Μέγεθος: px
Εμφάνιση ξεκινά από τη σελίδα:

Download ""

Transcript

1 ZO SYSTM LOK IGRM TV-OUT TFT L Panel WXG RT Speaker P P udio mplifier P P INT or V selector Resistor P P onnector MI Jack Phone Jack H (ST) O (PT) P P LVS TV-out RT P Int MI Line in MXM P zalia udioontroller RealTek L P P P M. LVS VG PT zalia X'TL.K M Sg ufpg P,,,0,, LP (WPLG) SPI ROM P,,, P X'TL.KHZ ual hannel R / MHz US.0 PU Thermal Sensor US Port x PI us P PI-xpress X TV-out ST0 Turion ual-ore/ Sempron Single-ore n-vidia MP Touch Pad P HT LINK P luetooth P P P PI-xpress LI P P0 P ardreader ontroller I Port P0 PU Fan RII SO-IMM 0 SO-IMM P X'TL.MHZ Ricoh R US Mini ard / WLN Media ard Reader P0 P VOR(ISL) P V/.V (TPS0) ISHRG.V P P P PI- LN PHY Realtek RTL Transformer New ard P RJ/ P P X'TL M.V/.VM/.V/.V SMR_VRF/ SMR_VTRM VG-ore (MX ).V P TTRY SLT TTRYHRGR (ISL) P P P Keyboard P PROJT : ZO Quanta omputer Inc. Size ocument Number Rev lock iagram Wednesday, pril, 00 ate: Sheet of 0

2 () HT_RX#[..0] HT_RX#[..0] () HT_TX[..0] () HT_RX[..0] HT_RX[..0] () HT_TX#[..0] HT_TX[..0] HT_TX#[..0] PROSSOR HYPRTRNSPORT INTRF VLT_RUN () HT_PU_UPLK () HT_PU_UPLK# () HT_PU_UPLK0 () HT_PU_UPLK#0 R _ R0 _ () HT_PU_UPTL0 () HT_PU_UPTL#0 VLT_x N VLT_x R ONNT TO TH LT_RUN POWR SUPPLY THROUGH TH PKG OR ON TH I. IT IS ONLY ONNT ON TH OR TO OUPLING NR TH PU PKG HT_TLIN_P HT_TLIN_N VLT_RUN HT_RX N HT_RX#P HT_RX M HT_RX#M HT_RX L HT_RX#M HT_RX K HT_RX#K HT_RX H HT_RX#H HT_RX0 G HT_RX#0H HT_RX F HT_RX# F HT_RX HT_RX# F HT_RX N HT_RX# N HT_RX L HT_RX# M HT_RX L HT_RX# L HT_RX J HT_RX# K HT_RX G HT_RX# H HT_RX G HT_RX# G HT_RX HT_RX# F HT_RX0 HT_RX#0 J K J J P P N P U VLT_ VLT_ VLT_ VLT_0 L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H0 L0_IN_L0 L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H L0_IN_L L0_IN_H0 L0_IN_L0 L0_LKIN_H L0_LKIN_L L0_LKIN_H0 L0_LKIN_L0 L0_TLIN_H L0_TLIN_L L0_TLIN_H0 L0_TLIN_L0 thlon S Processor Socket VLT_ VLT_ VLT_ VLT_0 L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H0 L0_OUT_L0 L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H L0_OUT_L L0_OUT_H0 L0_OUT_L0 L0_LKOUT_H L0_LKOUT_L L0_LKOUT_H0 L0_LKOUT_L0 L0_TLOUT_H L0_TLOUT_L L0_TLOUT_H0 L0_TLOUT_L0 T T HT_TX HT_TX# V HT_TX U HT_TX# V HT_TX V HT_TX# Y HT_TX W HT_TX# HT_TX HT_TX# HT_TX0 HT_TX#0 HT_TX HT_TX# HT_TX HT_TX# T HT_TX R HT_TX# U HT_TX U HT_TX# V HT_TX U HT_TX# W HT_TX W HT_TX# HT_TX HT_TX# HT_TX HT_TX# HT_TX HT_TX# HT_TX0 HT_TX#0 Y Y Y W T HT_PU_WNTL R HT_PU_WNTL# R R.U_ T T0 HT_PU_WNLK () HT_PU_WNLK# () HT_PU_WNLK0 () HT_PU_WNLK#0 () HT_PU_WNTL0 () HT_PU_WNTL#0 ().V_HT VLT_RUN 0 ohm() L FJHS00_0 L0 FJHS00_0.U_.U_.U_.U_ 0P_ LYOUT: Place bypass cap on topside of board NR HT POWR PINS THT R NOT ONNT IRTLY TO OWNSTRM HT VI, UT ONNT INTRNLLY TO OTHR HT POWR PINS PL LOS TO VLT0 POWR PINS 0 0P_ PROJT : ZO Quanta omputer Inc. Size ocument Number Rev THLON HT I/F ate: Wednesday, pril, 00 Sheet of 0

