi-tional transient immunity.Ensuring Valid Reset OutputsDown to V CC = 0The MAX6316_/MAX6317H/MAX6318_H/MAX6319_H/MAX6321HP/MAX6322HP are guaranteed to operate properly down to V CC = 1V. In applications that require valid reset levels down to V CC = 0, a pulldown resistor to active-low outputs (push/pull and bidirectional only,F igure 8) and a pullup resistor to active-high outputs(push/pull only, Figure 9) will ensure that the reset line is valid while the reset output can no longer sink orsource current. This scheme does not work with the open-drain outputs of the MAX6320/MAX6321/MAX6322.The resistor value used is not critical, but it must be large enough not to load the reset output when V CC is above the reset threshold. F or most applications,100k Ωis adequate.Watchdog Software Considerations(MAX6316/MAX6317/MAX6318/MAX6320/MAX6321)One way to help the watchdog timer monitor software execution more closely is to set and reset the watchdog input at different points in the program, rather than pulsing the watchdog input high-low-high or low-high-low. This technique avoids a stuck loop, in which the watchdog timer would continue to be reset inside the loop, keeping the watchdog from timing out.Figure 7. Watchdog Timing RelationshipFigure 9. Ensuring RESET Valid to V CC = 0 on Active-High Push/Pull OutputsFigure 8. Ensuring RESET Valid to V CC = 0 on Active-Low Push/Pull and Bidirectional OutputsMAX6316–MAX6322Watchdog and Manual Reset______________________________________________________________________________________11F igure 10 shows an example of a flow diagram where the I/O driving the watchdog input is set high at the beginning of the program, set low at the end of every subroutine or loop, then set high again when the pro-gram returns to the beginning. If the program should hang in any subroutine, the problem would be quickly corrected, since the I/O is continually set low and the watchdog timer is allowed to time out, causing a reset or interrupt to be issued. As described in the Watchdog Input Current section, this scheme results in higher time average WDI current than does leaving WDI low for the majority of the timeout period and periodically pulsing it low-high-low.Figure 10. Watchdog Flow Diagram__________________Pin ConfigurationsTypical Operating CircuitTable 2. Standard VersionsTable 1. Factory-Trimmed Reset ThresholdsM A X 6316–M A X 6322Watchdog and Manual ResetTable 3. Reset/Watchdog Timeout PeriodsMAX6316–MAX6322Watchdog and Manual Reset______________________________________________________________________________________13__Ordering Information (continued)a watchdog feature (see Selector Guide) are factory-trimmed to one of four watchdog timeout periods. Insert the letter corre-sponding to the desired watchdog timeout period (W, X, Y, or Z from Table 3) into the blank following the reset timeout suffix.TRANSISTOR COUNT: 191SUBSTRATE IS INTERNALLY CONNECTED TO V+Chip Informationdard versions only. The required order increment for nonstandard versions is 10,000 pieces. Contact factory for availability.M A X 6316–M A X 6322Watchdog and Manual Reset 14______________________________________________________________________________________Package Information(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /packages .)M axim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a M axim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________15©2007 Maxim Integrated Productsis a registered trademark of Maxim Integrated Products, Inc.MAX6316–MAX6322 Watchdog and Manual ResetRevision History。

