632P563X9400中文资料

P3SAE 和 370SAE系列品產主機板User’s Manual中文使用手冊品名稱產： P3SAE, P3SAE-L, P3SAE-P370SAE, 370SAE-L或370SAE-P 手冊版本：中文1.2商標聲明Intel, Socket 370, Celeron , Pentium II 及 Pentium III 為 Intel產（英代爾）Corp.之品及註冊商標。

產VIA 為 VIA （威盛）Technologies, Incorporated 之品及註冊商標。

產Award 為 Award Software International Inc. 之品及註冊商標。

MS-DOS, Windows 95, Windows 98, Windows 2000 及Windows NT 為Microsoft Corporation之註冊商標。

Novell 為Novell Corporation之註冊商標。

ADI 為 Analog Devices Inc., 之註冊商標。

產所有其他商標及品名稱屬於各該公司之註冊商標或版權。

-R01-目 錄第一章、簡介1.1品簡介產 (6)產內 (7)1.2品容產 (7)1.3品特色1.4品規格產 (7)1.5主機板零件配置圖 (10)第二章、主機板安裝設定2.1主機板安裝程序 (11)2.1.1一般跳接器設定 (11)2.1.2網路功能設定 (11)2.1.3鍵盤的電壓設定 (12)2.1.4清除 CMOS 的設定值 (12)2.1.5中央處理器電壓設定 (13)2.1.6中央處理器FSB頻率選擇 (13)2.2中央處理器的安裝 (13)2.2.1Slot 1 CPU的安裝方法 (13)2.2.2Socket 370 CPU的安裝方法 (15)2.3安裝系統記憶體 (15)2.3.1安裝168-pin 記憶模組方法 (15)2.3.2移除168-pin 記憶模組方法 (15)2.3.3記憶體的配置結構 (16)2.4輸出入連接埠/外接機殼之連接埠 (16)2.4.1ATX 電源接頭 (17)2.4.2機殼和CPU風扇連接頭 (17)2.4.3 紅外線資料傳輸連接埠 (18)2.4.4連接Creative相容的PCI音效卡的接頭 (19)2.4.5網路喚醒系統功能的接頭 (19)2.4.6磁碟機接頭 (20)2.4.7主要及次要 IDE連接頭 (20)2.4.8PS/2 滑鼠連接埠 (21)2.4.9PS/2 鍵盤連接頭 (21)2.4.10VGA 顯示埠 (21)2.4.11高速串列埠 (21)2.4.12印表機並列埠 (21)2.4.13通用串列匯流排(UBS)連接埠 (22)2.4.14網路連接埠 (22)2.4.15動作/連結顯示燈 (22)2.4.16速度顯示燈 (22)2.4.17Line Out 連接埠 (22)2.4.18Line In 連接埠 (23)2.4.19Microphone In 連接埠 (23)2.4.20Game/MIDI 連接埠 (23)2.4.21ATAPI IDE/SONY Audio 連接埠 (23)2.4.22Mitsumi Audio 連接埠 (23)2.4.23外接機殼之連接埠 (24)第三章、基本輸出入系統設定3.1CMOS 設定程式 (25)3.2標準 CMOS 設定 (26)3.3BIOS 特殊功能設定 (28)3.4晶片組特殊功能設定 (32)3.5週邊整合設定 (34)3.6系統省電管理功能設定 (39)3.7PNP/PCI 組態設定 (42)3.8個人電腦健康狀態 (44)3.9頻率控制 (45)3.10載入基本預設值 (46)3.11載入最佳值 (47)3.12管理者/使用者密碼設定 (47)3.13儲存並跳出設定程式 (47)3.14不儲存並離開設定程式 (47)第四章、驅動程式的安裝4.1Windows 95/98/ME/2000的INF程式更新 (48)4.1.1用於Windows 95/98第一版的安裝方法..484.1.2用於Windows 98SE的安裝方法 (49)4.1.3用於Windows ME/2000的安裝方法 (49)4.2安裝顯示埠的驅動程式(只提供給P3SAE或P3SAE-L )494.2.1用於Windows 95/98/ME的安裝方法 (49)4.2.2用於Windows 2000的安裝方法 (50)4.2.3用於Windows NT 4.0的安裝方法 (50)4.2.4用於Windows 3.11, NT 3.51 & OS/2 (50)4.3安裝音效埠的驅動程式 (50)4.4安裝網路的驅動程式(只提供給P3SAE-L ) (50)4.5安裝Intel防護程式 (51)4.6安裝 Ultra ATA Storage 的驅動程式 (51)4.7安裝硬體偵測的公用程式 (51)附錄 A 使用中止到RAM的功能 (52)第一章、簡介 ( Introduction )產 ( Product Overview )1.1 品簡介歡迎您選擇使用P3SAE 或370SAE 系列主機板. 本主機板是採用Intel公司最新開發之FW82815 或FW82815EP和 FW82801BA晶片組. 經本公司與各種的硬體週邊(如：中央處理器、記憶體、顯示卡、硬碟、光碟機....等)及應用軟體(如： Novell、 MS Office....等),除了符合 Year 2000,並且做各種的相容性測試，及嚴格品質管制，將是您最佳的選擇.本手冊有共分肆個章節。