3 V_VTT_SUS_PU IS ONNT TO TH V_VTT_SUS POWR SUPPLY THROUGH TH PKG OR ON TH I. IT IS ONLY ONNT ON TH OR TO OUPLING NR TH PU PKG.VSUS K/F_ M Q M Q () M Q[0..] M Q M_T M_T M Q[0..] () F M Q PU_M_VRF M Q M_T M_T F M Q M Q0 M_T M_T M Q0 M Q M_T0 M_T0 Y M Q 00 M Q M_T W R0 M_T M Q M Q M_T M_T Y M Q 000P_ M Q M_T K/F_ M_T F M Q M Q M_T M_T F M Q M Q M_T M_T F M Q M Q M_T M_T M Q.VSUS M Q M_T M_T F M Q SMR_VTRM M Q M_T M_T Y M Q M Q0 M_T M_T Y U M Q0 M Q M_T0 M_T0 W M Q R M Q M_T M_T W M Q./F_ M Q M_T M_T W M Q MMVRF VTT 0 0 M Q M_T M_T Y M Q VTT_SNS VTT 0 0 M Q M_T M_T M Q T Y0 VTT_SNS VTT 0 F M Q M_T M_T M Q VTT 0 F M Q M_T M_T M Q M_ZN VTT W0 F0 M Q M_T M_T 0 M Q M_ZP MMZN VTT 0 0 M Q M_T M_T F0 M Q MMZP VTT 0 M Q0 M_T M_T 0 M Q0 VTT 0 M Q M_T0 M_T0 Y0 M Q VTT 0 M Q M_T M_T M Q R M Q M_T M_T Y M Q () M S# V M0_S_L M0_LK_H Y M_LKOUT ()./F_ M Q M_T M_T W M Q () M S# J M0_S_L M0_LK_L M_LKOUT# () M Q M_T M_T W M Q () M S# V M0_S_L M0_LK_H M_LKOUT0 () M Q M_T M_T M Q () M S#0 T M0_S_L0 M0_LK_L F M_LKOUT0# () M Q M_T M_T M Q M Q M_T M_T M Q () M S# Y M0_S_L M0_LK_H F M_LKOUT () M Q M_T M_T Y M Q () M S# J M0_S_L M0_LK_L F M_LKOUT# () G M Q0 M_T M_T H M Q0 () M S# W M0_S_L M0_LK_H M_LKOUT () G M Q M_T0 M_T0 H0 M Q () M S#0 U M0_S_L0 M0_LK_L M_LKOUT# () M Q M_T M_T M Q M Q M_T M_T M Q () M_K H M_K M0_OT W M_OT () G M Q M_T M_T J M Q () M_K J M_K0 M0_OT0 W M_OT () G M Q M_T M_T H M Q () M_K J0 M_K M0_OT V0 M_OT () M Q M_T M_T F M Q () M_K0 J M_K0 M0_OT0 U M_OT0 () M Q M_T M_T F0 M Q () M [0..] M M M Q M_T M_T K M Q M [0..] () M M_ M_ J M M Q M_T M_T K0 M Q M M_ M_ J 0 V M M Q0 M_T M_T F M Q0 M M_ M_ W 0 K M M Q M_T0 M_T0 M Q M M_ M_ L L0 M M Q M_T M_T 0 M Q M 0 M_ M_ L R M 0 M Q M_T M_T M Q M M_0 M_0 U L M M Q M_T M_T M Q M M_ M_ L 0 L M M Q M_T M_T G M Q M M_ M_ M L M M Q M_T M_T G M Q M M_ M_ L M M M Q M_T M_T M Q M M_ M_ N M0 M M Q M_T M_T F M Q M M_ M_ N M M M Q M_T M_T M Q M M_ M_ N 0 M M M Q0 M_T M_T H M Q0 M M_ M_ N N M M Q M_T0 M_T0 M Q M M_ M_ P N M M Q M_T M_T M Q M 0 M_ M_ P R M 0 M Q M_T M_T H M Q M_0 M_0 T M Q M_T M_T M Q M Q M_T M_T M Q () M S# K M_NK M_NK K M S# () M Q M_T M_T H M Q () M S# R0 M_NK M_NK T M S# () G M Q M_T M_T H M Q () M S#0 T M_NK0 M_NK0 U M S#0 () M Q M_T M_T G M Q M Q M_T M_T H M Q () M RS# T0 M_RS_L M_RS_L U M RS# () M Q0 M_T M_T F M Q0 () M S# U0 M_S_L M_S_L V M S# () M_T0 M_T0 G () M W# U M_W_L M_W_L U M W# () M M M M M M M_M M_M Y M M R II: M/TRL/LK M M M_M M_M M M M M M_M M_M Y M M thlon S M M M_M M_M M M Processor Socket M M M_M M_M F M M M M M_M M_M M M M M0 M_M M_M M M0 () M M[0..] M_M0 M_M0 M M[0..] () Near PU L<00mil M QS F M QS M QS# M_QS_H M_QS_H W M QS# M_LKOUT M_LKOUT0 M QS M_QS_L M_QS_L W M QS M QS# M_QS_H M_QS_H Y M QS# M QS M_QS_L M_QS_L W F M QS M QS# M_QS_H M_QS_H F M QS#.P_ M QS M_QS_L 0.P_ M_QS_L M QS M_LKOUT# M_LKOUT0# M QS# M_QS_H M_QS_H M QS# M QS M_QS_L M_QS_L F M QS M_LKOUT M_LKOUT M QS# M_QS_H M_QS_H G M QS# M QS M_QS_L M_QS_L G M QS M QS# M_QS_H M_QS_H M QS# M QS M_QS_L M_QS_L M QS.P_.P_ M QS# M_QS_H M_QS_H G M QS# M_LKOUT# M_LKOUT# M QS0 M_QS_L M_QS_L G M QS0 M QS#0 M_QS_H0 M_QS_H0 G M QS#0 M_QS_L0 M_QS_L0 H.U_.U_ SMR_VTRM.U_.U_.U_.U_.U_.U_ R 0 000P_ 000P_ 000P_ 000P_ 0 0P_ 0 0P_ 0 0P_ 0P_ To SOIMM socket (Far) () M QS#0 M QS# M QS# M QS# M QS# M QS# M QS# M QS# () M QS[0..] M QS#[0..] Processor R Memory Interface M QS0 M QS M QS M QS M QS M QS M QS M QS U R: T thlon S Processor Socket M QS0 M QS M QS M QS M QS M QS M QS M QS M QS#0 M QS# M QS# M QS# M QS# M QS# M QS# M QS# M QS[0..] () To SOIMM socket (near) M QS#[0..] () PROJT : ZO Quanta omputer Inc. Size ocument Number Rev THLON RII MMORY I/F ate: Wednesday, pril, 00 Sheet of 0