General DescriptionThe MAX6314 low-power CMOS microprocessor (µP)supervisory circuit is designed to monitor power supplies in µP and digital systems. The MAX6314’s RESET output is bidirectional, allowing it to be directly connected to µPs with bidirectional reset inputs, such as the 68HC11. It provides excellent circuit reliability and low cost by eliminating external components and adjustments. The MAX6314 also provides a debounced manual reset input.This device performs a single function: it asserts a reset signal whenever the V CC supply voltage falls below a preset threshold or whenever manual reset is asserted.Reset remains asserted for an internally programmed interval (reset timeout period) after V CC has risen above the reset threshold or manual reset is deasserted.The MAX6314 comes with factory-trimmed reset threshold voltages in 100mV increments from 2.5V to 5V. Preset timeout periods of 1ms, 20ms, 140ms,and 1120ms (minimum) are also available. The device comes in a SOT143 package.F or a µP supervisor with an open-drain reset pin, see the MAX6315 data sheet.________________________ApplicationsComputers ControllersIntelligent InstrumentsCritical µP and µC Power Monitoring Portable/Battery-Powered EquipmentFeatures♦Small SOT143 Package♦RESET Output Simplifies Interface to Bidirectional Reset I/Os♦Precision Factory-Set V CC Reset Thresholds:100mV Increments from 2.5V to 5V♦±1.8% Reset Threshold Accuracy at T A = +25°C ♦±2.5% Reset Threshold Accuracy Over Temp.♦Four Reset Timeout Periods Available: 1ms, 20ms, 140ms, or 1120ms (minimum) ♦Immune to Short V CC Transients ♦5µA Supply Current♦Pin-Compatible with MAX811MAX6314*68HC11/Bidirectional-CompatibleµP Reset Circuit________________________________________________________________Maxim Integrated Products1Pin ConfigurationTypical Operating Circuit19-1090; Rev 2; 12/05Ordering Information continued at end of data sheet.*Patents PendingFor pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .Ordering Information†The MAX6314 is available in a SOT143 package, -40°C to+85°C temperature range.††The first two letters in the package top mark identify the part,while the remaining two letters are the lot tracking code.Devices are available in both leaded and lead-free packaging.Specify lead-free by replacing “-T” with “+T” when ordering.M A X 631468HC11/Bidirectional-Compatible µP Reset Circuit 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = +2.5V to +5.5V, T A = -40°C to +85°C, unless otherwise noted. Typical values are at T A = +25°C.)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Note 1:The MAX6314 monitors V CC through an internal, factory-trimmed voltage divider that programs the nominal reset threshold.Factory-trimmed reset thresholds are available in 100mV increments from 2.5V to 5V (see Ordering and Marking Information ).Note 2:This is the minimum time RESET must be held low by an external pull-down source to set the active pull-up flip-flop.Note 3:Measured from RESET V OL to (0.8 x V CC ), R LOAD = ∞.V CC ........................................................................-0.3V to +6.0V All Other Pins..............................................-0.3V to (V CC + 0.3V)Input Current (V CC ).............................................................20mA Output Current (RESET )......................................................20mA Rate of Rise (V CC )...........................................................100V/µsContinuous Power Dissipation (T A = +70°C)SOT143 (derate 4mW/°C above +70°C).......................320mW Operating Temperature Range ...........................-40°C to +85°C Storage Temperature Range.............................-65°C to +160°C Lead Temperature (soldering, 10sec).............................+300°CMAX631468HC11/Bidirectional-CompatibleµP Reset Circuit_______________________________________________________________________________________3__________________________________________Typical Operating Characteristics(T A = +25°C, unless otherwise noted.)4.7k Ω PULL-UP 2V/divMAX6314 PULL-UP 2V/divINPUT 5V/div200ns/divPULLUP CHARACTERISTICS100pF4.7k Ω+5V74HC0574HC05V CCGNDMR 100pF+5VRESETMAX63146-50-303090SUPPLY CURRENT vs. TEMPERATURE215TEMPERATURE (°C)S U P P L Y C U R R E N T (µA )-101050347060135SUPPLY CURRENT vs. SUPPLY VOLTAGE215SUPPLY VOLTAGE (V)S U P P L Y C U R R E N T (µA )2344500-50-301090POWER-DOWN RESET DELAYvs. TEMPERATURE1040TEMPERATURE (°C)P O W E R -D O W N R E S E T D E L A Y (µs )-1020303050701.040.96-50-301090NORMALIZED RESET TIMEOUT PERIOD vs. TEMPERATURE (V CC RISING)0.970.981.021.001.03M A X 6314-05TEMPERATURE (°C)N O R M A L I Z E D R E S E T T I M E O U T P E R I O D -100.991.013050701.0060.994-50-301090NORMALIZED RESET THRESHOLD vs. TEMPERATURE (V CC FALLING)0.9960.9981.0041.000M A X 6314-06TEMPERATURE (°C)N O R M A L I Z E D R E S E T T H R E S H O L D-101.0023050701000101001000MAXIMUM TRANSIENT DURATION vs. RESET COMPARATOR OVERDRIVE20RESET COMP. OVERDRIVE, V TH - V CC (mV)M A X I M U M T R A N S I E N T D U R A T I O N (µs )4060806000-50-301090RESET PULLUP TIME vs. TEMPERATURE100200500300TEMPERATURE (°C)R E S E T P U L L -U P -T I M E (n s )-10400305070Figure 1. Functional Diagram M A X 631468HC11/Bidirectional-Compatible µP Reset Circuit 4_____________________________________________________________________________________________________________________________________________________Pin DescriptionSupply Voltage and Reset Threshold Monitor InputV CC4Manual Reset Input. A logic low on MR asserts reset. Reset remains asserted as long as MR is low, and for the reset timeout period (t RP ) after the reset conditions are terminated. Connect to V CC if not used.MR 3PIN Active-Low Complementary Output. In addition to the normal n-channel pulldown, RESET has a p-channel pullup transistor in parallel with a 4.7k Ωresistor to facilitate connection to µPs with bidirectional resets. See the Reset Output section.RESET2GroundGND 1FUNCTIONNAMEMAX631468HC11/Bidirectional-CompatibleµP Reset Circuit_______________________________________________________________________________________5Detailed DescriptionThe MAX6314 has a reset output consisting of a 4.7k Ωpull-up resistor in parallel with a P-channel transistor and an N-channel pull down (Figure 1), allowing this IC to directly interface with microprocessors (µPs) that have bidirectional reset pins (see the Reset Output section).Reset OutputA µP’s reset input starts the µP in a known state. The MAX6314 asserts reset to prevent code-execution errors during power-up, power-down, or brownout conditions. RESET is guaranteed to be a logic low for V CC > 1V (see the Electrical Characteristics table).Once V CC exceeds the reset threshold, the internal timer keeps reset asserted for the reset timeout period (t RP ); after this interval RESET goes high. If a brownout condition occurs (monitored voltage dips below its pro-grammed reset threshold), RESET goes low. Any time V CC dips below the reset threshold, the internal timer resets to zero and RESET goes low. The internal timer starts when V CC returns above the reset threshold, and RESET remains low for the reset timeout period.The MAX6314’s RESET output is designed to interface with µPs that have bidirectional reset pins, such as the Motorola 68HC11. Like an open-drain output, the MAX6314 allows the µP or other devices to pull RESET low and assert a reset condition. However, unlike a standard open-drain output, it includes the commonly specified 4.7k Ωpullup resistor with a P-channel active pullup in parallel.This configuration allows the MAX6314 