1/26XC6101_07_XC6111_17 ETR0207_009Preliminary◆CMOS Voltage Detector◆Manual Reset Input ◆Watchdog Functions ◆Built-in Delay Circuit ◆Detect Voltage Range: 1.6~5.0V, ± 2% ◆Reset Function is Selectable V DFL (Low When Detected) V DFH (High When Detected)■GENERAL DESCRIPTION The XC6101~XC6107, XC6111~XC6117 series aregroups of high-precision, low current consumption voltage detectors with manual reset input function and watchdog functions incorporating CMOS process technology. The series consist of a reference voltage source, delay circuit, comparator, and output driver.With the built-in delay circuit, the XC6101 ~ XC6107, XC6111 ~ XC6117 series’ ICs do not require any external components to output signals with release delay time. Moreover, with the manual reset function, reset can be asserted at any time. The ICs produce two types of output; V DFL (low when detected) and V DFH (high when detected).With the XC6101 ~ XC6105, XC6111 ~ XC6115 series’ ICs, the WD pin can be left open if the watchdog function is not used. Whenever the watchdog pin is opened, the internal counter clears before the watchdog timeout occurs. Since the manual reset pin is internally pulled up to the V IN pin voltage level, the ICs can be used with the manual reset pin left unconnected if the pin is unused.The detect voltages are internally fixed 1.6V ~ 5.0V in increments of 100mV, using laser trimming technology. Six watchdog timeout period settings are available in a range from 6.25msec to 1.6sec. Seven release delay time 1 are available in a range from 3.13msec to 1.6sec.■APPLICATIONS●Microprocessor reset circuits●Memory battery backup circuits ●System power-on reset circuits ●Power failure detection■TYPICAL APPLICATION CIRCUIT* Not necessary with CMOS output products.■FEATURESDetect Voltage Range: 1.6V ~ 5.0V, +2% (100mV increments)Hysteresis Range : V DF x 5%, TYP .(XC6101~XC6107)V DF x 0.1%, TYP .(XC6111~XC6117)Operating Voltage Range : 1.0V ~ 6.0V Detect Voltage Temperature Characteristics : +100ppm/O C (TYP .) Output Configuration : N-channel open drain,CMOSWatchdog Pin : Watchdog inputIf watchdog input maintains ‘H’ or ‘L’ within the watchdog timeout period, a reset signal is output to the RESET output pinManual Reset Pin : When driven ‘H’ to ‘L’levelsignal, the MRB pin voltage asserts forced reset on theoutput pin.Release Delay Time : 1.6sec, 400msec, 200msec,100msec, 50msec, 25msec, 3.13msec (TYP .) can be selectable.Watchdog Timeout Period : 1.6sec, 400msec, 200msec,100msec, 50msec,6.25msec (TYP .) can be selectable.■TYPICAL PERFORMANCE CHARACTERISTICS ●Supply Current vs. Input Voltage* ‘x’ represents both ‘0’ and ‘1’. (ex. XC61x1⇒XC6101 and XC6111)2/26XC6101~XC6107, XC6111~XC6117 SeriesPIN NUMBERXC6101, XC6102 XC6103 XC6104, XC6105XC6106, XC6107XC6111, XC6112 XC6113 XC6114, XC6115XC6116, XC6117SOT-25 USP-6C SOT-25 USP-6C SOT-25 USP-6C SOT-25USP-6CPIN NAMEFUNCTION1 4 - - 1 4 1 4 R ESETB Reset Output(V DFL : Low Level When Detected)2 5 2 5 2 5 2 5 V SSGround3 2 3 2 - -4 1 M RB ManualReset 4 1 4 1 4 1 - - WDWatchdog5 6 5 6 5 6 5 6 V IN Power Input - - 1 4 3 2 3 2 RESETReset Output (V DFH: High Level When Detected)■PIN CONFIGURATION SOT-25 (TOP VIEW)MRBV IN WD RESETBV SSMRBWD RESETV SSV IN RESETWD RESETBV SS V IN SOT-25 (TOP VIEW)RESETMRB RESETBV SS V IN SOT-25 (TOP VIEW) ■PIN ASSIGNMENT●SOT-25XC6101, XC6102 SeriesXC6111, XC6112 SeriesSOT-25 (TOP VIEW)XC6103 & XC6113 SeriesXC6104, XC6105 Series XC6114, XC6115 SeriesXC6106, XC6107 Series XC6116, XC6117 Series●USP-6CXC6101, XC6102 Series XC6111, XC6112 SeriesXC6103 & XC6113 SeriesXC6104, XC6105 Series XC6114, XC6115 SeriesXC6106, XC6107 Series XC6116, XC6117 SeriesUSP-6C (BOTTOM VIEW)USP-6C (BOTTOM VIEW)USP-6C (BOTTOM VIEW)USP-6C (BOTTOM VIEW)* The dissipation pad for the USP-6C package should be solder-plated in recommended mount pattern and metal masking so as to enhance mounting strength and heat release. If the pad needs to be connected to other pins, it should be connected to the V SS pin.3/26XC6101 ~ XC6107, XC6111~ XC6117SeriesRESET OUTPUTSERIES WATCHDOGMANUAL RESET V DFL (RESETB)V DFH (RESET)XC6101 XC6111 Available Available CMOS - XC6102XC6112AvailableAvailableN-channel open drain-XC6103 XC6113 Available Available - CMOS XC6104 XC6114 Available Not AvailableCMOS CMOS XC6105 XC6115 Available Not Available N-channel open drain CMOS XC6106 XC6116 Not Available AvailableCMOSCMOS XC6107XC6117Not AvailableAvailableN-channel open drainCMOSDESIGNATORDESCRIPTIONSYMBOLDESCRIPTION0 : V DF x 5% (TYP .) with hysteresis ① Hysteresis Range1 : V DF x 0.1% (TYP .) without hysteresis② Functions and Type of Reset Output1 ~ 7: Watchdog and manual functions, and reset output type as per Selection Guide in the above chartA : 3.13msec (TYP .)B : 25msec (TYP .) C: 50msec (TYP .) D : 100msec (TYP .) E : 200msec (TYP .) F : 400msec (TYP .) ③ Release Delay Time * H : 1.6sec (TYP .)0 : No WD timeout period forXC6106, XC6107, XC6116, XC6117 Series 1: 6.25msec (TYP .) 2 : 50msec (TYP .) 3 : 100msec (TYP .) 4 : 200msec (TYP .) 5 : 400msec (TYP .) ④ Watchdog Timeout Period6: 1.6sec (TYP .) ⑤⑥ Detect Voltage 16 ~ 50: Detect voltageex.) 4.5V: ⑤⇒4, ⑥⇒5M : SOT-25 ⑦ Package E : USP-6C R : Embossed tape, standard feed ⑧ Device OrientationL: Embossed tape, reverse feed* Please set the release delay time shorter than or equal to the watchdog timeout period. ex.) XC6101D427MR or XC6101D327MR■PRODUCT CLASSIFICATION ●Selection Guide ●Ordering Information XC61①②③④⑤⑥⑦⑧4/26XC6101~XC6107, XC6111~XC6117 Series■PACKAGING INFORMATION●SOT-25●USP-6C5/26XC6101 ~ XC6107, XC6111~ XC6117Series④ Represents production lot number0 to 9 and A to Z and inverted 0 to 9 and A to Z repeated. (G, I, J, O, Q, W expected.) * ‘X’ represents both ‘0’ and ‘1’. (ex. XC61X1⇒XC6101 and XC6111)■MARKING RULE●SOT-25①②③④SOT-25 (TOP VIEW)6/26XC6101~XC6107, XC6111~XC6117 Series① Represents product series② Represents release delay time MARK RELEASE DELAY TIME PRODUCT SERIES A 3.13msec XC61XxAxxxxx B 25msec XC61XxBxxxxx C 50msec XC61XxCxxxxx D 100msec XC61XxDxxxxx E 200msec XC61XxExxxxx F 400msec XC61XxFxxxxx H 1.6sec XC61XxHxxxxx③ Represents watchdog timeout period MARK WATCHDOG TIMEOUT PERIOD PRODUCT SERIES 0 XC61X6, XC61X7 series XC61Xxx0xxxx 1 6.25msec XC61Xxx1xxxx 2 50msec XC61Xxx2xxxx 3 100msec XC61Xxx3xxxx 4 200msec XC61Xxx4xxxx 5 400msec XC61Xxx5xxxx 6 1.6sec XC61Xxx6xxxx④⑤ Represents detect voltage MARK④ ⑤DETECT VOLTAGE (V)PRODUCT SERIES3 3 3.3 XC61Xxxx33xx 5 0 5.0XC61Xxxx50xx⑥ Represents production lot number0 to 9 and A to Z repeated. (G, I, J, O, Q, W excepted.)* No character inversion used. ** ‘X’ represents both ‘0’ and ‘1’. (ex. XC61X1⇒XC6101 and XC6111)MARK PRODUCT SERIES MARK PRODUCT SERIES 3 XC6101xxxxxx 8 XC6111xxxxxx 4 XC6102xxxxxx 9 XC6112xxxxxx 5 XC6103xxxxxx A XC6113xxxxxx 6 XC6104xxxxxx B XC6114xxxxxx 7 XC6105xxxxxx C XC6115xxxxxx 3 XC6106xxxxxx 8 XC6116xxxxxx 4 XC6107xxxxxx 9 XC6117xxxxxx■MARKING RULE (Continued)●USP-6CUSP-6C (TOP VIEW)7/26XC6101 ~ XC6107, XC6111~ XC6117Series■BLOCK DIAGRAMS●XC6101, XC6111 Series●XC6102, XC6112 Series●XC6103, XC6113 Series8/26XC6101~XC6107, XC6111~XC6117 Series■BLOCK DIAGRAMS (Continued)●XC6107, XC6117 Series●XC6106, XC6116 Series●XC6105, XC6115 Series●XC6104, XC6114 Series9/26XC6101 ~ XC6107, XC6111~ XC6117SeriesPARAMETERSYMBOL RATINGSUNITSV INV SS -0.3 ~ 7.0 VM RBV SS -0.3 ~ V IN +0.3 VInput Voltage WD V SS -0.3 ~ 7.0V Output Current I OUT 20 mACMOS Output RESETB/RESET V SS -0.3 ~ V IN +0.3Output Voltage N-ch Open Drain Output RESETB V SS -0.3 ~ 7.0VSOT-25 250Power Dissipation USP-6C Pd 100mWOperational Temperature Range Topr -40 ~ +85 OCStorage Temperature Range Tstg -40 ~ +125 OC■ABSOLUTE MAXIMUM RATINGSTa = 25O C10/26XC6101~XC6107, XC6111~XC6117 SeriesNOTE:*1: XC6101~XC6107 (with hysteresis) *2: XC6111~XC6117 (without hysteresis)*3: ‘X’ represents both ‘0’ and ‘1’. (ex. XC61X1⇒XC6101 and XC6111) *4: V DF(T): Setting detect voltage*5: If only “V DF ” is indicated, it represents both V DFL (low when detected) and V DFH (high when detected).PARAMETERSYMBOLCONDITIONSMIN.TYP .MAX. UNITS CIRCUITDetect Voltage V DFL V DFHV DF(T)× 0.98V DF(T) V DF(T)× 1.02 V 1 Hysteresis Range XC6101~XC6107 (*1) V HYS V DF × 0.02V DF × 0.05 V DF× 0.08 V 1Hysteresis Range XC6111~XC6117 (*2) V HYS 0 V DF × 0.001 V DFx 0.01V 1V IN =V DF(T)×0.9V - 5 11 V IN =V DF(T)×1.1V- 10 16 XC61X1/XC61X2/XC61X3XC61X4/XC61X5 (*3)(The MRB & the WD Pin: No connection) V IN =6.0V - 1218 V IN =V DF(T)×0.9V - 4 10 V IN =V DF(T)×1.1V - 8 14 Supply Current I SS XC61X6/XC61X7 (*3)(The MRB Pin: No connection)V IN = 6.0V - 1016 µA 2Operating Voltage V IN 1.0 - 6.0 V 1VIN = 1.0V 0.15 0.5 -V IN =2.0V (V DFL(T)> 2.0V) 2.0 2.5 - V IN =3.0V (V DFL(T) >3.0V) 3.0 3.5 -N-ch.V DS = 0.5V V IN =4.0V (V DFL(T) >4.0V) 3.5 4.0 - 3 V DFL Output Current (RESETB) I RBOUTCMOS,P-chV DS = 0.5V V IN = 6.0V - - 1.1 -0.8 mA 4 N-chV DS = 0.5VV IN =6.0V 4.4 4.9 - 3V IN =1.0V - - 0.08 - 0.02 V IN =2.0V (V DFH(T)> 2.0V)- - 0.50 - 0.30 V IN =3.0V (V DFH(T)>3.0V)- - 0.75 - 0.55V DFHOutput Current (RESET) I ROUT P-ch. V DS = 0.5V V IN =4.0V (V DFH(T)>4.0V)- - 0.95 - 0.75 mA 4Temperature Characteristics △V DF / △Topr ・V DF -40OC < Topr < 85 O C - +100 - ppm / O C12 3.13 5 13 25 3825 50 75 60 100 140 120 200 280 240 400 560Release Delay Time(V DF <1.8V)T DR Time until V IN is increased from1.0V to2.0Vand attains to the release time level,and the Reset output pin inverts.960 1600 2240 ms 5 2 3.13 5 13 25 38 25 50 7560 100 140 120 200 280 240 400 560 Release Delay Time(V DF >1.9V)T DRTime until V IN is increased from1.0V to (V DF x1.1V) and attains to the releasetime level,and the Reset output pin inverts. 960 1600 2240ms 5 Detect Delay Time T DFTime until V IN is decreased from 6.0V to 1.0V and attains to the detect voltage level, and the Reset output pin detectswhile the WD pin left opened.