4 LYOUT: ROUT V TR PPROX. 0 mils WI (US x mil TRS TO XIT LL FIL) N 00 mils LONG. THLON ontrol and ebug PU_V_RUN PU_V_RUN.U_ R 00_ H_PROHOT# V ().VSUS.U_ () () (,,) PU_TST_THRM HTPU_PWRG PU_TST_THRM 0 mil trace / 0 mil space L LMPG0SN_ HTPU_STOP# HTPU_RST# PWROK_.V R *0_ V_THM.V PU H/W MONITOR R Q MMT0 /F_ 00P_ R 0_ 00P_ MIL 0 00U-.V_ R0 V.VSUS *0_ R0 *.K/F_.VSUS.VSUS _PROHOT# () MP_PROHOT# () ddress H R00 0_ R 0_ R0 0_ U G V -LT XN SMT XP SMLK -OVT U *NSZ0PX_NL 0 U *NSZ0PX_NL U *NSZ0PX_NL R 0K_ KSMT KSMLK * * * Q0 V.VSUS PU_LL_PWROK PU_LTSTOP# PU_HT_RST# V R 0K_ If M SI is not used, the SI pin can be left unconnected and SI should have a 00-Ω (±%) pulldown to VSS. N00 R0 R0 ().VSUS To S GPIO To FN *00_ *00_ R0 00_ PSI# MP_THRMIP#.V 00_ R THRM_LRT# () PUFN#_ON () H_THRMTRIP# V PU_SI_R PU_SI_R () ().V V Q MMT0 R0 PU_LK PU_LK# () () PWR_PSI# () VLT_RUN ORFV ORF- PWROK_ R.K_ V R 0K_ *0_ R.K_ R K/F_ Q N00 Q *MMT0 Q N00.V R 0_ R *.K_ Q MMT0 00P_ 00P_ MT_PU () MLK_PU () R /F_ R *.K_ R R T T T T0 T T T THRM_SYS_PWR () PU_V_RUN PU_HT_RST# PU_LL_PWROK PU_LTSTOP# PU_SI_R PU_SI_R./F_./F_ PU_VIO_SUS_F_H PU_VIO_SUS_F_L PU_LKIN_S_P PU_LKIN_S_N PU_RY PU_TMS PU_TK PU_TRST# PU_TI PU_HTRF PU_HTRF0 PU_TST_H_YPSSLK_H PU_TST_L_YPSSLK_L PU_TST_PLLTST0 PU_TST_PLLTST PU_TST_P PU_TST_P PU_TST_P PU_TST_P0 PU_TST_SNSHIFTN PU_TST_THRM PU_TST_THRM U F V F V RST_L PWROK F0 LTSTOP_L F SI F SI P HT_RF R HT_RF0 F W Y G0 F G H0 F W W Y P0 P N0 N R R P R V_F_H V_F_L VIO_F_H VIO_F_L LKIN_H LKIN_L RY TMS TK TRST_L TI TST_H TST_L TST TST TST TST TST TST TST TST TST TST TST TST TST TST TST RSV0 RSV RSV RSV RSV RSV RSV RSV MIS PU_TST_SINGLHIN PU_TST_URNIN# PU_PRSNT# PU_TST_H_YPSSLK_H PU_TST_SNN PU_TST_L_YPSSLK_L PU_TST_PLLTST0 PU_TST_PLLTST THRMTRIP_L PROHOT_L M NPT S SOKT Processor Socket VI VI VI VI VI VI0 PU_PRSNT_L PSI_L RQ_L TO TST_H TST_L TST TST TST TST TST0 TST_H TST_L TST TST TST0 TST RSV RSV RSV0 RSV RSV RSV RSV RSV RSV RSV RSV RSV RSV0 R0 *00_ R0 00_ R K/F_ R 0/F_ R0 00_ R 0/F_ R 00_ R 00_.VSUS F 0 F J H F K H H G R W R H H H_THRMTRIP# H_PROHOT# PU_PRSNT# PU_RQ# PU_TO PSI# PU_TST_H_FLKOUT_P R 0./F_ PU_TST_L_FLKOUT_N TST_L and TST_H differential pair should have an 0- differential trace routed to a termination resistor. These traces should be shorter than. inches. //// PU_TST_SNLK PU_TST_TSTUP PU_TST_SNSHIFTN PU_TST_SNN PU_TST0_SNLK PU_TST_SINGLHIN PU_TST_URNIN#.VSUS HTPU_RST#.VSUS PU_RQ# PU_RY PU_TK PU_TMS PU_TI PU_TRST# PU_TO.VSUS V H_VI () H_VI () H_VI () H_VI () H_VI () H_VI0 () PSI_L is a Power Status Indicator signal. This signal is asserted when the processor is in a low powerstate. PSI_L should be connected to the power supply controller, if the controller supports skipmode, or diode emulation mode. PSI_L is asserted by the processor during the and S states. R0 0_ R 0_ R 0_ R0 0_ R 0K_ R 00_ R 0_ Q MMT0 T T T T0 HT ONNTOR R K/F_ H_HTPU_RST# T T T T T T T.VSUS T HT N *SP-00-0-P-LV RSV RSV0 RQ_L RY 0 TK TMS TI TRST_L TO 0 V_PRO_IO_ V_PRO_IO_RST_L KY PROJT : ZO Quanta omputer Inc. Size ocument Number Rev THLON TRL & UG Wednesday, pril, 00 ate: Sheet of 0 0 0