to solve a prob-lem associated with µPs that have bidirectional reset pins in systems where several devices connect to RESET . These µPs can often determine if a reset was asserted by an external device (i.e., the supervisor IC)or by the µP itself (due to a watchdog fault, clock error,or other source), and then jump to a vector appropriate for the source of the reset. However, if the µP does assert reset, it does not retain the information, but must determine the cause after the reset has occurred.The following procedure describes how this is done with the Motorola 68HC11. In all cases of reset, the µP pulls RESET low for about four E-clock cycles. It then releases RESET , waits for two E-clock cycles, then checks RESET ’s state. If RESET is still low, the µP con-cludes that the source of the reset was external and,when RESET eventually reaches the high state, jumps to the normal reset vector. In this case, stored state information is erased and processing begins fromscratch. If, on the other hand, RESET is high after the two E-clock cycle delay, the processor knows that it caused the reset itself and can jump to a different vec-tor and use stored state information to determine what caused the reset.The problem occurs with faster µPs; two E-clock cycles is only 500ns at 4MHz. When there are several devices on the reset line, the input capacitance and stray capacitance can prevent RESET from reaching the logic-high state (0.8 x V CC ) in the allowed time if only a passive pullup resistor is used. In this case, all resets will be interpreted as external. The µP is guaranteed to sink only 1.6mA, so the rise time cannot be much reduced by decreasing the recommended 4.7k Ωpullup resistance.The MAX6314 solves this problem by including a pullup transistor in parallel with the recommended 4.7k Ωresis-tor (Figure 1). The pullup resistor holds the output high until RESET is forced low by the µP reset I/O, or by the MAX6314 itself. Once RESET goes below 0.5V, a com-parator sets the transition edge flip-flop, indicating that the next transition for RESET will be low to high. As soon as RESET is released, the 4.7k Ωresistor pulls RESET up toward V CC . When RESET rises above 0.5V,the active p-channel pullup turns on for the 2µs duration of the one-shot. The parallel combination of the 4.7k Ωpullup and the p-channel transistor on-resistance quickly charges stray capacitance on the reset line, allowing RESET to transition low to high with-in the required two E-clock period, even with several devices on the reset line (Figure 2). Once the one-shot times out, the p-channel transistor turns off. This process occurs regardless of whether the reset was caused by V CC dipping below the reset threshold, MR being asserted, or the µP or other device asserting RESET . Because the MAX6314 includes the standard 4.7k Ωpullup resistor, no external pullup resistor is required. To minimize current consumption, the internal pullup resistor is disconnected whenever the MAX6314asserts RESET .Manual Reset InputMany µP-based products require manual reset capabil-ity, allowing the operator, a test technician, or external logic circuitry to initiate a reset. A logic low on MR asserts reset. Reset remains asserted while MR is low,and for the reset active timeout period after MR returns high. To minimize current consumption, the internal 4.7k Ωpullup resistor on RESET is disconnected whenever RESET is asserted.M A X 631468HC11/Bidirectional-Compatible µP Reset Circuit 6_______________________________________________________________________________________MR has an internal 63k Ωpullup resistor, so it can be left open if not used. Connect a normally open momen-tary switch from MR to GND to create a manual reset function; external debounce circuitry is not required. If MR is driven from long cables or if the device is used in a noisy environment, connecting a 0.1µF capacitor from MR to ground provides additional noise immunity.__________Applications InformationNegative-Going V CC TransientsIn addition to issuing a reset to the µP during power-up,power-down, and brownout conditions, these devices are relatively immune to short-duration negative-going transients (glitches). The T ypical Operating Character-istics show the Maximum Transient Duration vs. Reset Threshold Overdrive, for which reset pulses are not generated. The graph was produced using negative-going pulses, starting at V RST max and ending below the programmed reset threshold by the magnitude indicated (reset threshold overdrive). The graph shows the maximum pulse width that a negative-going V CC transient may typically have without causing a reset pulse to be issued. As the amplitude of the transient increases (i.e., goes farther below the reset threshold),the maximum allowable pulse width decreases. A 0.1µF bypass capacitor mounted close to V CC provides addi-tional transient immunity.Ensuring a Valid RESET OutputDown to V CC = 0VWhen V CC falls below 1V, RESET no longer sinks current—it becomes an open circuit. Therefore, high-impedance CMOS-logic inputs connected to RESET can drift to undetermined voltages. This presents no problem in most applications, since most µP and other circuitry is inoperative with V CC below 1V. However, in applications where RESET must be valid down to V CC = 0V, adding a pull-down resistor to RESET will cause any stray leakage currents to flow to ground,holding RESET low (Figure 3). R1’s value is not critical;100k Ωis large enough not to load RESET and small enough to pull RESET to ground.Figure 2. MAX6314 Supports Additional Devices on the Reset BusFigure 3. RESET Valid to V CC = Ground CircuitMAX631468HC11/Bidirectional-CompatibleµP Reset Circuit_______________________________________________________________________________________7Figure 4. RESET Timing Diagram†The MAX6314 is available in a SOT143 package, -40°C to +85°C temperature range.††The first two letters in the package top mark identify the part, while the remaining two letters are the lot tracking code.†††Sample stocks generally held on the bolded products; also, the bolded products have 2,500 piece minimum-order quantities.Non-bolded products have 10,000 piece minimum-order quantities. Contact factory for details.Devices are available in both leaded and lead-free packaging. Specify lead-free by replacing “-T” with “+T” when ordering.Note:All devices available in tape-and-reel only. Contact factory for availability.___________________________________________Ordering Information (continued)M A X 631468HC11/Bidirectional-Compatible µP Reset Circuit Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.8_____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2005 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products, Inc._____________________________Ordering and Marking Information (continued)†The MAX6314 is available in a SOT143 package, -40°C to +85°C temperature range.††The first two letters in the package top mark identify the part, while the remaining two letters are the lot tracking code.†††Sample stocks generally held on the bolded products; also, the bolded products have 2,500 piece minimum-order quantities.Non-bolded products have 10,000 piece minimum-order quantities. Contact factory for details.Devices are available in both leaded and lead-free packaging. Specify lead-free by replacing “-T” with “+T” when ordering.Note:All devices available in tape-and-reel only. Contact factory for availability.Chip InformationTRANSISTOR COUNT: 519Package InformationFor the latest package outline information, go to /packages .。