- 3 30 µs 5V DFL /V DFH CMOS Output Leak CurrentI LEAK V IN =6.0V, RESETB=6.0V (V DFL ) V IN =6.0V, RESET=0V (V DFH )- 0.01 - µA 3V DFL N-ch Open DrainOutput Leak CurrentI LEAKV IN =6.0V, RESETB=6.0V-0.010.10µA 3■ELECTRICAL CHARACTERISTICS●XC6101~XC6107, XC6111~XC6117 SeriesTa = 25O CSeriesPARAMETERSYMBOL CONDITIONS MIN.TYP . MAX. UNITS CIRCUIT3.13 6.25 9.38 25 50 7560 100 140 120 200 280240 400 560 Watchdog Timeout Period (V DF <1.8V)T WDTime until V IN increases form1.0V to2.0V andthe Reset output pin is released to go into the detection state. (WD=V SS )960 1600 2240 ms 6 3.13 6.25 9.38 25 50 75 60 100 140 120 200 280240 400 560 Watchdog Timeout Period (V DF >1.9V)T WDTime until V IN increases form1.0V to (V DF x1.1V)and the Reset output pin is released to go into the detection state. (WD=V SS )960 1600 2240 ms 6 WatchdogMinimum Pulse Width T WDIN V IN =6.0V,Apply pulse from 6.0V to 0Vto the WD pin. 300 - - ns 7 Watchdog High Level VoltageV WDH V IN =V DF x 1.1V ~ 6.0V V IN x 0.7- 6 V 7 Watchdog Low Level Voltage V WDL V IN =V DF x 1.1V ~ 6.0V0 - V IN x 0.3 V 7 V IN =6.0V, V WD =6.0V (Avg. when peak )- 12 19Watchdog Input Current I WD V IN =6.0V, V WD =0V (Avg. when peak) - 19 -12 -µA 8 Watchdog Input ResistanceR WDV IN =6.0V, V WD =0V, R WD =V IN / |I WD |315500880k Ω8PARAMETERSYMBOL CONDITIONS MIN.TYP . MAX.UNITS CIRCUITMRBHigh Level VoltageV MRH V IN =V DF x1.1V ~ 6.0V 1.4 - V IN 9MRBLow Level VoltageV MRL V IN =V DF x1.1V ~ 6.0V-0.35 V9MRBPull-up Resistance R MR V IN =6.0V, MRB=0V, R MR =V IN / |I MRB | 1.6 2.4 3.0 M Ω 10 MRB Minimum Pulse Width (*3) XC6101~XC6105 XC6111~XC6115 T MRINV IN =6.0V,Apply pulse from 6.0V to 0V tothe MRB pin 2.8 - -MRB Minimum Pulse Width (*4) XC6106, XC6107 XC6116, XC6117T MRIN V IN =6.0V,Apply pulse from 6.0V to 0V tothe MRB pin1.2 - -µs11●XC6101 ~ XC6103, XC6106 ~ XC6107, XC6111 ~ XC6113, XC6116 ~ XC6117 Series NOTE:*1: V DF(T): Setting detect voltage *2: If only “V DF ” is indicated, it represents both V DFL (low when detected) and V DFH (high when detected). *3: Watchdog function is available. *4: Watchdog function is not available.Ta = 25O CTa = 25O C ■ELECTRICAL CHARACTERISTICS (Continued)●XC6101~XC6105, XC6111~XC6115 Series■OPERATIONAL EXPLANATIONThe XC6101~XC6107, XC6111~XC6117 series compare, using the error amplifier, the voltage of the internal voltage reference source with the voltage divided by R1, R2 and R3 connected to the V IN pin. The resulting output signal from the error amplifier activates the watchdog logic, manual reset logic, delay circuit and the output driver. When the V IN pin voltage gradually falls and finally reaches the detect voltage, the RESETB pin output goes from high to low in the case of the V DFL type ICs, and the RESET pin output goes from low to high in the case of the V DFH type ICs.<RESETB / RESET Pin Output Signal>* V DFL (RESETB) type - output signal: Low when detected.The RESETB pin output goes from high to low whenever the V IN pin voltage falls below the detect voltage, or whenever the MRB pin is driven from high to low. The RESETB pin remains low for the release delay time (T DR) after the V IN pin voltage reaches the release voltage. If neither rising nor falling signals are applied to the WD pin within the watchdog timeout period, the RESETB pin output remains low for the release delay time (T DR), and thereafter the RESET pin outputs high level signal. * V DFH (RESET) type – output signal: High when detected.The RESET pin output goes from low to high whenever the V IN pin voltage falls below the detect voltage, or whenever the MRB pin is driven from high to low. The RESET pin remains high for the release delay time (T DR) after the V IN pin voltage reaches the release voltage. If neither rising nor falling signals are applied to the WD pin within the watchdog timeout period, the V OUT pin output remains high for the release delay time (T DR), and thereafter the RESET pin outputs low level signal.<Hysteresis>When the internal comparator output is high, the NMOS transistor connected in parallel to R3 is turned ON, activating the hysteresis circuit. The difference between the release and detect voltages represents the hysteresis range, as shown by the following calculations:V DF (detect voltage) = (R1+R2+R3) x Vref(R2+R3)V DR (release voltage) = (R1+R2) x Vref(R2)V HYS (hysteresis range)=V DR-V DF (V)V DR > V DF* Detect voltage (V DF) includes conditions of both V DFL (low when detected) and V DFH (high when detected).* Please refer to the block diagrams for R1, R2, R3 and Vref.Hysteresis range is selectable from V DF x 0.05V (XC6101~XC6107) or V DF x 0.001V (XC6111~XC6117).<Watchdog (WD) Pin>The XC6101~XC6107, XC6111~XC6117 series use a watchdog timer to detect malfunction or “runaway” of the microprocessor. If neither rising nor falling signals are applied from the microprocessor within the watchdog timeout period, the RESETB/RESET pin output maintains the detection state for the release delay time (T DR), and thereafter the RESET/RESETB pin output returns to the release state (Please refer to the FUNCTION CHART). The timer in the watchdog is then restarted. Six watchdog timeout period settings are available in 1.6sec, 400msec, 200msec, 100msec, 50msec, 6.25msec.<MRB Pin>Using the MRB pin input, the RESET/RESETB pin signal can be forced to the detection state. When the MRB pin is driven from high to low, the RESETB pin output goes from high to low in the case of the V DFL type ICs, and the RESET pin output goes from low to high in the case of the V DFH type. Even after the MRB pin is driven back high, the RESET/RESETB pin output maintains the detection state for the release delay time (T DR). Since the MRB pin is internally pulled up to the V IN pin voltage level, leave the MRB pin open if unused (Please refer to the FUNCTION CHART). A diode, which is an input protection element, is connected between the MRB pin and V IN pin. Therefore, if the MRB pin is applied voltage that exceeds V IN, the current will flow to V IN through the diode. Please use this IC within the stated maximum ratings (V SS -0.3 ~ V IN+0.3) on the MRB pin.<Release Delay Time>Release delay time (T DR) is the time that elapses from when the V IN pin reaches the release voltage, or when the watchdog timeout period expires with no rising signal applied to the WD pin, until the RESET/RESETB pin output is released from the detection state. Seven release delay time (T DR) watchdog timeout period settings are available in 1.6sec, 400msec, 200msec, 100msec, 50msec, 25msec, 3.13msec.<Detect Delay Time>Detect Delay Time (T DF) is the time that elapses from when the V IN pin voltage falls to the detect voltage until the RESET/ RESETB pin output goes into the detection state.Series■TIMING CHARTS●CMOS Output●T DF (CMOS Output)VINVDFL LevelGNDVIN Level VDFL Level GNDVIN x 0.1V■NOTES ON USE1. Please use this IC within the stated maximum ratings. Operation beyond these limits may cause degrading or permanent damage to the device.2. When a resistor is connected between the V IN pin and the input, the V IN voltage drops while the IC is operating and a malfunction may occur as a result of the IC’s through current. For the CMOS output products, the V IN voltage drops while the IC is operating and malfunction may occur as a result of the IC’s output current. Please be careful with using the XC6111~XC6117 series (without hysteresis).3. In order to stabilize the IC’s operations, please ensure that the V IN pin’s input frequency’s rise and fall times are more than 1 µ sec/V.4. Noise at the power supply may cause a malfunction of the watchdog operation or the circuit. In such case, please strength the line between V IN and the GND pin and connect about 0.22µF of a capacitor between the V IN pin and the GND pin.5. Protecting against a malfunction while the watchdog time out period, an ignoring time (no reaction time) occurs to the rise and fall times. Referring to the figure below, the ignoring time (no reaction time) lasts for 900µsec at maximum.GNDGNDGNDVIN Pin Wave FormWD Pin Wave FormRESETB Pin Wave Form (VDFL)SeriesPIN NAMELOGIC CONDITIONSH V IN >V DF +V HYS V IN L V IN <V DF H MRB>1.40V MRBL MRB<0.35V H When keeping W D >V WDH more than T WD L When keeping W D <V WDL more than T WD L → H V WDL → V WDH , T WDIN >300nsec WDH → L V WDH →V WDH , T WDIN >300nsecV IN MRB WD RESETB (*2) H HH LRepeat detect and release (H →L →H)H OpenH L → HH H or Open H → L H HLL *1 LV IN MRB WD RESETB (*3) H HH LRepeat detect and release (L →H →L)H OpenH L → HH H or Open H → L L HLL *1 HV IN WD RESETB (*2) RESET (*3) H HH L Repeat detect and release (H →L →H)Repeat detect and release (L →H →L)H OpenH L → HH H → L H L HL*1 L HV IN MRB RESETB (*2)RESET (*3)H H or Open H LH LL L H■PIN LOGIC CONDITIONSNOTE:*1: If only “V DF ” is indicated, it represents both V DFL (low when detected) and V DFH (high when detected).*2: For the details of each parameter, please see the electrical characteristics. V DF : Detect VoltageV HYS : Hysteresis RangeV WDH : WD High Level Voltage V WDL: WD Low Level Voltage T WDIN : WD Pulse Width T WD : WD Timeout Period■FUNCTION CHART●XC6103/XC61113 Series●XC6104/XC61114, XC6105/XC6115 Series●XC6106/XC61116, XC6107/XC6117 Series●XC6101/XC61111, XC6102/6112 Series*1: Including all logic of WD (WD=H, L, L →H, H →L, OPEN). *2: When the RESETB is High, the circuit is in the release state. When the RESETB is Low, the circuit is in the detection state. *3: When the RESET is High, the circuit is in the release state. When the RESET is Low, the circuit is in the detection state.■TEST CIRCUITSCircuit 1Circuit 2Circuit 3Circuit 4Series ■TEST CIRCUITS (Continued)Circuit 5Circuit 6Circuit 7■TEST CIRCUITS (Continued)Circuit 8Circuit 9Circuit 10Circuit 11Series■TYPICAL PERFORMANCE CHARACTERISTICS(1.1) Supply Current vs. Input Voltage(1.2) Supply Current vs. Input Voltage■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(2) Detect, Release Voltage vs. Ambient Temperature(1.2) Supply Current vs. Input Voltage (Continued)Series■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (3-1) Output Voltage vs. Input Voltage (V DFL ) (3.1) Detect, Release Voltage vs. Input Voltage (V DFL )(3.2) Detect, Release Voltage vs. Input Voltage (V DFH )■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(4) N-ch Driver Output Current vs. V DSSeries(6) P-ch Driver Output Current vs. Input Voltage 1■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(8) Release Delay Time vs. Ambient Temperature(7) P-ch Driver Output Current vs. Input Voltage 2■TYPICAL PERFORMANCE CHARACTERISTICS (Continued) (10) Release Delay Time vs. Input Voltage(11) Watchdog Timeout Period vs. Input VoltageSeries■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(14) MRB Low Level Voltage vs. Ambient Temperature(15) MRB High Level Voltage vs. Ambient Temperature* ‘X’ represents both ‘0’ and ‘1’. (ex. XC61X1⇒XC6101 and XC6111)。