5 PROSSOR POWR N GROUN V_OR V_OR VSS VSS J VSS VSS J V V V VSS VSS J0 V V V VSS VSS J G V_OR V V W VSS VSS0 J H V V Y VSS VSS J J V V J VSS VSS J J V V K VSS VSS K J V V L VSS VSS K K V V0 M VSS0 VSS K K0 VSS VSS K 0 V V P 0 0 K U-0V_ VSS VSS K U-0V_ U-0V_ U-0V_ U-0V_ U-0V_ U-0V_ V0 V T U-0V_ U-0V_ K V V U VSS VSS K L V V V.VSUS VSS VSS K L V VSS VSS0 L L V VSS VSS L L V_OR V VIO H VSS VSS L0 L V VIO J VSS VSS L M V VIO K VSS VSS L M V VIO K VSS0 VSS L M V VIO K VSS VSS L M0 VSS VSS M 0 V0 VIO K N.U_ VSS VSS M.U_.0U_ 0P_ V VIO L N V VIO M VSS VSS M N V VIO M VSS VSS0 M P V VIO0 M VSS VSS N P0 V VIO M VSS VSS N R V VIO N VSS VSS N0 R V VIO P VSS VSS N R V VIO P VSS0 VSS N R V VIO P VSS VSS P T V0 VIO P VSS VSS P T V VIO R VSS VSS P T V VIO T VSS VSS P T0 V VIO T VSS VSS00 P T V VIO0 T VSS VSS0 R T V VIO T VSS VSS0 R0 U V VIO U VSS VSS0 R U V VIO V VSS VSS0 R U V VIO V VSS0 VSS0 T U V VIO V VSS VSS0 T V V0 VIO V VSS VSS0 T V V VIO Y VSS VSS0 T V0 V VSS VSS0 T OUPLING TWN PROSSOR N IMMs VSS VSS0 T POWR VSS VSS U thlon S VSS VSS U PL LOS TO PROSSOR S POSSIL Processor Socket VSS VSS U VSS VSS U0 VSS0 VSS U.VSUS VSS VSS U F VSS VSS U F VSS VSS U F VSS VSS V F VSS VSS0 V F VSS VSS V 0 0 F.0U_ 0P_ VSS VSS V.U_.U_.U_.U_.U_.U_.U_.U_.0U_ 0P_ 0P_ F VSS VSS V F VSS VSS V F VSS0 VSS V H VSS VSS W H VSS VSS Y H VSS VSS Y H VSS VSS N J.VSUS VSS M Sg GROUN thlon S upg Processor Socket 0 U-0V_ U-0V_.U_.U_ F Top View U UF PROJT : ZO Quanta omputer Inc. Size ocument Number Rev THLON PWR & ate: Wednesday, pril, 00 Sheet of 0

6 M M M M 0 M QS M M M M Q M Q M Q M QS#0 M M Q M Q M Q M Q M M0 M Q M Q M Q M QS# M Q M Q M M M M M M Q0 M Q M Q M Q M Q M Q M Q M QS M M Q M Q M Q M QS# M M QS M M QS# M Q M Q M Q M Q M Q0 M QS M QS M Q M Q M Q0 M M Q0 M Q M QS# M QS M M M Q M Q M Q M Q M QS0 M Q M Q M Q M Q M Q MVRF_IM M QS M M M M M M M QS# M QS# MM_SMLK MM_SMT M Q M Q M QS# M M M Q M Q M Q M Q M Q M 0 M Q M Q M Q0 M M M M M M Q M Q M Q M QS# M QS0 M M M M Q0 M QS M M M Q M Q M QS# M QS M M M M Q0 M Q M Q M M0 M 0 M Q M Q M Q M Q M M M Q M Q M Q MM_SMLK M QS M Q M QS# M M Q M Q M Q M M M M M M Q M Q M Q M Q M QS# MM_SMT M M M Q M Q M Q0 M Q M QS# M M Q M Q M Q M M QS M QS M M Q M Q M Q M QS M Q M Q M Q M Q M QS# M QS#0 M M Q0 M Q0 M Q M QS# M M M Q M 0 M Q M Q0 M QS M M Q M Q M Q M Q MVRF_IM MVRF_IM M Q M Q M Q0 M Q M Q M Q M Q M Q M Q M Q M Q M M M M M M M M M 0 M M M M M M 0 M S# M W# M S# M RS# M_K M_OT0 M S# M RS# M S# M S# M S#0 M S# MM_SMLK MM_SMT M M M M 0 M S# M M_K M_OT M_OT M_K M S#0 M S# M S# M M M M S#0 M M M M M M M M Q M Q M Q M Q M Q0 M Q M Q M Q M Q M Q0 M Q M Q M Q M Q M Q M Q M Q M Q M_K0 M S# M 0 M S# M_OT M S# M S#0 M W# M MSM_T () MSM_LK () V V.VSUS.VSUS.VSUS.VSUS.VSUS.VSUS SMR_VRF V V SMR_VTRM SMR_VTRM V.VSUS SMR_VTRM M [0..] () M_K0 () M_K () M RS# () M S# () M W# () M S#0 () M S# () M_OT0 () M Q[0..] () M_LKOUT0 () M_LKOUT0# () M_LKOUT () M_LKOUT# () M_OT () M S# () M S# () M S#0 () M QS#[0..] () M QS[0..] () M M[0..] () M_LKOUT () M_LKOUT# () M_LKOUT () M_LKOUT# () M_OT () M_K () M_K () M_OT () M [0..] () M S# () M S#0 () M S# () M QS#[0..] () M QS[0..] () M M[0..] () M RS# () M S# () M W# () M Q[0..] () M S# () M S# () M S# () M S# () M S#0 () M S# () Size ocument Number Rev ate: Sheet of R-II SOIMM* 0 Wednesday, pril, 00 Size ocument Number Rev ate: Sheet of R-II SOIMM* 0 Wednesday, pril, 00 Size ocument Number Rev ate: Sheet of R-II SOIMM* 0 Wednesday, pril, 00 (H=.) (H=.) RVRS RVRS RP X_ RP X_ 0 