MAX6387XS26D7-T中文资料元器件交易网19-1839; Rev 1; 04/01SC70, Single/Dual Low-Voltage, Low-Power µP Reset CircuitsGeneral DescriptionFeaturesThe MAX6381�CMAX6390 microprocessor (µP) supervisorycircuits monitor power supply voltages from +1.8V tooFactory-Set Reset Threshold Voltages Ranging+5.0V while consuming only 3µA of supply current atfrom +1.58V to+4.63V in Approximately 100mV+1.8V. Whenever VCCfalls below the factory-set resetIncrementsthresholds, the reset output asserts and remains assert-o±2.5% Reset Threshold Accuracy Overed for a minimum reset timeout period after VCCrisesTemperature (-40°C to +125°C)above the reset threshold. Re set thresholds are availablefrom +1.58V to +4.63V, in approximately 100mV incre-oSeven Reset Timeout Periods Available: 1ms,ments. Seven minimum reset timeout delays ranging20ms, 140ms, 280ms, 560ms, 1120ms, from 1ms to 1200ms are available.1200ms (min)The MAX6381/MAX6384/MAX6387 have a push-pullo3 Reset Output Optionsactive-low reset output. The MAX6382/MAX6385/Active-Low Push-PullMAX6388 have a push-pull active-high reset output,Active-High Push-Pulland theMAX6383/MAX6386/MAX6389/MAX6390 have an open-drain active-low reset output. TheActive-Low Open-DrainMAX6384/MAX6385/MAX6386 also feature aoReset Output State Guaranteed Valid debounced manual reset input (with internal pullupDown to VCC= 1Vresistor). The MAX6387/MAX6388/MAX6389 have anauxiliary input for monitoring a second voltage. TheoManual Reset Input(MAX6384/MAX6385/MAX6386)MAX6390 offers a manual reset input with a longer VoAuxiliary RESETINreset timeout period (1120ms or 1200ms) and ashorterCC(MAX6387/MAX6388/MAX6389)manual reset timeout (140ms or 150ms).oVCCReset Timeout (1120ms or 1200ms)/ManualThe MAX6381/MAX6382/MAX6383 are available in 3-pinReset Timeout (140ms or 150ms) (MAX6390)SC70 packages and the MAX6384�CMAX6390 are avail-able in 4-pin SC70 packages.oNegative-Going VCCTransient Immunity________________________ApplicationsoLow Power Consumption of 6µA at +3.6V and 3µA at +1.8VComputersoPin Compatible withControllersMAX809/MAX810/MAX803/MAX6326/MAX6327/Intelligent InstrumentsMAX6328/MAX6346/MAX6347/MAX6348, Critical µP and µC Power Monitoringand MAX6711/MAX6712/MAX6713Portable/Battery-Powered EquipmentoTiny 3-Pin SC70 and 4-Pin SC70 PackagesDual Voltage SystemsPin ConfigurationsNote:Insert reset threshold suffix (see Reset Threshold table)after "XR" or "XS". Insert reset timeout delay (see Reset TimeoutDelay table) after "D" to complete the part number. Samplestock is generally held on standard versions only (seeStandard Versions table). Standard versions have an orderincrement requirement of 2500 pieces. Nonstandard versionshave an order increment requirement of 10,000 pieces.Contact factory for availability of nonstandard versions.*MAX6390 is available with D4 or D7 timing only.Ordering Information continuedat end of data sheet.Typical Operating Circuit appears at end of data sheet.Selector Guide appears at end of data sheet.________________________________________________________________Maxim Integrated Products1For pricing, delivery, and ordering information,please contactMaxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .MAX6381�CMAX6390SC70, Single/Dual Low-Voltage, Low-Power µP Reset CircuitsMAX6381�CMAX6390ABSOLUTE MAXIMUM RATINGSVCC to GND..........................................................-0.3Vto +6.0VRESETOpen-Drain Output....................................-0.3V to+6.0VRESET, RESET (Push-Pull Output).............-0.3V to (VCC+ 0.3V)MR, RESET IN.............................................-0.3V to (VCC+ 0.3V)Input Current (VCC).............................................................20mAOutput Current (All Pins).....................................................20mAContinuous Power Dissip ation (TA= +70°C)3-Pin SC70 (derate 2.9mW/°C above +70°C)........235mW4-Pin SC70 (derate 3.1mW/°C above +70°C)........245mWOperating Temperature Range.........................-40°C to +125°CStorage Temperature Range.............................-65°C to +150°CLead Temperature (soldering, 10s).................................+300°CStresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functionaloperation of the device at these or any other conditions beyondthose indicated in the operational sections of the specifications is not implied. Exposure toabsolute maximum rating conditions for extended periodsmay affect device reliability.ELECTRICAL CHARACTERISTICSSC70, Single/Dual Low-Voltage, Low-Power µP Reset Circuits_______________________________________________________________________________________3MAX6381�CMAX6390SC70, Single/Dual Low-Voltage, Low-Power µP Reset CircuitsMAX6381�CMAX6390Typical Operating Characteristics(TA = +25°C, unless otherwise noted.)SUPPLY CURRENT vs. TEMPERATURE(NO LOAD)POWER-DOWN RESET DELAYvs. TEMPERATURENORMALIZED RESET TIMEOUT PERIOD8SUPPLY CURRENT (µA)7654321041POWER-DOWN RESET DELAY (µs)393735333129271.061.041.021.000.980.960.94-40-25-105203550658095110125TEMPERATURE (°C)25-40-25-105203550658095110125TEMPERATURE (°C)-40-25-105203550658095110125TEMPERATURE (°C)NORMALIZED RESET THRESHOLDvs. TEMPERATUREMAX6381/90 toc04OUTPUT VOLTAGE LOWvs. SINK CURRENTOUTPUT VOLTAGE HIGHvs. SOURCE CURRENT1.020NORMALIZED RESETTHRESHOLD1.0151.0101.0051.0000.9950.9900.985 1.21.00.8VOL (V)0.60.40.20036ISINK (mA)93.02.52.0VOH (V)1.51.00.500250500750100012500.990-40-25-105203550658095110125TEMPERATURE (°C)121500ISOURCE (µA)MAXIMUM TRANSIENT DURATIONvs. RESET COMPARATOR OVERDRIVERESET IN TO RESET DELAYvs. TEMPERATURE5.35.1RESET IN DELAY (µs)4.94.74.54.34.13.93.73.5MAX6381/90 toc08500MAXIMUM TRANSIENT DURATION (µs)450400350300250200150100501101005.51000-40-25-105203550658095110125TEMPERATURE (°C)RESET COMPARATOR OVERDRIVE, VTH - VCC (mV)4_____________________________________________________________________________ _________MAX6381/90 toc039NORMALIZED POWER-UP RESET TIMEOUTvs. TEMPERATURE1.0843SC70, Single/Dual Low-Voltage, Low-Power µP Reset Circuits______________________________________________________________________________ _________5MAX6381�CMAX6390SC70, Single/Dual Low-Voltage, Low-Power µP ResetCircuitsMAX6381�CMAX6390Detailed DescriptionRESET OutputA µP reset input starts the µP in a known state. TheseµP supervisory circuits assert reset to prevent codeexecution errors during power-up, power-down, orbrownout conditions.Reset asserts when VCCis below the reset threshold;once VCCexceeds the reset threshold, an internal timerkeeps the reset output asserted for the reset timeoutperiod. After this interval, reset output deasserts. Resetoutput is guaranteed to be in the correct logic state forVCC≥1V.Manual Reset Input (MAX6384/MAX6385/MAX6386/MAX6390)Man y µP-based products require manual reset capabil-ity, allowing the operator, a test technician, or externallogic circuitry to initiate a reset. A logic low on MRasserts reset. Reset remains asserted while MRis low,and for the reset active timeout period (tRP) after MRreturns high. This input has an internal 63k pullupresistor (1.35k for MAX6390), so it can be left uncon-nected if it is not used. MRcan be driven with TTL orCMOS logic levels, or with open-drain/collector outputs.Connect a normally open momentary switch from MRtoGND to create a manual-reset function; externaldebounce circuitry is not required. If MRis driven fromlong cables or if the device is used in anoisy environ-ment, connecting a 0.1µF capacitor from MRto GNDprovides additional noise immunity.RESET IN Comparator(MAX6387/MAX6388/MAX6389)RESET IN is compared to an internal +1.27V reference.If the voltage at RESET IN is less than 1.27V, resetasserts. Use the RESET IN comparator as a user-adjustable reset detector or as a secondary power-sup-ply monitor by implementing a resistor-divider at RESETIN (shown in Figure 1). Reset asserts when either VCCor RESET IN falls below its respective threshold volt-age. Use the following equation to set the threshold:VINTH= VTHRST (R1/R2 + 1)where VTHRST= +1.27V. To simplify the resistor selec-tion, choose a value of R2 and calculate R1:R1 = R2 [(VINTH/VTHRST) - 1]Since the input current at RESET IN is 50nA (max),large values can be used for R2 with no significant lossin accuracy.___________Applications InformationIn addition to issuing a reset to the µP during power-up,power-down, and brownout conditions, theMAX6381�CMAX6390 are relatively immune to short dura-tion negative-going VCCtransients (glitches).The Typical Operating Characteristicssection shows theMaximum Transient Durations vs. Reset ComparatorOverdrive, for which the MAX6381�CMAX6390 do notgenerate a reset pulse. This graph was generated usingNegative-Going VCCTransients6_____________________________________________________________________________ __________SC70, Single/Dual Low-Voltage, Low-Power µP Reset CircuitsMAX6381�CMAX6390not work with the open-drain outputs of theMAX6383/MAX6386/MAX6389/MAX6390. The resistorvalue used is not critical, but it must be small enoughnot to load the reset output when VCCis above the resetthreshold. For most applications, 100k is adequate.a negative-going pulse applied to VCC, starting above theactual reset threshold and ending below it by the magni-tude indicated (reset comparator overdrive). The graphindicates the typical maximum pulse width a negative-going VCCtransient may have without causing a resetpulse to be issued. As the magnitude of the transientincreases (goes farther below the reset threshold), themaximum allowable pulse width decreases. A 0.1µFcapacitor mounted as close as possible to VCCprovidesadditional transient immunity.The MAX6381�CMAX6390 are guaranteed to operateproperly down to VCC= 1V.In applications that requirevalid reset levels down to VCC= 0, a pulldown resistor toactive-low outputs (push/pull only, Figure 2) and apullup resistorto active-high outputs (push/pull only) willensure that the reset line isvalid while the reset outputcan no longer sink or source current. This scheme doesEnsuring a Valid RESETOutput Down to VCC= 0_______________________________________________________________________________________7SC70, Single/Dual Low-Voltage, Low-Power µP ResetCircuitsMAX6381�CMAX6390Pin Configurations (continued)*MRis for MAX6384/MAX6385/MAX6386/MAX6390**RESET IN is forMAX6387/MAX6388/MAX6389( ) are for MAX6382/MAX6385/MAX6388Chip InformationTRANSISTOR COUNT: 647PROCESS: BiCMOSSC70, Single/Dual Low-Voltage, Low-Power µP Reset CircuitsOrdering InformationNote:Insert reset threshold suffix (see Reset Threshold table)after "XR" or "XS". Insert reset timeout delay (see Reset TimeoutDelay table) after "D" to complete the part number. Samplestock is generally held on standard versions only (seeStandard Versions table). Standard versions have an orderincrement requirement of 2500 pieces. Nonstandard versionshave an order increment requirement of 10,000 pieces.Contact factory for availability of nonstandard versions.*MAX6390 is available with D4 or D7 timing only.______________________________________________________________________________ _________9MAX6381�CMAX6390SC70, Single/Dual Low-Voltage, Low-Power µP ResetCircuitsMAX6381�CMAX6390Package Information10____________________________________________________________________________ __________SC70, Single/Dual Low-Voltage, Low-Power µP Reset CircuitsPackage Information (continued)Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses areimplied. Maxim reserves the right to change the circuitry and specifications without notice at any time.Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600____________________11©2001 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.MAX6381�CMAX6390感谢您的阅读，祝您生活愉快。