Key Features:Power Rating:2600W,5200W,6500W,10400W,14500W, 15600WVoltage range: 1-80V/ 2.5-500VCurrent range: Up to 1000ACC, CR, CVMaster/Slave paralleling control mode, allow synchronous load control under static and dynamic loading modeDynamic loading: Up to 20KHzOnly need 1V to draw rated currentProgrammable slew rate, up to 41A/uS Measurement: Voltage / CurrentPower/ ResistanceLarge LED/LCD displayExternal loading waveform simulationShort circuit simulation and shortcircuit current measurementFull protection: OPreverse protectionVersatile remote controllerGPIB& RS-232C; RS-485 interfaceSurge load capabilityBattery discharge timerand therefore can test if the battery charger has correct charging current corresponding to its own out-put, or more precisely, the battery voltage. If the UUT is battery, the electronic load is able to simulate the behavior of the device that uses the battery. For most of the electronic and electrical devices, their power consumption patterns are more likely constant power devices.Consequently, CP mode simulation will be essential for a battery discharge load.2. LOW VOLTAGE OPERATING CHARACTERISTICSdirectly.1000A at only 1V input.3. MEASUREMENTSChroma 63200 series are built in the15-bits precision A/D converter, thus can achieve 0.05%F .S., 0.1%F .S. and 0.3%F .S. accuracy for voltage,current and power measurement respectively. And they can be shown simultaneously on three big LED displays for user's convenience. In additional to standard measurements, they also provide voltage and current monitor outputs, which are useful when user needs to monitor the voltage and current waveform via scope.4. DYNAMIC LOADING AND CONTROLparameters of the 63200 load modules. The programmable slew rate makes the simulation of transient load change demanded by the require-ment of real life application possible. The internal waveform generator of 63200 is capable of producing maximum slew rate at 25A/uS (63208),and dynamic cycling up to 20KHz. Its dedicated remote load senses and controls circuit guarantee the minimum waveform distortion during continuous load changes.5. MASTER / SLAVE PARALLEL CONTROLWhen higher power is required,it is common to parallel two elec-tronic loads together to draw higher current. 63200 series high power loads have smart Master / Slave control mode. When the loads are set to Master / Slave mode, users can program the load-ing (CC mode only) on master unit. The loading current values ofthe slave units will be calculated and downloaded by master unit automatically. In short, unlike the traditional design, users may consider several load units that work under Master / Slave mode as a single load unit. It simplifies the user operation dramatically.SIMULATIONThe CC and CR mode loading simula-tion is helpful to test whether the output voltage of the UUT remains stable or regulated under different loading cur-rent or resistance conditions. For bat-tery chargers, CV mode may help tochange the output voltage of a charger 1. APPLICATION SPECIFIC LOAD SIMULATIONChroma electronic loads 63200 series provide constant current, constant resistance, constant voltage and constant power modes for various application requirements.V I V I V I VIConstant current Constant resistance Constant voltage Constant power8. SURGE LOAD CAPABILITYChroma’s 63200 Series D C Loads provide a unique surge load simulation capability which allows users to overdrive the loads up to 2.7 times their rated power for short periods. This feature is ideal when the average power require by the UUT is low compared to short-term peak power demands. Plasma Display Panel (PDPs) testing is one typical applica-tion, others include battery 3C discharge, breaker & fuse over rating (300% to 1000%) tests, car engine startup simu-lation and DC motor startup simulation.The amount of surge loading available using the 63200 loads is related to the initial loading conditions. Figures 1 and 2 show the relationship of initial state (Load_Low under D ynamic mode) and the maximum acceptable overdrive power. Under this operation, the load will display an Over Power Protection Alarm (OPP) and will disable the load cur-rent if the user violates the maximum surge load capability showed in the figures.Note 1 :The Initial state under Static Mode should last at least 1 second. Note 2 :This surge load capability will be regulated by the temperature de-rat-ing characteristics. (Refer to Note 1 in Specifications)Note 3 :Examples below assume the use of the Model 63201 load with a con-tinuous rating of 2600W/300A/1-80VDC9. TIMER FUNCTION FOR BATTERY DISCHARGE TESTINGThe 63200 Loads include unique timing & measurement function allowing for precision time settings and measure-ments in the range of 1s to 99999s. This feature allows users to set a final voltage & timeout value for battery dis-charge testing and similar applications.For Example, Figure 3 below shows that the 63200’s internal timer can be initiated automatically when the battery voltage falls below a preset value. The timer will continue countinguntil the second preset voltage value is reached.Example 1: STATIC LOADINGThe Model 63201 can be overdriven to approximately 5200W (200% of its rated con-tinuous power rating) for 6.0 ms seconds when the starting power is 650W (25% of its rated power). This is represented by DOT on the blue curve in Figure 1.Example 2: DYNAMIC LOADINGThe Model 63201 is capable of a zero – to- 6500W (250%) pulse at a duty cycle of 5%. This is represented by the DOT on the purple curve in Figure 2.7. SHORT CIRCUIT SIMULATION63200 series electronic loads can also simulate short circuit condition. Owing to this capability, it can short DC power source or any power sup-plies that have built in current limit function, and measure their short circuit currents. So that users can verify if the UUT current limit is functional.APPLICATIONSof testing all sorts of DC output power supplies directly or via rectifier, they can also be used to test the AC output power supplies.CC & CR ModeA/ D Power supplyD/ D ConverterBattery chargerUPS/AVR4. SYSTEM INTEGRATIONChroma 63200 series electronic loads provide GPIB, RS-232C and RS-485 PC controllable interfaces. The external waveform simulation and voltage / current monitoring capability make Chroma 63200 family ideal for automatic system integration.Discharge by CR modeDischarge by CP mode1. Power Switch2. LED Display:Voltage read back.3. LED Display:Current/ ohm read back.4. LED Display:Power read back.5. LCD Display:For setting and editing.6. Rotary knob:T o adjust the loading and parameter setting.7. Numeric key:For data setting.8. Function key:T o select load mode, control mode, and define thereading specification.9. System key:For system config and data store, recall.10. Load terminal11. Voltage sense terminal12. RS-485 connector13. GPIB connector14. RS-232C connector15. Voltage monitor output:Analog output which indicates the voltage waveform.16. Current monitor output:Analog output which indicates the current waveform.17. External V reference:External programming voltage input.246351Model: 63203, 63204PANEL DESCRIPTIONModel 63208 / 63209 / 63210Model 63206 / 63207Model 63203 / 63204Model63201 / 63202Model 63205SPECIFICATIONSSPECIFICATIONSSe riesAll specifications are subject to change without notice.Note*1: The power rating specifications at ambient temperature=25. And see the diagram below for power derating. (Derate power by 1.53perfrom 25to 40)Note*2: The Vin is greater than min. operating voltage of each model.Note*3: The Vin is greater than 7V of each model.Note*4: Setting error will be 1% for R<0.005Ωat CRL range.SPECIFICATIONSV-I Curve:Model 63201/ 63203/ 63205/ 63206/ 63207/ 63208/ 63209Low Voltage Operating:Low Voltage & V-I Curve Operating Characteristics (Typical) of 63200 SeriesNote: All specifications are measured at load input terminals. (Ambient temperature of +25)Distributed by:Worldwide Distribution and Service Network63200-200607-PDFCHINACHROMA ELECTRONICS (SHENZHEN) CO., LTD.8F , No.4, Nanyou Tian An Industrial Estate, Shenzhen,China PC: 518054T el: +86-755-2664-4598Fax: +86-755-2641-9620EUROPECHROMA ATE EUROPE B.V.Max Planckstraat 4, 6716 BE Ede, The Netherlands T el: +31-318-648282Fax: +31-318-648288U.S.A.CHROMA ATE INC. (U.S.A.)7 Chrysler Irvine, CA 92618T el: +1-949-421-0355Fax: +1-949-421-0353T oll Free: +1-800-478-2026CHROMA ATE INC.HEADQUARTERS66, Hwa-Y a 1st Rd., Hwa-Y a T echnology Park, Kuei-Shan Hsiang, Taoyuan Hsien 333,TaiwanT el: +886-3-327-9999 Fax: +886-3-327-8898E-mail:*****************.twDeveloped and Manufactured by :63207 : DC Electronic Load 10.4KW/ 300A/ 80V 63208 : DC Electronic Load 15.6KW/ 600A/ 80V 63209 : DC Electronic Load 15.6KW/ 1000A/ 80V 63210 : DC Electronic Load 14.5KW/ 150A/ 500V A600009 : GPIB Cable (200 cm)A600010 : GPIB Cable (60 cm)A632001 :Remote Controller63201 : DC Electronic Load 2.6KW/ 300A/ 80V 63202 : DC Electronic Load 2.6KW/ 50A/ 500V 63203 : DC Electronic Load 5.2KW/ 600A/ 80V 63204 : DC Electronic Load 5.2KW/ 100A/ 500V 63205 : DC Electronic Load 6.5KW/ 180A/ 80V 63206 : DC Electronic Load 10.4KW/ 600A/ 80VA632001ORDERING INFORMATION15A 30A 45A 60A 75A 90A 105A 120A 135A 150A15A30A 45A60A 75A 90A 105A 120A 135A 150A。