0 *0U-.V_ *0U-.V_ 0 0 RP X_ RP X_ 0 0 0U-.V_ 0 0U-.V_ 0 RP0 X_ RP0 X_ RP X_ RP X_ RP X_ RP X_ 0 0 RP X_ RP X_ U_ U_ * * RP0 X_ RP0 X_ R _ R _ RP X_ RP X_ 0 0 Q *N00 Q *N RP X_ RP X_ 0 0 R 0_ R 0_ 0U-.V_ 0U-.V_ *0U-.V_ *0U-.V_ * * RP X_ RP X_ RP X_ RP X_ R _ R _ RP X_ RP X_ 0 0 *0U-.V_ *0U-.V_ RP X_ RP X_ RP X_ RP X_ 0 0 Q *N00 Q *N00 R *0_ R *0_ SO-IMM J RII_SOIMM_R H. SO-IMM J RII_SOIMM_R H. Q0 Q Q Q Q Q Q Q Q Q Q0 Q Q 0 Q Q Q Q Q Q Q Q0 Q Q Q Q Q Q Q Q Q Q0 Q Q Q Q Q Q Q Q Q Q0 Q Q Q Q 0 Q Q Q Q Q Q0 Q Q Q 0 Q Q Q Q Q Q Q0 0 Q Q Q N 0 N N N 0 N/TST M0 0 M M M M 0 M M 0 M QS0 QS QS QS 0 QS QS QS QS K0 0 K0 K K K0 K 0 VRF RS 0 S W 0 S0 0 S S0 S 00 S SL Vspd V0 V V V V V V 0 V V 0 V V0 V VSS0 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS0 VSS VSS VSS VSS 0 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS0 VSS VSS VSS VSS VSS VSS VSS VSS VSS0 0 VSS VSS VSS VSS VSS0 VSS VSS VSS VSS VSS VSS VSS VSS 0 VSS QS0 QS QS QS QS QS QS QS OT0 OT VSS VSS VSS VSS 0 VSS VSS VSS VSS VSS0 Quanta omputer Inc. PROJT : ZO Quanta omputer Inc. PROJT : ZO RP X_ RP X_ RP X_ RP X_ * * RP *.KX_ RP *.KX_ R _ R _ RP X_ RP X_ RP X_ RP X_ R 0K_ R 0K_ 0 0 *0U-.V_ *0U-.V_ RP X_ RP X_ 0 0 SO-IMM J RII_SOIMM_R H. SO-IMM J RII_SOIMM_R H. Q0 Q Q Q Q Q Q Q Q Q Q0 Q Q 0 Q Q Q Q Q Q Q Q0 Q Q Q Q Q Q Q Q Q Q0 Q Q Q Q Q Q Q Q Q Q0 Q Q Q Q 0 Q Q Q Q Q Q0 Q Q Q 0 Q Q Q Q Q Q Q0 0 Q Q Q N 0 N N N 0 N/TST M0 0 M M M M 0 M M 0 M QS0 QS QS QS 0 QS QS QS QS K0 0 K0 K K K0 K 0 VRF RS 0 S W 0 S0 0 S S0 S 00 S SL Vspd V0 V V V V V V 0 V V 0 V V0 V VSS0 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS0 VSS VSS VSS VSS 0 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS0 VSS VSS VSS VSS VSS VSS VSS VSS VSS0 0 VSS VSS VSS VSS VSS0 VSS VSS VSS VSS VSS VSS VSS VSS 0 VSS QS0 QS QS QS QS QS QS QS OT0 OT VSS VSS VSS VSS 0 VSS VSS VSS VSS VSS0 0 0 RP X_ RP X_ R 0_ R 0_ * * RP X_ RP X_ R _ R _ R0 K/F_ R0 K/F_ RP X_ RP X_ RP X_ RP X_ R 0_ R 0_.U_.U_ R _ R _ RP X_ RP X_ R K/F_ R K/F_.U_.U_ RP X_ RP X_ * * R _ R _ RP X_ RP X_ 0 0 RP X_ RP X_

7 V V MP Used UM Only MP Signal Name RG RST RG VRF _T0 TV RST TV VRF IFP_RST IFP_VPRO _T HPLUG_T HMI_RST HMI_VPRO _T_R HP_ROM_ST HPLUG_T_R MP Unused UM Only MP Signal Name RG RST RG VRF _T0 TV RST TV VRF IFP_RST IFP_VPRO _T HPLUG_T HMI_RST HMI_VPRO _T_R HP_ROM_ST HPLUG_T_R FOR UM ONLY omponent *0K LV N *0K LV N K PULN 0K PULLHIGH 0K PULLHIGH.K PULN omponent 0K PULLHIGH 0K PULLHIGH K PULN 0K PULLHIGH 0K PULLHIGH.K PULN () INT_HSYN R IV@0_ INT_RT_R () INT_VSYN R IV@0_ INT_RT_GRN R /F_ R IV@0_ INT_RT_LU.0U_ R R0 R R R IV@0_ INT_TV_/R IV@0_ INT_TV_Y/G IV@0_ INT_TV_OMP 0 IV@P_ Y IV@MHZ IV@P_ : changed P value V@.K_ INT_RT_T V@.K_ INT_LVS_IT () HT_TX[..0] () HT_TX#[..0] () HT_PU_WNLK0 () HT_PU_WNLK#0 () HT_PU_WNLK () HT_PU_WNLK# () HT_PU_WNTL0 () HT_PU_WNTL#0.V_HT () MP_THRMIP# () MP_PROHOT# () INT_RT_R () INT_RT_GRN () INT_RT_LU () INT_RT_LK () INT_RT_T V () INT_TV_/R () INT_TV_Y/G () INT_TV_OMP R HT_TX0 HT_TX HT_TX HT_TX HT_TX HT_TX HT_TX HT_TX HT_TX HT_TX HT_TX0 HT_TX HT_TX HT_TX HT_TX HT_TX HT_TX#0 HT_TX# HT_TX# HT_TX# HT_TX# HT_TX# HT_TX# HT_TX# HT_TX# HT_TX# HT_TX#0 HT_TX# HT_TX# HT_TX# HT_TX# HT_TX# 0/F_ PU_L_PV 0/F_ PU_L_ RG RST RG VRF /F_ TV RST.0U_ TV VRF TV_XTLIN TV_XTLOUT *0K_ HP_ROM_SLK 0K_ HP_ROM_ST *0K