用于Peltier模块的集成温度控制器概论MAX1978 / MAX1979是用于Peltier热电冷却器（TEC）模块的最小, 最安全, 最精确完整的单芯片温度控制器。

片上功率FET和热控制环路电路可最大限度地减少外部元件, 同时保持高效率。

可选择的500kHz / 1MHz开关频率和独特的纹波消除方案可优化元件尺寸和效率, 同时降低噪声。

内部MOSFET的开关速度经过优化, 可降低噪声和EMI。

超低漂移斩波放大器可保持±0.001°C的温度稳定性。

直接控制输出电流而不是电压, 以消除电流浪涌。

独立的加热和冷却电流和电压限制提供最高水平的TEC保护。

MAX1978采用单电源供电, 通过在两个同步降压调节器的输出之间偏置TEC, 提供双极性±3A输出。

真正的双极性操作控制温度, 在低负载电流下没有“死区”或其他非线性。

当设定点非常接近自然操作点时, 控制系统不会捕获, 其中仅需要少量的加热或冷却。

模拟控制信号精确设置TEC 电流。

MAX1979提供高达6A的单极性输出。

提供斩波稳定的仪表放大器和高精度积分放大器, 以创建比例积分（PI）或比例积分微分（PID）控制器。

仪表放大器可以连接外部NTC或PTC热敏电阻, 热电偶或半导体温度传感器。

提供模拟输出以监控TEC温度和电流。

此外, 单独的过热和欠温输出表明当TEC温度超出范围时。

片上电压基准为热敏电阻桥提供偏置。

MAX1978 / MAX1979采用薄型48引脚薄型QFN-EP 封装, 工作在-40°C至+ 85°C温度范围。

采用外露金属焊盘的耐热增强型QFN-EP封装可最大限度地降低工作结温。

评估套件可用于加速设计。

应用光纤激光模块典型工作电路出现在数据手册的最后。

WDM, DWDM激光二极管温度控制光纤网络设备EDFA光放大器电信光纤接口ATE特征♦尺寸最小, 最安全, 最精确完整的单芯片控制器♦片上功率MOSFET-无外部FET♦电路占用面积<0.93in2♦回路高度<3mm♦温度稳定性为0.001°C♦集成精密积分器和斩波稳定运算放大器♦精确, 独立的加热和冷却电流限制♦通过直接控制TEC电流消除浪涌♦可调节差分TEC电压限制♦低纹波和低噪声设计♦TEC电流监视器♦温度监控器♦过温和欠温警报♦双极性±3A输出电流（MAX1978）♦单极性+ 6A输出电流（MAX1979）订购信息* EP =裸焊盘。