CAPACITANCE CHANGE .032" [0.813] diameter (No. 20 AWG) copper-clad steel leadsexcept that .025" [.635] diameter (No. 22 AWG) leads will besupplied on .153" [3.886] and .185" [4.699] diameter units.Document Number: 42024 For technical questions, contact spresale@Document Number: 42024For technical questions, contact spresale@Document Number: 42024For technical questions, contact spresale@Document Number: 42024For technical questions, contact spresale@Legal Disclaimer NoticeVishay Document Number: NoticeSpecifications of the products displayed herein are subject to change without notice. Vishay Intertechnology, Inc., or anyone on its behalf, assumes no responsibility or liability for any errors or inaccuracies.Information contained herein is intended to provide a product description only. No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document. Except as provided in Vishay's terms and conditions of sale for such products, Vishay assumes no liability whatsoever, and disclaims any express or implied warranty, relating to sale and/or use of Vishay products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright, or other intellectual property right. The products shown herein are not designed for use in medical, life-saving, or life-sustaining applications. Customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Vishay for any damages resulting from such improper use or sale.。

250 kSPS 、六通道、同步采样、双极性16/14/12-位 ADCAD7656/AD7657/AD7658Rev. D Information furnished by Analog Devices is believed to be accurate and reliable. However , no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Speci cations subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. T rademarks and registered trademarks are the property of their respective owners.One Technology Way, P.O.Box 9106, Norwood, MA 02062-9106, U.S.A.Tel: 781.329.4700 Fax: 781.461.3113 2006–2012 Analog Devices, Inc. All rights reserved.功能框图V SSDGNDV DDREFCONVST ACONVST B CONVST C OUTPUT DRIVERSOUTPUT DRIVERSOUTPUT DRIVERSOUTPUT DRIVERSCONTROL LOGICBUFBUFBUFAGNDT/HT/H T/H T/HT/HT/HCLK OSCAV CCDV CCV1V2V3V4V5V6SER/PAR CSV DRIVE STBYDOUT ADOUT BDOUT C SCLKRD WRDATA/CONTROL LINES 05020-001AD7656/AD7657/AD765816-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR16-/14-/12-BIT SAR图1.-1受美国专利第6,731,232号保护。