LK_R 0K T_R.K_ HPLUG_T_R * HMI_VPRO *K/F_HMI_RST HMI_TX_P_R HMI_TX_N_R : Remove,R for Nvidia suggest. UNUS HMI ONLY T T0 T T T T T T R R R0 R0 R R R R HMI_TX0_P_R HMI_TX0_N_R HMI_TX_P_R HMI_TX_N_R HMI_TX_P_R HMI_TX_N_R U0 F HT_MP_RX0_P H HT_MP_RX_P J HT_MP_RX_P K HT_MP_RX_P G HT_MP_RX_P L HT_MP_RX_P L HT_MP_RX_P J HT_MP_RX_P HT_MP_RX_P F HT_MP_RX_P H HT_MP_RX0_P L HT_MP_RX_P HT_MP_RX_P HT_MP_RX_P HT_MP_RX_P HT_MP_RX_P G HT_MP_RX0_N J HT_MP_RX_N K HT_MP_RX_N L HT_MP_RX_N F HT_MP_RX_N K HT_MP_RX_N K HT_MP_RX_N K HT_MP_RX_N HT_MP_RX_N G HT_MP_RX_N J HT_MP_RX0_N K HT_MP_RX_N HT_MP_RX_N HT_MP_RX_N HT_MP_RX_N HT_MP_RX_N J HT_MP_RX_LK0_P H HT_MP_RX_LK0_N L HT_MP_RX_LK_P K HT_MP_RX_LK_N H HT_MP_RXTL0_P G HT_MP_RXTL0_N HT_MP_RXTL_P HT_MP_RXTL_N M L MP :JMP0T00 :JMP0T0 MP_THRMIP# MP_PROHOT# THRMTRIP#/GPIO_(V) PROHOT#/GPIO_0(V_S) HT_MP_OMP_V HT_MP_OMP_ RG R RG GRN RG LU G RG HSYN H RG VSYN K RG RST RG VRF G _LK0 H _T0 TV R TV GRN TV LU TV RST H TV VRF TV_XTLIN F TV_XTLOUT MP OF HT S HT_RX0 HT_MP_TX0_P K HT_RX HT_MP_TX_P K HT_RX HT_MP_TX_P K HT_RX HT_MP_TX_P L HT_RX HT_MP_TX_P K HT_RX HT_MP_TX_P K HT_RX HT_MP_TX_P H HT_RX HT_MP_TX_P L0 HT_RX HT_MP_TX_P G HT_RX HT_MP_TX_P F HT_RX0 HT_MP_TX0_P H HT_RX HT_MP_TX_P HT_RX HT_MP_TX_P HT_RX HT_MP_TX_P F HT_RX HT_MP_TX_P 0 HT_RX HT_MP_TX_P HT_RX#0 HT_MP_TX0_N J HT_RX# HT_MP_TX_N L HT_RX# HT_MP_TX_N L HT_RX# HT_MP_TX_N K HT_RX# HT_MP_TX_N L HT_RX# HT_MP_TX_N L HT_RX# HT_MP_TX_N J HT_RX# HT_MP_TX_N M0 HT_RX# HT_MP_TX_N H HT_RX# HT_MP_TX_N G HT_RX#0 HT_MP_TX0_N J HT_RX# HT_MP_TX_N F HT_RX# HT_MP_TX_N HT_RX# HT_MP_TX_N G HT_RX# HT_MP_TX_N 0 HT_RX# HT_MP_TX_N F HT_MP_TX_LK0_P K HT_MP_TX_LK0_N J HT_MP_TX_LK_P G HT_MP_TX_LK_N H HT_MP_TXTL0_P K0 HT_MP_TXTL0_N J0 HT_MP_TXTL_P HT_MP_TXTL_N LKOUT_00MHZ_P L LKOUT_00MHZ_N M HT_MP_RQ# HTPU_RQ# HT_MP_STOP# 0 HT_MP_RST# HT_MP_PWRG PU_SVRF LK00_TRM_ G J IFP_TX_P 0 IFP_TX_N IFP_TX0_P 0 IFP_TX0_N IFP_TX_P IFP_TX_N IFP_TX_P 0 IFP_TX_N IFP_TX_P IFP_TX_N IFP_TX_P J IFP_TX_N J IFP_TX_P IFP_TX_N IFP_TX_P F0 IFP_TX_N F IFP_TX_P G0 IFP_TX_N G IFP_TX_P H IFP_TX_N H0 HP_ROM_SLK IFP_VPRO 0 HP_ROM_ST IFP_RST L _LK K FLT PNL _T _LK L L HPLUG_T _T J K HMI_VPRO K HMI_RST L_PNL_PWR L_KL_ON L HMI_TX_P L_KL_TL M HMI_TX_N GPIO_(V_S)/FRR/SYS_SRR/IGPU_GPIO_* U GPIO_(V_S)/NFRR/SYS_PRR/IGPU_GPIO_* T K HMI_TX0_P J HMI_TX0_N M0 HMI_TX_P L0 HMI_TX_N HPLUG_T K0 HMI_TX_P J0 HMI_TX_N PU_SVRF MP_TRM INT_TXLOUT INT_TXLOUT- IFP_VPRO IFP_RST MP_GPIO MP_GPIO HPLUG_T HT_RX[..0] () HT_RX#[..0] () HT_PU_UPLK0 () HT_PU_UPLK#0 () HT_PU_UPLK () HT_PU_UPLK# () HT_PU_UPTL0 () HT_PU_UPTL#0 () PU_LK () PU_LK# () HTPU_STOP# () HTPU_RST# () HTPU_PWRG () R 0_.V_HT 0 R0 INT_TXLLKOUT () INT_TXLLKOUT- () INT_TXLOUT0 () INT_TXLOUT0- () INT_TXLOUT () INT_TXLOUT- () INT_TXLOUT () INT_TXLOUT- () T T INT_LVS_ILK () INT_LVS_IT () INT_LVS_IGON () INT_LVS_LON () L_KLT_TRL () FOR VI IS NOT IMPLMNT V V [LVS] HTPU_RQ# MP_THRMIP# atasheet error its should be. plane : Remove,R for Nvidia suggest. R R R R0.K/F_ *.0U_ *K/F_ *.K_ *.K_ K_ FOR UM ONLY : Remove R,R R R K_ *00_ MP_THRMIP# R 00_ HTPU_STOP# R0 00_ HTPU_RST# R 00_ HTPU_PWRG R 00_ MP_PROHOT# R 00_ V V.VSUS PROJT : ZO Quanta omputer Inc. Size ocument Number Rev MP(HT/VG/FLT_PNL) ate: Wednesday, pril, 00 Sheet of 0

