JEDEC JESD8-29-2016 0 6 V Low Voltage Swing Terminated Logic (LVSTL06).pdf

1、JEDEC STANDARD 0.6 V Low Voltage Swing Terminated Logic (LVSTL06) JESD8-29 DECEMBER 2016 JEDEC SOLID STATE TECHNOLOGY ASSOCIATION NOTICE JEDEC standards and publications contain material that has been prepared, reviewed, and approved through the JEDEC Board of Directors level and subsequently review

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8、l the resulting material. PRICE: Contact JEDEC Printed in the U.S.A. All rights reserved PLEASE! DONT VIOLATE THE LAW! This document is copyrighted by JEDEC and may not be reproduced without permission. For information, contact: JEDEC Solid State Technology Association 3103 North 10th Street Suite 2

9、40 South Arlington, VA 22201-2107 or refer to www.jedec.org under Standards-Documents/Copyright Information. JEDEC Standard No. 8-29 Page 1 0.6 V LOW VOLTAGE SWING TERMINATED LOGIC (LVSTL06) (From JEDEC Board Ballot JCB-16-37, formulated under the cognizance of the JC-16 Committee on Interface Techn

10、ology. 1 Scope This standard defines power supply voltage range, dc interface, switching parameter and overshoot/undershoot for high speed low voltage swing terminated NMOS driver family digital circuits with 0.6V supply. The specifications in this standard represent a minimum set of interface speci

11、fications for low voltage terminated circuits. The purpose of this standard is to provide a standard of specification for uniformity, multiplicity of sources, elimination of confusion, and ease of device specification and design by users. Class 1 describes low VOH (Nominal VOH = VDDQ*0.5) level term

12、inated electrical characteristics. Class 2 describes high VOH (Nominal VOH = VDDQ*0.6) level terminated electrical characteristics. 2 LVSTL system definition LVSTL (Low Voltage Swing Terminated Logic) Driver and ODT System LVSTL I/O cell is comprised of pull-up, pull-down driver and a terminator. Th

13、e basic cell is shown in Figure 1. Figure 1 LVSTL I/O Cell JEDEC Standard No. 8-29 Page 2 2.1 Standard specifications All voltages are referenced to ground except where noted. 2.2 Recommended DC Operating conditions Table 1 Recommended DC operating conditions Min Nom Max Unit VDDQ 0.57 0.6 0.65 V I/

14、O Buffer Power 2.3 Pull Up Driver Characteristics for class 1 and class 2 Table 2 Pull-Up Characteristics VOHPU,nom VOH(mV) VOHPUUnit Min Nom Max Min Nom Max Class 1 VDDQ*0.5 270 300 330 0.9 1 1.1 VOH, nom Class 2 VDDQ*0.6 325 360 395 0.9 1 1.1 VOH, nom 2.4 Data Input Characteristics for class 1 and

15、 class 2 Input levels are same for both class 1 and class 2 Figure 2 DQ Receiver (Rx) mask JEDEC Standard No. 8-29 Page 3 2.4 Data Input Characteristics for class 1 and class 2 (contd) Figure 3 DQ TdIPW definition (for each input pulse) Vcent_DQRx Mask Rx Mask Rx Mask VdIVW_totalVIHL_AC(min)/2VIHL_A

16、C(min)/2Figure 4 DQ VIHL_AC definition (for each input pulse) Table 3 DQ Input Voltage Symbol Parameter Range 1 Range 2 Unit Min max Min max VdIVW_total Rx Mask voltage - p-p total - 140 - 120 mV VIHL_AC DQ AC input pulse amplitude pk-pk 180 - 170 - mV NOTE Each device specification defines Range 1

17、and Range 2 adaptation. Please refer to the device specification. JEDEC Standard No. 8-29 Page 4 2.5 CA Input Characteristics for class 1 and class 2 Input levels are same for both class 1 and class 2. Figure 5 CA Receiver(Rx) mask VcIVWFigure 6 CA TcIPW definition (for each input pulse) Figure 7 CA