LA6324N LA6324NMOverviewThe LA6324 consists of four independent, high-performance, internally phase compensated operational amplifiers that are designed to operate from a single power supply over a wide range of voltages. These four operational amplifiers are packaged in a single package. As in case of conventional general-purpose operational amplifiers, operation from dual power supplies is also possible and the power dissipation is low. It can be applied to various uses in commercial and industrial equipment including all types of transducer amplifiers and DC amplifiers.Features• No phase compensation required • Wide operating voltage range:3.0 V to 30.0 V (single supply) ±1.5 V to ±15.0 V (dual supplies) • Highly resistant to dielectric breakdown• Input voltag range includes the neighborhood of GND level and output voltage range V OUT is from 0 to V CC –1.5 V. • Small current dissipation:I CC = 0.6 mA typ/V CC = + 5 V, R L = ∞SpeciticationsAbsolute Maximum Ratings at Ta = 25 °CParameterSymbol ConditionsRatingsUnit Maximum Supply voltage V CC max 32 V Differential input voltage V ID 32V Maximum input voltage V IN max-0.3 to +32V LA6324N 720 mW Allowable power dissipationPd maxLA6324NM330 mW Operating temperature Topr -30 to +85 °C Storage temperatureTstg-55 to +125°CMonolithic Linear ICHigh-PerformanceQuad Operational AmplifierOperating Characteristics at Ta = 25 °C, V CC = +5 VRatingsParameterSymbol ConditionsTest circuitmintypmaxUnit Input offset voltage V IO1 ±2 ±7 mV Input offset current I IO I IN (+) / I IN (–) 2 ±5 ±50 nA Input bias currentI B I IN (+) / I IN (–) 3 45 250 nA Common-mode input voltage range V ICM 4 0 V CC –1.5V Common-mode rejection ratio CMR4 65 80 dB Voltage gain VG V CC = 15 V, R L ≥ 2 k Ω 5 25 100V/mV Output voltage range V OUT 0 V CC –1.5V Supply voltage rejection ratio SVR6 65 100 dB Channel separation CS f = 1 k to 20 kHz7 120 dB I CC8 0.6 2mA Current drainI CC V CC = 30 V8 1.5 3 mA Output current (Source) I O source V IN + = 1 V, V IN – = 0 V 9 20 40 mA Output current (Sink) I O sinkV IN + = 0 V, V IN – = 1 V101020mAPackage Dimensionsunit : mmunit : mm3003B [LA6324N]3034B [LA6324NM]Equivalent CircuitPin Assignment(1 unit)(LA6324N, 6324NM)V OUT1V OUT2V IN1-V IN2-V IN1+V IN2+V CC OUT4OUT3Top viewIN4-IN3-IN4+IN3+Test Circuit1. Input offset voltage V IO2. Input offset current I IO3. Input bias current I B4. Common-mode rejection ratio CMR5. Voltage gain VG Common-mode input voltage range V ICM6. Supply voltage rejection ratio SVR7. Channel separation CSF4F2F3V F8V F6V F10V F12V IO =V F1F1CMR = 20 log (E C1 - E C2) (1+R2/R1)V F5 - V F6SVR (+) = 20 log (1+R2/R1) (V CC1 - V CC2)V F9 - V F10SVR (-) = 20 log (1+R2/R1) (V EE1 - V EE2)V F11 - V F12SW: a CS (A B) = 20 log R2 V OA R1 V OB SW: b CS (B A) = 20 logThese apply also to other channels.R2 V OB R1 V OA VG =(E K1 - E K2) (1+R2/R1)V F8 - V F7I IO =V F2 - V F1I B =V F4 - V F32R(1+R2/R1)8. C urrent drain I CC 9. Output current I O source10. Output current I O sinkV OV O+1VI - V C u r r e n t d r a i n , I C C - m ASupply voltage, V CC - VI (source) - Ta O ut p u t c u r r e n t , I O (s o u r c e ) - mAVG - V V o l t a g e g a i n , V G - d BSupply voltage, V CC - VI - V I n p u t b i a s c u r r e n t , I B - n ASupply voltage, V CC - VV - fO u t p u t v o l t a g e a m p l i t u d e , V O U T - V p -pFrequency, f - Hz VG - fV o l t a g e g a i n , V G - d BFrequency, f - HzSample Application CircuitsNoninverting DC amplifier Rectangular wave oscillator Inverting AC amplifierPd max - T aA l l o w a b l e p o w e r d i s s i p a t i o n , P d m a x - m WPd max - TaA l l o w a b l e p o w e r d i s s i p a t i o n , P d m a x - m W。