8 [MXM] [NW R] [TV] [MINI R] U0 () PG_RXP[:0] PG_TXP[:0] () PG_RXP0 F _PG_TXP0 PG_TXP0 PG_RXP P0_RX0_P P0_TX0_P F _PG_TXP PG_TXP PG_RXP P0_RX_P MP P0_TX_P _PG_TXP PG_TXP PG_RXP P0_RX_P OF P0_TX_P _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P F _PG_TXP PG_TXP PG_RXP P0_RX_P PI P0_TX_P F _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P 0 0 H _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P H _PG_TXP PG_TXP PG_RXP0 P0_RX_P P0_TX_P H _PG_TXP0 PG_TXP0 PG_RXP P0_RX0_P P0_TX0_P 0 K _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P K _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P F K _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P G J _PG_TXP PG_TXP PG_RXP P0_RX_P P0_TX_P H K _PG_TXP PG_TXP P0_RX_P P0_TX_P H () PG_RXN[:0] PG_TXN[:0] () PG_RXN0 G _PG_TXN0 PG_TXN0 PG_RXN P0_RX0_N P0_TX0_N F _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N 0 _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N 0 _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N F _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N F _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N 0 H _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N H _PG_TXN 0 PG_TXN PG_RXN0 P0_RX_N P0_TX_N H _PG_TXN0 PG_TXN0 PG_RXN P0_RX0_N P0_TX0_N K _PG_TXN PG_TXN P0_PRSNTX PG_RXN P0_RX_N P0_TX_N 0 K _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N F0 K _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N G0 J0 _PG_TXN PG_TXN PG_RXN P0_RX_N P0_TX_N H0 K0 _PG_TXN PG_TXN P0_RX_N P0_TX_N H P0_PRSNTX# P0_PRSNTX# R _ P0_RFLK_P P0_PRSNTX () LK_MXM R V P0_RFLK_N P0_RFLK_P P0_PRSNTX#/_LK U R *0K_ R _ P0_PRSNTX R0 *0K_ P0_PRSNTX# () LK_MXM# R0 P0_RFLK_N P0_PRSNTX#/_T U0 P0_PRSNTX R *0K_ Internal Pull-up P0_PRSNTX#/XP_N U P0_PRSNTX R *0K_ P0_PRSNTX# U R *0_ () PI_RXP () PI_RXN () NW_LKRQ# () PP# NW_LKRQ# PP# PI_TXP_ PI_TXN_ LK_PI_NW R LK_PI_NW_#_R PI_TXP_ () PI_RXP N 0 P_RX_P P_TX_P M PI_TXP () PI_TXN_ () PI_RXN N PI_TXN () MINI_LKRQ# P_RX_N P_TX_N M LK_PI_MINI_R () MINI_LKRQ# U P_LKRQ# P_RFLK_P T R _ LK_PI_MINI () U LK_PI_MINI#_R P_PRSNT# P_RFLK_N T R _ LK_PI_MINI# () :PIN U GO IRTLY L P_RX_P L0 P_RX_N W P_LKRQ# W P_PRSNT# M P_RX_P M P_RX_N U P_LKRQ# U P_PRSNT# N0 P_RX_P N P_RX_N R P_LKRQ#/GPIO_(V) U P_PRSNT# P P_RX_P P0 P_RX_N T P_LKRQ#/GPIO_(V) V P_PRSNT# P P_RX_P P P_RX_N U PF_LKRQ#/GPIO_(V) V0 PF_PRSNT# MP P_TX_P M P_TX_N M P_RFLK_P T P_RFLK_N T P_TX_P M P_TX_N M P_RFLK_P T P_RFLK_N T0 P_TX_P M0 P_TX_N M P_RFLK_P T P_RFLK_N T P_TX_P P P_TX_N P P_RFLK_P T P_RFLK_N T P_TX_P P P_TX_N P P_RFLK_P P P_RFLK_N R P_RST# W0 P_RST# W P_LK_OMP V P_OMP <00mil R R *0_ R _ R _ PI_RST# () dd 0R resistor, The resistor should only be stuffed for MP *.K/F_ PI_RST# () PI_TXP () PI_TXN () LK_PI_NW_ () LK_PI_NW_# () : Remove R for Nvidia suggest. P0_PRSNTX () NT NM P0_PRSNTX [NW R] [MINI R] MP (ISRT) LK_MXM LK_MXM# LK_PI_MINI LK_PI_MINI# LK_PI_NW_ LK_PI_NW_# MINI_LKRQ# NW_LKRQ# PP# MPM (GPU) N/ *0P_ *0P_ *0P_ *0P_ *0P_ *0P_ Internal 0K to. R0 R0 R *0K_ *0K_ *0K_ V PROJT : ZO Quanta omputer Inc. Size ocument Number Rev MP(PI-) ate: Wednesday, pril, 00 Sheet of 0