For free samples and the latest literature, visit or phone 1-800-998-8800.For small orders, phone 1-800-835-8769.General DescriptionThe MAX6361–MAX6364 supervisory circuits reduce the complexity and number of components required for power-supply monitoring and battery control functions in microprocessor (µP) systems. The circuits significantly improve system reliability and accuracy compared to that obtainable with separate ICs or discrete components.Their functions include µP reset, backup battery switchover, and power failure warning.The MAX6361–MAX6364 operate from supply voltages as low as +1.2V. The factory-preset reset threshold voltage ranges from 2.32V to 4.63V (see Ordering Information ).These devices provide a manual reset input (MAX6361),watchdog timer input (MAX6362), battery-on output (MAX6363), and an auxiliary adjustable reset input (MAX6364). In addition, each part type is offered in three reset output versions: an active-low open-drain reset, an active-low open-drain reset, and an active-high open-drain reset (see Selector Guide at end of data sheet).ApplicationsFeatures♦Low +1.2V Operating Supply Voltage (V CC or V BATT )♦Precision Monitoring of +5.0V, +3.3V, +3.0V, and +2.5V Power-Supply Voltages♦Debounced Manual Reset Input (MAX6361)♦Watchdog Timer with 1.6s Timeout Period (MAX6362)♦Battery-On Output Indicator (MAX6363)♦Auxiliary User-Adjustable RESET IN (MAX6364)♦Three Available Output StructuresPush-Pull RESET , Open-Drain RESET , Open-Drain RESET♦RESET/RESET Valid Down to 1.2V Guaranteed (V CC or V BATT )♦Power-Supply Transient Immunity ♦150ms (min) Reset Timeout Period ♦Small 6-Pin SOT23 PackageMAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup________________________________________________________________Maxim Integrated Products119-1615; Rev 3; 11/05Ordering InformationPin ConfigurationsFrom the table below, select the suffix corresponding to the desired threshold voltage and insert it into the part number to complete it. When ordering from the factory, there is a 2500-piece minimum on the SOT package (tape-and-reel only).Devices are available in both leaded and lead-free packaging.Specify lead-free by replacing "-T" with "+T" when ordering.Computers ControllersIntelligent Instruments Critical µP/µC Power MonitoringFax Machines Industrial Control POS EquipmentPortable/Battery-Powered EquipmentSelector Guide appears at end of data sheet.Typical Operating Circuit appears at end of data sheet.M A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery BackupABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = +2.4V to +5.5V, V BATT = 3V, T A = -40°C to +85°C, reset not asserted. Typical values are at T A = +25°C, unless otherwise noted.) (Note 1)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Terminal Voltages (with respect to GND)V CC , BATT, OUT.......................................................-0.3V to +6V RESET (open drain), RESET (open drain)................-0.3V to +6V BATT ON, RESET (push-pull), RESET IN,WDI.......................................................-0.3V to (V OUT + 0.3V)MR .............................................................-0.3V to (V CC + 0.3V)Input CurrentV CC Peak ............................................................................1A V CC Continuous............................................................250mA BATT Peak....................................................................250mA BATT Continuous............................................................40mAGND................................................................................75mA Output CurrentOUT................................Short-Circuit Protection for up to 10s RESET, RESET , BATT ON ..............................................20mA Continuous Power Dissipation (T A = +70°C)6-Pin SOT23 (derate 8.70mW/°C above +70°C) .........696mW Operating Temperature Range ...........................-40°C to +85°C Junction Temperature......................................................+150°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CMAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS (continued)(V CC = +2.4V to +5.5V, V BATT = 3V, T A = -40°C to +85°C, reset not asserted. Typical values are at T A = +25°C, unless otherwise noted.) (Note 1)Note 1:All devices are 100% production tested at T A = +25°C. Limits over temperature are guaranteed by design.Note 2:V BATT can be 0 anytime or V CC can go down to 0 if V BATT is active (except at startup).M A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery Backup 4_______________________________________________________________________________________Typical Operating Characteristics(T A = +25°C, unless otherwise noted.)1214161820SUPPLY CURRENT vs. TEMPERATURE(NO LOAD)TEMPERATURE (°C)S U P P L Y C U R R E N T (µA )-402040-2060800.20.60.40.81.01.2BATTERY SUPPLY CURRENT (BACKUP MODE) vs. TEMPERATURETEMPERATURE (°C)B A T T E R Y S U P P L Y C U R R E N T (µA )-402040-20060801432567BATTERY TO OUT ON-RESISTANCEvs. TEMPERATURETEMPERATURE (°C)B A T T T O O U T O N -R E S I S T A NC E (Ω)-402040-20608000.30.90.61.2V CC TO OUT ON-RESISTANCEvs. TEMPERATURETEMPERATURE (°C)V O U T T O O U T O N -R E S I S T A N C E (Ω)-402040-206080190195205200210RESET TIMEOUT PERIOD vs. TEMPERATUREM A X 6361 t o c 05TEMPERATURE (°C)R E S E T T I M E O U T P E R I O D (m s )-402040-206080301575604513512010590V CC TO RESET PROPAGATION DELAYvs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E LA Y (µs )-402040-2060802.03.02.55.04.54.03.5RESET THRESHOLD vs. TEMPERATURETEMPERATURE (°C)T H R E S H O L D (V )-402040-2060801.21.41.31.61.51.91.81.72.0-40-2020406080MAX6362WATCHDOG TIMEOUT PERIODvs. TEMPERATUREM A X 6361t o c 06aTEMPERATURE (°C)W A T C H D O G T I M E O U T P E R I O D (s )1100101k10kMAXIMUM TRANSIENT DURATION vs. RESET THRESHOLD OVERDRIVERESET THRESHOLD OVERDRIVE V TH - V CC (mV)M A X I M U M T R A N S I E N T D U R A T I O N (µs )400300350250200050150100MAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup1.2341.2351.236MAX6364RESET IN THRESHOLD vs. TEMPERATUREM A X 6361 t o c 10TEMPERATURE (°C)T H R E S H O L D (V )-402040-206080Typical Operating Characteristics (continued)(T A = +25°C, unless otherwise noted.)1.01.91.61.32.82.52.2MAX6364RESET IN TO RESET PROPAGATION DELAYvs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E L A Y (µs )-402040-206080Pin Description0321456789101234BATTERY SUPPLY CURRENT vs. SUPPLY VOLTAGEV CC (V)B A T T E R Y S U P P L YC U R R E N T (µA )M A X 6361–M A X 6364Detailed DescriptionThe Typical Operating Circuit shows a typical connection for the MAX6361–MAX6364 family. OUT powers the stat-ic random-access memory (SRAM). OUT is internally connected to V CC if V CC is greater than the reset thresh-old, or to the greater of V CC or V BATT when V CC is less than the reset threshold. OUT can supply up to 150mA from V CC . When V CC is higher than V BATT , the BATT ON (MAX6363) output is low. When V CC is lower than V BATT ,an internal MOSF ET connects the backup battery to OUT. The on-resistance of the MOSFET is a function of backup-battery voltage and is shown in the Battery to Out On-Resistance vs. Temperature graph in the Typical Operating Characteristics section.Backup-Battery SwitchoverIn a brownout or power failure, it may be necessary to preserve the contents of the RAM. With a backup bat-tery installed at BATT, the MAX6361–MAX6364 auto-matically switch the RAM to backup power when V CC falls. The MAX6363 has a BATT ON output that goes high when in battery-backup mode. These devices require two conditions before switching to battery-backup mode:1)V CC must be below the reset threshold.2)V CC must be below V BATT .Table 1 lists the status of the inputs and outputs in bat-tery-backup mode. The device will not power up if the only voltage source is on BATT. OUT will only power up from V CC at startup.Manual Reset Input (MAX6361 Only)Many µP-based products require manual reset capabili-ty, allowing the operator, a test technician, or external logic circuitry to initiate a reset. For the MAX6361, a logic low on MR asserts reset. Reset remains asserted while MR is low, and for a minimum of 150ms (t RP ) after it returns high. MR has an internal 20k Ωpull-up resistor to V CC . This input can be driven with TTL/CMOS logic lev-els or with open-drain/collector outputs. Connect a nor-mally open momentary switch from MR to GND to create a manual reset function; external debounce circuitry is not required. If MR is driven from long cables or the device is used in a noisy environment, connect a 0.1µF capacitor from MR to GND to provide additional noise immunity.Watchdog Input (MAX6362 Only)The watchdog monitors µP activity through the input WDI. If the µP becomes inactive, the reset output is asserted in pulses. To use the watchdog function, con-nect WDI to a bus line or µP I/O line. A change of state(high to low or low to high) within the watchdog timeout period (t WD ) with a 100ns minimum pulse width clears the watchdog timer. If WDI remains high or low for longer than the watchdog timeout period, the internal watchdog timer runs out and a reset pulse is triggered for the reset timeout period (t RP ). The internal watchdog timer clears whenever reset asserts or the WDI sees a rising or falling edge within the watchdog timeout period. If WDI remains in a high or low state for an extended period of time, a reset pulse asserts after every watchdog timeout period (t WD ) (Figure 1).Reset In (MAX6364 Only)RESET IN is compared to an internal 1.235V reference.If the voltage at RESET IN is less than 1.235V, reset is asserted. The RESET IN comparator may be used as an undervoltage detector to signal a failing power sup-ply. It can also be used as a secondary power-supply reset monitor.To program the reset threshold (V RTH ) of the secondary power supply, use the following equation (see Typical Operating Circuit ):where V REF = 1.235V. To simplify the resistor selection,choose a value for R2 and calculate R1:Since the input current at RESET IN is 25nA (max), large values (up to 1M Ω) can be used for R2 with no signifi-cant loss in accuracy. F or example, in the TypicalSOT23, Low-Power µP Supervisory Circuits with Battery Backup 6_______________________________________________________________________________________R R V V RTH REF 121 /=()−[]MAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup_______________________________________________________________________________________7Operating Circuit,the MAX6362 monitors two supply voltages. To monitor the secondary 5V logic or analog supply with a 4.60V nominal programmed reset thresh-old, choose R2 = 100k Ω, and calculate R1 = 273k Ω.Reset OutputA µP’s reset input starts the µP in a known state. The MAX6361–MAX6364 µP supervisory circuits assert a reset to prevent code-execution errors during power-up, power-down, and brownout conditions. RESET is guaranteed to be a logic low or high depending on the device chosen (see Ordering Information ). RESET or RESET asserts when V CC is below the reset threshold and for at least 150ms (t RP ) after V CC rises above the reset threshold. RESET or RESET also asserts when MR is low (MAX6361) and when RESET IN is less than 1.235V (MAX6364). The MAX6362 watchdog function will cause RESET (or RESET ) to assert in pulses follow-ing a watchdog timeout (Figure 1).Applications InformationOperation Without a BackupPower SourceThe MAX6361–MAX6364 were designed for battery-backed applications. If a backup battery is not used,connect V CC to OUT and connect BATT to GND.Replacing the Backup BatteryIf BATT is decoupled with a 0.1µF capacitor to ground,the backup power source can be removed while V CC remains valid without danger of triggering a reset pulse.The device does not enter battery-backup mode when V CC stays above the reset threshold voltage.Negative-Going V CC TransientsThese supervisors are relatively immune to short-dura-tion, negative-going V CC transients. Resetting the µPwhen V CC experiences only small glitches is usually not desirable.The Typical Operating Characteristics section shows a graph of Maximum Transient Duration vs. Reset Threshold Overdrive for which reset is not asserted.The graph was produced using negative-going V CC pulses, starting at V CC and ending below the reset threshold by the magnitude indicated (reset threshold overdrive). The graph shows the maximum pulse width that a negative-going V CC transient can typically have without triggering a reset pulse. As the amplitude of the transient increases (i.e., goes further below the reset threshold), the maximum allowable pulse width decreases. Typically, a V CC transient that goes 100mV below the reset threshold and lasts for 30µs will not trigger a reset pulse.A 0.1µF bypass capacitor mounted close to the V CC pin provides additional transient immunity.Figure 1. MAX6362 Watchdog Timeout Period and Reset Active TimeM A X 6361–M A X 6364Watchdog Software Considerations(MAX6362 Only)To help the watchdog timer monitor software execution more closely, set and reset the watchdog input at dif-ferent points in the program, rather than “pulsing” the watchdog input low-high-low. This technique avoids a “stuck” loop, in which the watchdog timer would contin-ue to be reset within the loop, keeping the watchdog from timing out. F igure 2 shows an example of a flow diagram where the I/O driving the WDI is set low at the beginning of the program, set high at the beginning of every subroutine or loop, then set low again when the program returns to the beginning. If the program should “hang” in any subroutine, the problem would quickly be corrected, since the I/O is continually set low and the watchdog timer is allowed to time out, trigger-ing a reset.SOT23, Low-Power µP Supervisory Circuits with Battery Backup 8_______________________________________________________________________________________Figure 2. Watchdog Flow DiagramMAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup_______________________________________________________________________________________9*Sample stock generally held on standard versions only. Contact factory for availability of nonstandard versions.Device Marking CodesSelector GuideM A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery Backup 10______________________________________________________________________________________Pin Configurations (continued)Typical Operating CircuitChip InformationTRANSISTOR COUNT: 720MAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuits with Battery Backup______________________________________________________________________________________11Package InformationM A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery BackupMaxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.12____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2005 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products, Inc.NOTES。