For free samples & the latest literature: , or phone 1-800-998-8800.For small orders, phone 1-800-835-8769.General DescriptionThe MAX6326/MAX6327/MAX6328/MAX6346/MAX6347/MAX6348 microprocessor (µP) supervisory circuits moni-tor the power supplies in µP and digital systems. These devices provide excellent circuit reliability and low cost by eliminating external components and adjustments when used with 2.5V, 3V, 3.3V, and 5V powered circuits.These circuits perform a single function: they assert a reset signal whenever the V CC supply voltage declines below a preset threshold, keeping it asserted for at least 100ms after V CC has risen above the reset threshold.The only difference between the devices is their output.The MAX6326/MAX6346 (push-pull) and MAX6328/MAX6348 (open-drain) have an active-low reset output.The MAX6327/MAX6347 have an active-high push-pull reset output. All of these parts are guaranteed to be in the correct state for V CC down to 1V. The reset compara-tor is designed to ignore fast transients on V CC . Reset thresholds are factory-trimmable between 2.2V and 4.63V, in approximately 100mV increments. Twenty-one standard versions are available. Contact the factory for availability of nonstandard versions.Ultra-low supply currents (1µA max for the MAX6326/MAX6327/MAX6328) make these parts ideal for use in portable equipment. All six devices are available in space-saving SOT23 and SC70 packages.ApplicationsComputers Intelligent Instruments Controllers AutomotiveCritical µP and µC Portable/Battery-Powered Power MonitoringEquipmentFeatureso Ultra-Low 1µA (max) Supply Current (MAX6326/MAX6327/MAX6328)o Precision Monitoring of 2.5V, 3V, 3.3V, and 5V Power-Supply Voltageso Reset Thresholds Available from 2.2V to 4.63V o Fully Specified Over Temperatureo 100ms (min) Power-On Reset Pulse Width o Low Costo Available in Three Versions: Push-Pull RESET ,Push-Pull RESET, and Open-Drain RESET o Power-Supply Transient Immunity o No External Componentso 3-Pin SC70/SOT23 Packageso Pin Compatible with MAX803/MAX809/MAX810MAX6326/MAX6327/MAX6328/MAX6346/MAX6347/MAX63483-Pin, Ultra-Low-Power SC70/SOTµP Reset Circuits________________________________________________________________Maxim Integrated Products 1Pin Configuration19-1294; Rev 3; 1/00†The MAX6326/MAX6327/MAX6328/MAX6346/MAX6347/MAX6348 are available in factory-set V CC reset thresholds from 2.2V to 4.63V, in approximately 0.1V increments. Choose the desired reset-threshold suffix from Table 1 and insert it in the blank spaces following “R.”There are 21 standard versions witha required order increment of 2500 pieces. Sample stock is gen-erally held on the standard versions only (see the SelectorGuide). Required order increment is 10,000 pieces for nonstan-dard versions (Table 2). Contact factory for availability. All devices available in tape-and-reel only.Selector Guide appears at end of data sheet.M A X 6326/M A X 6327/M A X 6328/M A X 6346/M A X 6347/M A X 63483-Pin, Ultra-Low-Power SC70/SOT µP Reset Circuits 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = full range, T A = -40°C to +85°C, unless otherwise noted. Typical values are at T A = +25°C and V CC = 3V.) (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 Voltage (with respect to GND)V CC ...........................................................................-0.3V to +6V RESET, RESET (push-pull).........................-0.3V to (V CC + 0.3V)RESET (open drain)..................................................-0.3V to +6V Input Current (V CC ).............................................................20mA Output Current (RESET, RESET ).........................................20mA Rate of Rise (V CC )...........................................................100V/µsContinuous Power Dissipation (T A = +70°C)3-Pin SC70 (derate 2.7mW/°C above +70°C)...............174mW 3-Pin SOT23 (derate 4mW/°C above +70°C)................320mW Operating Temperature Range ...........................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CNote 1:Overtemperature limits are guaranteed by design and not production tested.MAX6326/MAX6327/MAX6328/MAX6346/MAX6347/MAX63483-Pin, Ultra-Low-Power SC70/SOTµP Reset Circuits_______________________________________________________________________________________3__________________________________________Typical Operating Characteristics(T A = +25°C, unless otherwise noted.)00.30.20.10.40.50.60.70.80.91.0-400-2020406080SUPPLY CURRENT vs. TEMPERATURE TEMPERATURE (°C)S U P P L Y C U R R E N T(µA)050100150200-400-2020406080POWER-DOWN RESET DELAY vs. TEMPERATURE TEMPERATURE (°C)R E S E T D E L A Y(µs)130150140160170180190200210-400-2020406080POWER-UP RESET TIMEOUT vs. TEMPERATURE M A X6326-03TEMPERATURE (°C)P O W E R-U P R E S E T T I M E O U T(m s)500011001000MAXIMUM TRANSIENT DURATION vs. RESET THRESHOLD OVERDRIVE (SC70)100300400200M A X6326-04RESET 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)10______________________________________________________________Pin DescriptionM A X 6326/M A X 6327/M A X 6328/M A X 6346/M A X 6347/M A X 63483-Pin, Ultra-Low-Power SC70/SOT µP Reset Circuits 4___________________________________________________________________________________________________Applications InformationInterfacing to µPs with Bidirectional Reset PinsSince the RESET output on the MAX6328/MAX6348 is open drain, these devices interface easily with micro-processors (µPs) that have bidirectional reset pins,such as the Motorola 68HC11. Connecting the µP supervisor’s RESET output directly to the microcon-troller’s (µC’s) RESET pin with a single pull-up resistor allows either device to assert reset (Figure 1).Negative-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 V CC transients (glitches).The Typical Operating Characteristics show the Maxi-mum Transient Duration vs. Reset Threshold Overdrive graph, for which reset pulses are not generated. The graph shows the maximum pulse width that a negative-going V CC transient may typically have when issuing a reset signal. As the amplitude of the transient increas-es, the maximum allowable pulse width decreases.Figure 1. Interfacing to µPs with Bidirectional Reset PinsTable 1. Factory-Trimmed Reset Thresholds ‡‡Factory-trimmed reset thresholds are available in approximately 100mV increments with a 1.5% room-temperature variance.MAX6326/MAX6327/MAX6328/MAX6346/MAX6347/MAX63483-Pin, Ultra-Low-Power SC70/SOTµP Reset Circuits_______________________________________________________________________________________5Table 1. Factory-Trimmed Reset Thresholds‡(continued)‡Factory-trimmed reset thresholds are available in approximately 100mV increments with a 1.5% room-temperature variance.Table 2. Device Marking Codes and Minimum Order IncrementsM A X 6326/M A X 6327/M A X 6328/M A X 6346/M A X 6347/M A X 63483-Pin, Ultra-Low-Power SC70/SOT µP Reset Circuits 6__________________________________________________________________________________________________________Chip InformationTRANSISTOR COUNT: 419Table 2. Device Marking Codes and Minimum Order Increments (continued)Selector Guide(standard versions*)*Sample stock is generally held on all standard versions.________________________________________________________Package InformationMAX6326/MAX6327/MAX6328/MAX6346/MAX6347/MAX63483-Pin, Ultra-Low-Power SC70/SOTµP Reset Circuits_______________________________________________________________________________________7M A X 6326/M A X 6327/M A X 6328/M A X 6346/M A X 6347/M A X 63483-Pin, Ultra-Low-Power SC70/SOT µP Reset Circuits 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©2000 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.Package Information (continued)。