18、 VIHL_AC definition (for each input pulse) JEDEC Standard No. 8-29 Page 5 2.5 CA Input Characteristics for class 1 and class 2 (contd) Table 4 CMD/ADR, CS voltage definitions Symbol Parameter Range 1 Range 2 Range 3 Unitmin max min max min maxVcIVW Rx Mask voltage - p-p - 175 - 155 - 145 mV VIHL_AC

19、CA AC input pulse amplitude pk-pk 210 - 190 - 180 - mV NOTE Each device specification defines Range 1, Range 2, and Range 3 adaptations. Please refer to the device specification. 2.6 DQS Differential Input Cross Point Voltage Figure 8 DQS input Crosspoint voltage (Vix) Table 5 DQS input voltage cros

20、spoint(Vix) ratio Parameter Symbol Min Max Units NotesDQS Differential input crosspoint voltage ratio Vix_DQS_ratio - 20 % 1,2 NOTE 1 The Vix voltage is referenced to Vswing/2(avg) = 0.5(VDQS_t + VDQS_c) where the average is over TBD1UI. NOTE 2 The ratio of the Vix pk voltage divided by Vdiff_DQS :

21、Vix_DQS_Ratio = 100* (Vix_DQS/Vdiff DQS pkpk) where VdiffDQS pk-pk = 2*|VDQS_t - VDQS_c| 1At time of publication the formulating committee has not defined the value. JEDEC Standard No. 8-29 Page 6 2.7 Clock Differential Input Cross Point Voltage Figure 9 CK input Crosspoint voltage (Vix) Table 6 CK

22、input voltage crosspoint (Vix) ratio Parameter Symbol Min Max Units NotesClock Differential input crosspoint voltage ratio Vix_CK_ratio - 25 % 1,2 NOTE 1 The Vix voltage is referenced to Vswing/2(avg)= 0.5(VCK_t + VCK_c) where the average is over TBD2UI. NOTE 2 The ratio of the Vix pk voltage divide

23、d by Vdiff_CK : Vix_CK_Ratio = 100* (Vix_CK/Vdiff CK pk-pk) where VdiffCK pk-pk = 2*|VCK_t - VCK_c| 2.8 Internal Reference Voltage Ranges LVSTL interface use internal generated Reference Voltage (Vref) for single ended signals. Vref Range should be min 15% of VDDQ to 62.9% of VDDQ. Internal Vref sho

24、uld be adjusted to suitable value. At time of publication the formulating committee has not defined the value. 2At time of publication the formulating committee has not defined the value. JEDEC Standard No. 8-29 Page 7 2.9 Overshoot and Undershoot Table 7 AC Overshoot/Undershoot Specification Parame

25、ter Units Maximum peak amplitude allowed for overshoot area. (See Figure 10) Max 0.3 V Maximum peak amplitude allowed for undershoot area. (See Figure 10) Max 0.3 V Maximum area above VDD. (See Figure 10) Max 0.1 V-ns Maximum area below VSS. (See Figure 10) Max 0.1 V-ns NOTE 1 VDD2 stands for VDD fo

26、r CA5:0, CK_t, CK_c, CS_n, CKE and ODT. VDD stands for VDDQ for DQ, DMI, DQS_t and DQS_c. NOTE 2 VSS stands for VSS for CA5:0, CK_t, CK_c, CS_n, CKE and ODT. VSS stands for VSSQ forDQ, DMI, DQS_t and DQS_c. NOTE 3 Maximum peak amplitude values are referenced from actual VDD and VSS values. NOTE 4 Ma

27、ximum area values are referenced from maximum operating VDD and VSS values. Figure 10 Overshoot and Undershoot Definition JEDEC Standard No. 8-29 Page 8 Rev. 8/13 Standard Improvement Form JEDEC The purpose of this form is to provide the Technical Committees of JEDEC with input from the industry reg

28、arding usage of the subject standard. Individuals or companies are invited to submit comments to JEDEC. All comments will be collected and dispersed to the appropriate committee(s). If you can provide input, please complete this form and return to: JEDEC Attn: Publications Department 3103 North 10th

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