_______________General DescriptionThe MAX4516/MAX4517 are single-pole/single-throw (SPST), CMOS, low-voltage, dual-supply analog switch-es with very low switch on-resistance. The MAX4516 is normally open (NO). The MAX4517 is normally closed (NC).These CMOS switches can operate continuously with dual supplies between ±1V and ±6V. Each switch can handle rail-to-rail analog signals. The off-leakage cur-rent maximum is only 1nA at +25°C or 20nA at +85°C.The digital input is referenced to the positive power supply and is CMOS compatible.For pin-compatible parts for use with a single supply,refer to the MAX4514/MAX415.________________________ApplicationsBattery-Operated Equipment Audio and Video Signal Routing Low-Voltage Data-Acquisition Systems Communications Circuits PCMCIA Cards Cellular Phones Modems____________________________Featureso Available in SOT23-5 Package o ±1V to ±6V Dual-Supply Operation o Guaranteed On-Resistance: 20Ωwith ±5V Supplies o Guaranteed Low Off-Leakage Currents:1nA at +25°C 20nA at +85°C o Guaranteed Low On-Leakage Currents:2nA at +25°C 40nA at +85°C o Low Charge Injection: 20pC Maxo Fast Switching Speed: t ON = 100ns, t OFF = 75ns o t ON > t OFF at ±5Vo CMOS Logic Compatible with ±5V SuppliesMAX4516/MAX4517Dual-Supply, Low-On-Resistance,SPST, CMOS Analog Switches________________________________________________________________Maxim Integrated Products 1__________________________________________________________Pin Configurations19-1068; Rev 0; 6/96Ordering Information continued at end of data sheet.*Contact factory for dice specifications.For free samples & the latest literature: , or phone 1-800-998-8800M A X 4516/M A X 4517Dual-Supply, Low-On-Resistance, SPST, CMOS Analog Switches 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS—±5V Supply(V+ = +4.5V to +5.5V, V- = -4.5V to -5.5V, V INH = 3.5V, V INL = 1.5V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.(Voltages Referenced to V-)V+..............................................................................-0.3V, +13V Voltage into Any Terminal (Note 1)or ±20mA (whichever occurs first) ..........-0.3V to (V+ + 0.3V)Continuous Current into Any Terminal..............................±20mA Peak Current, NO, NC, or COM_(pulsed at 1ms, 10% duty cycle)..................................±30mA ESD per Method 3015.7..................................................>2000V Continuous Power Dissipation (T A = +70°C)8-Pin Plastic DIP (derate 9.09mW/°C above +70°C)...727mW 8-Pin SO (derate 5.88mW/°C above +70°C)................471mW 5-Pin SOT23-5 (derate 7.1mW/°C above +70°C)........571mW 8-Pin CERDIP (derate 8.00mW/°C above +70°C)........640mW Operating Temperature RangesMAX4516C_ _/MAX4517_ _................................0°C to +70°C MAX4516E_ _/MAX4517E_ _...........................-40°C to +85°C MAX4516MJA/MAX4517MJA........................-55°C to +125°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10sec).............................+300°CNote 1:Voltages exceeding V+ or V- on any signal terminal are clamped by internal diodes. Limit forward-diode current to maximum current rating.MAX4516/MAX4517Dual-Supply, Low-On-Resistance,SPST, CMOS Analog Switches_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS—±5V Supply (continued)(V+ = +4.5V to +5.5V, V- = -4.5V to -5.5V, V INH = 3.5V, V INL = 1.5V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)Note 2:The algebraic convention is used in this data sheet; the most negative value is shown in the minimum column.Note 3:Leakage parameters are 100% tested at maximum-rated hot operating temperature, and are guaranteed by correlation at +25°C.Note 4:Guaranteed, not production tested.Note 5:SOT packaged parts are 100% tested at +25°C. Limits at maximum and minimum rated temperature are guaranteed by design and correlation limits at +25°C.M A X 4516/M A X 4517Dual-Supply, Low-On-Resistance, SPST, CMOS Analog Switches 4_________________________________________________________________________________________________________________________________Typical Operating Characteristics(V+ = +5V, V- = -5V, T A = +25°C, unless otherwise noted.)300510-50-11324-4-3-25ON-RESISTANCE vs. V COM OVER TEMPERATUREV COM (V)R O N (Ω)15202510001-6024-4-26V COM (V)R O N (Ω)10010ON-RESISTANCE vs. V COM160264-60-224-46CHARGE INJECTION vs. V COMV COM (V)Q (p C )10812141001010.10.00001-60406080100120-40-20020140ON/OFF-LEAKAGE vs. TEMPERATURETEMPERATURE (°C)O N /O F F L E A K A G E ( n A )0.010.0010.00011000.01101k 10k100100kTOTAL HARMONIC DISTORTIONvs. FREQUENCY0.1M A X 4516/17-06FREQUENCY (Hz)T H D (%)1100-10-20-30-50-40-1201001M 10M 100M 1k 10k 100k 1GFREQUENCY RESPONSEFREQUENCY (Hz)L O S S (d B )P H A S E (D E G R E E S )-60-70-90-80-100-110605040301020-600-10-30-20-40-5030005010024681012T ON /T OFF vs. SUPPLY VOLTAGESUPPLY VOLTAGE (V)T I M E (n s )150200250020406080100120140160-55-35-15525456585105125SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)I +, I - (µA )__________Applications InformationPower-Supply ConsiderationsThe MAX4516/MAX4517 operate with power-supply voltages from ±1V to ±6V, but are tested and guaran-teed only with ±5V supplies. Similarly, they will operate with a single +2V to +12V supply, but logic-level inputs can shift with higher voltages. The pin-compatible MAX4514/MAX4515 are recommended for use with a single supply.The MAX4516/MAX4517 construction is typical of most CMOS analog switches, except that they have only two supply pins: V+ and V-. V+ and V- drive the internal CMOS switches and set their analog voltage limits.Reverse ESD-protection diodes are internally connected between each analog-signal pin and both V+ and V-.One of these diodes conducts if any analog signal exceeds V+ or V-.Virtually all the analog leakage current comes from the ESD diodes to V+ or V-. Although the ESD diodes on a given signal pin are identical and therefore fairly well balanced, they are reverse biased differently. Each is biased by either V+ or V- and the analog signal. This means their leakages will vary as the signal varies. The difference in the two diode leakages to the V+ and V-pins constitutes the analog-signal-path leakage current.All analog leakage current flows between each pin and one of the supply terminals, not to the other switch ter-minal. This is why both sides of a given switch can show leakage currents of the same or opposite polarity.There is no connection between the analog-signal paths and V+ or V-.V+ and V- also power the internal logic and logic-level translators. The logic-level translators convert the logic levels to switched V+ and V- signals to drive the analog signal gates.Logic-Level ThresholdsThe logic-level thresholds are CMOS-compatible but not TTL-compatible . Since these parts have no ground pin, the logic-level threshold is referenced to V+. The threshold limits are V+ = -1.5V and V+ = -3.5V for V+ levels between +6V and +3V. When V+ = +2V,the logic threshold is approximately 0.6V.Do not connect the MAX4516/MAX4517’s V+ to +3V and then connect the logic-level pins to logic-level signals that operate from a +5V supply. TTL levels can exceed +3V and violate the absolute maximum ratings, damaging the part and/or external circuits.High-Frequency PerformanceIn 50Ωsystems, signal response is reasonably flat up to 250MHz (see Typical Operating Characteristics ).Above 20MHz, the on response has several minor peaks that are highly layout dependent. The problem is not in turning the switch on; it’s in turning it off. The off-state switch acts like a capacitor and passes higher fre-quencies with less attenuation. At 10MHz, off isolation is about -48dB in 50Ωsystems, decreasing (approximate-ly 20dB per decade) as frequency increases. Higher cir-cuit impedances also cause off isolation to decrease.Off isolation is about 3dB above that of a bare IC sock-et, and is due entirely to capacitive coupling.MAX4516/MAX4517Dual-Supply, Low-On-Resistance,SPST, CMOS Analog Switches_______________________________________________________________________________________5______________________________________________________________Pin DescriptionNote:NO, NC, and COM pins are identical and interchangeable. Any may be considered as an input or an output; signals passequally well in both directions.M A X 4516/M A X 4517Dual-Supply, Low-On-Resistance, SPST, CMOS Analog Switches 6_______________________________________________________________________________________Figure 1. Switching TimesFigure 2. Charge Injection ______________________________________________Test Circuits/Timing DiagramsMAX4516/MAX4517Dual-Supply, Low-On-Resistance,SPST, CMOS Analog Switches_______________________________________________________________________________________7_________________________________Test Circuits/Timing Diagrams (continued)Figure 3. Off Isolation, On Loss, and CrosstalkFigure 4. NO, NC, and COM Capacitance_Ordering Information (continued)*Contact factory for dice specifications.**Contact factory for availability.TRANSISTOR COUNT: 36SUBSTRATE IS INTERNALLY CONNECTED TO V+___________________Chip TopographyV-0.043" (1.09mm)0.031" (0.79mm)COMNO or NCV+INMaxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are M A X 4516/M A X 4517Dual-Supply, Low-On-Resistance, SPST, CMOS Analog Switches implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.8___________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 (408) 737-7600©1996 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.__________________________________________________Tape-and-Reel Information。