PROFIBUS_DP_Communication For 9400 servo driveConfiguration of the host 上位PLC组态:Configuration of the host 上位PLC组态:Configuration of the host 上位PLC组态:E94AYCPM通信模板外形图说明说明说明位置位置位置颜色条件通信模板的外部供电端子设计设计：：可插拔螺钉连接端子可插拔螺钉连接端子，，两极PROFIBUS 连接端子设计设计：：PROFIBUS 标准9针小D 插座节点地址硬件设置开关地址设置见下页说明绿色红色绿色红色红色闪烁闪烁常亮常亮常亮常亮通信模板已经供电通信模板已经供电，，但是与驱动器尚未建立连接但是与驱动器尚未建立连接（（例如例如，，可能驱动器尚未供电可能驱动器尚未供电，，驱动器正在初始化或没有插在驱动器上器上）。

）。

通信模板已经供电通信模板已经供电，，并与驱动器已建立连接并与驱动器已建立连接。

出现通信错误出现通信错误。

通过通信模板的通信已建立通过通信模板的通信已建立，，PROFIBUS 通信有效通信有效。

总线监视已经作出响应总线监视已经作出响应。

通信模板不被驱动器接受通信模板不被驱动器接受（（参看驱动器操作说明书的注释）。

Configuration of the host 上位PLC 组态:说明小D 插座外观图名称针数据线B （接收数据/发送数据 ＋）数据线A （接收数据/发送数据发送数据－）－）数据参考位 （5V 地电位地电位））5V DC / 30 ma （总线终端总线终端））请求发送请求发送（（接收数据 / 发送数据发送数据，， 非差分信号非差分信号））Configuration of the host 上位PLC 组态:PROFIBUS 9针小D 插座插座（（X201)针脚信号分配Cabinet with 82EV为了寻址的目的为了寻址的目的，，每一个PROFIBUS 站必须给出一个唯一的地址唯一的地址，，有效的地址范围有效的地址范围：：1 (126)模板的地址能够通过面板上硬件开关来自由设置模板的地址能够通过面板上硬件开关来自由设置。