KINTEX UltraScale开发平台用户手册ACKU040核心板2 / 24芯驿电子科技（上海）有限公司文档版本控制文档版本修改内容记录REV1.0创建文档目录文档版本控制 (2)一、ACKU040核心板 (4)(一)简介 (4)(二)FPGA芯片 (5)(三)DDR4 DRAM (5)(四)QSPI Flash (10)(五)时钟配置 (11)(六)LED灯 (12)(七)电源 (12)(八)结构图 (14)(九)连接器管脚定义 (14)3 / 244 / 24芯驿电子科技（上海）有限公司一、 ACKU040核心板(一) 简介ACKU040(核心板型号，下同)核心板，FPGA 芯片是基于XILINX 公司的XC7K325系列的XCKU040-2FFVA1156I 。

核心板使用了4片Micron 的1GB 的DDR4芯片MT40A512M16LY-062EIT,总的容量达4GB 。

另外核心板上也集成了2片128MBit 大小的QSPI FLASH ，用于启动存储配置和系统文件。

这款核心板的6个板对板连接器扩展出了359个IO ，其中BANK64和BANK65的104个IO 的电平是3.3V ，其它BANK 的IO 都是1.8V 。

另外核心板也扩展出了20对高速收发器GTH 接口。

对于需要大量IO 的用户，此核心板将是不错的选择。

而且IO连接部分，FPGA 芯片到接口之间走线做了等长和差分处理，并且核心板尺寸仅为80*60（mm ），对于二次开发来说，非常适合。

ACKU040核心板正面图5 / 24(二) FPGA 芯片核心板使用的是Xilinx 公司的KINTEX UltraSacale 芯片，型号为XCKU040-2FFVA1156I 。

速度等级为2，温度等级为工业级。

此型号为FFVA1156封装，1156个引脚，引脚间距为1.0mm 。

Xilinx KINTEX UltraSacale 的芯片命名规则如下图1-2-1所示：图1-2-1 KINTEX UltraSacale FPGA 型号命名规则定义其中FPGA 芯片XCKU040的主要参数如下所示：名称具体参数 逻辑单元Logic Cells 530,250 查找表(CLB LUTs) 242,400 触发器(CLB flip-flops) 484,800 Block RAM （Mb ）大小 21.1 DSP 处理单元（DSP Slices ）1,920 PCIe Gen3 x8 3GTH Transceiver20个，16.3Gb/s max速度等级 -2 温度等级工业级(三) DDR4 DRAM核心板上配有四片Micron(美光）的1GB 的DDR4芯片,型号为MT40A512M16LY-062EIT 。

型号资料名称备注4N35/ 4N36/ 4N37 光电耦合器AD752 0/AD7521/A D7530 /AD75 21 D/A转换器10-Bit,12-Bit,Multiplying D/A ConvertersAD754 1 12位D/A转换器12-Bit,Multiplying D/A ConverterADC0802/AD C0803 /ADC0 804 8位A/D转换器8-Bit,Microprocessor-Compatibie,A/D ConvertersADC08 08/AD C0809 8位A/D转换器8-Bit μP Compatibie A/D Converters with 8-ChannelMultiplexerADC08 31/ADC0832 /ADC0 834/A DC083 8 8位A/D转换器8-Bit Serial I/O A/D Converters with Multiplexer OptionsCA308 0/CA3 080A OTA跨导运算放大器CA314 0/CA3 140A BiMOS运算放大器DAC08 30/DA C0832 8位D/A转换器8-Bit μP Compatibie,Double-Buffered D to A ConvertersICL71 06,IC L7107 3位半A/D转换器ICL7106,ICL7107,ICL7106S,ICL7107S 3位半LCD/LED显示A/D转换器（ICL7106,ICL7107,ICL7106S,ICL7107S,3 1/2Digit,LCD/LED Display,A/D Converters）ICL71 16,IC L7117 3位半A/D转换器ICL7116,ICL7117 3位半LCD/LED显示数据保持A/D转换器（ICL7116,ICL7117 ,3 1/2 Digit,LCD/LED Display,A/DConverter with Display Hold）ICL76 50 载波稳零运算放大器ICL76 60/MA X1044 CMOS电源电压变换器ICL80 38 单片函数发生器ICM72 16 10MHz通用计数器ICM7216A/ICM7216B/ICM7216D 10MHz通用计数器、数字频率计、计数器、周期测量仪等仪器的单片专用电路，只须少量的外围元件就能构成10MHz的数字频率计等数字测量仪表。