9 PI/LP PULL-UP (0,) [..0] (0,) 0# (0) # (0) # (0) # (0,) LKRUN# (,,) L0 (,,) L (,,) L (,,) L (0,,,) LFRM# () LRQ#0 T (,0,,) SRIRQ (,,) LP_RST# V R _ R _ R _ R _ L0_R L_R L_R L_R R0 _ LFRM#_R LRQ#0 LRQ# SRIRQ R _ R R 0K_ *0K_ U0 0 PI_0 0 PI_ 0 PI_ L PI_ K PI_ J PI_ PI_ PI_ J PI_ H PI_ G PI_0 F PI_ PI_ PI_ PI_ PI_ G PI_ PI_ PI_ J PI_ PI_0 PI_ K PI_ PI_ L PI_ G PI_ J PI_ PI_ H PI_ PI_ F PI_0 PI_ K PI_0# K PI_# F PI_# K PI_# PI_LKRUN#/GPIO_(V) LP_0 LP_ LP_ LP_ MP PI_FRM# J MP PI_IRY# H OF PI_TRY# K PI_STOP# PI_VSL# L PI_PR PI_PRR#/GPIO_(V)/RS_# J PI_SRR# PI_PM#/GPIO_0(V_S) PI PI_RQ0# 0 PI_RQ# G0 PI_RQ#/GPIO_0(V)/RS_SR# J0 PI_RQ#/GPIO_(V)/RS_TS# M PI_RQ#/GPIO_(V)/RS_SIN# PI_GNT0# F0 PI_GNT# H0 PI_GNT#/GPIO_(V)/RS_TR# K0 PI_GNT#/GPIO_(V)/RS_RTS# L0 PI_GNT#/GPIO_(V)/RS_SOUT# F PI_INTW# L PI_INTX# J PI_INTY# PI_INTZ# K PI_LK0 PI_LK PI_LK PI_LK PI_LK LP LP_FRM# LP_RQ0#/GPIO_0(V) LP_RQ#/GPIO_(V)/FNRPM LP_SRIRQ LP_RST# LP_RST# MP_TK T JTG_TK MP_TI U JTG_TI P0 PKG_TST JTG PI_LKIN PI_RST# L PI_RST# K PI_RST# K PI_RST0# J LP_PWRWN#/GPIO_(V)/XT_NMI# LP_LK0 LP_LK JTG_TO JTG_TMS JTG_TRST# TST_MO_N T T U P FRM# IRY# TRY# STOP# VSL# PR PRR# SRR# PI_PM# RQ0# RQ# RQ# RQ# RQ# GNT0# GNT# GNT# GNT# GNT# INT# INT# INT# INT# PI_LK R PI_LK PI_LK PI_LK PI_LK PI_LKIN PIRST# PIRST# IRST_R# PIRST_R# LP_P# LP_LK R PI_LK_UG R R _ MP_TO MP_TMS MP_TRST# TSTMO_N R _ R _ FRM# (0) IRY# (0) TRY# (0) STOP# (0) VSL# (0) PR (0) PRR# (0) SRR# (0) PI_PM# (0) RQ0# (0) T T T T0 GNT0# (0) T T T T INT# (0) INT# (0) T T PLK_PM (0) T T T L:match to within 000 = Length of PI feedback and onboard devices = R _ R _ R _ R _ R0 R0 R *0K_ 0K_ K_ T T IRST# () PIRST# (0) T V LP_LK_ () T PI_LK_UG () PI_LK_UG () V V V TRY# PRR# VSL# RQ# IRY# FRM# SRR# STOP# RQ# RQ0# LKRUN# RQ# SRIRQ 0 0 PI_PM# RP.KX_0PR RP.KX_0PR R LOK YPSS 0 0 RP.KX_0PR R P_ P_ P_ P_ MI solution 0K_ INT# INT# INT# INT# LRQ# LRQ#0 RQ# L0 L L L *.K_ LP_LK_ PLK_PM PI_LK_UG R PI_LKIN V V_S V V V PROJT : ZO Quanta omputer Inc. Size ocument Number Rev MP(PI/LP/JTG) ate: Wednesday, pril, 00 Sheet of 0

10 () LN_TX0 () LN_TX () LN_TX () LN_TX () LN_TXLK () LN_TXTL (,) P[..0] () ST_TXP0 () ST_TXN0 (,) P[..0].V_RMGT INT LFT US XT US(PJ) LUTOOTH INT LFT US T () LN_RX0_R () LN_RX_R () LN_RX_R () LN_RX_R () LN_RXLK_R () LN_RXTL_R () () () () () () P[..0] P[..0] H_SIN USP USP- US_RIS_ ST_THRM LK_KX LK_KX LN_RXR LN_OL LN_RS MII_PWRN LN_INT MII_MHZ_R MIIRST# RGMII_VRF MP_GPIO MP_GPIO USO#0 USO# USO# USO# USO# ST_RXP ST_RXN ST_RXP ST_RXN ST_RXP ST_RXN PIOR#_R L_T_P I_OMP_V I_OMP_V_ R VRT RTRST# H_SOUT H_SYN H_RST# USP () USP- () USP () USP- () () () H_ITLK () H_SIN0 () H_SIN.K for MP only USP- RN USP USP RN USP- USP0 USP0- USP USP- () USP W US_P US_P W USP () () USP- W US_N US_N W USP- () USP USP- USP USP- % pull-down to for other MP models :Z timing issue, modify to P P_ P_ R R R0 LN_TX0_R LN_TX_R J K R0 _ LN_TX_R L R _ LN_TX_R L R _ LN_TXLK_R H R _ LN_TXTL_R K R R R 00.0U_.0U_ T T T T0 R *0M_ LN_RX0_R 0 LN_RX_R 0 LN_RX_R LN_RX_R F LN_RXLK_R G LN_RXTL_R J0 Y.KHz U0./F_ MII_OMP_PV./F_ MII_OMP_ MII_OMP_PV MII_OMP_.K/F_ T T.K/F_ T ST_TXP0_ ST_TXN0_ ST_0_TX_P ST_0_TX_N ST_TXP_ ST_TXN_ ST TX_P ST TX_N ST_TXP G ST_TXN G ST_TXP G ST_TXN G J H RGMII_TX0/MII_TX0 MP RGMII/MII_M K0 RGMII_TX/MII_TX OF RGMII/MII_MIO L0 RGMII_TX/MII_TX MII_RXR/GPIO_(V_S) RGMII_TX/MII_TX MII_OL/MI_T J RGMII_TXLK/MII_TXLK MII_RS/MI_LK RGMII_TXTL/MII_TXN RGMII/MII_PWRWN#/GPIO_(V_S) RGMII/MII_INTR/GPIO(V_S) RGMII_RX0/MII_RX0 RGMII_RX/MII_RX RGMII_RX/MII_RX UF_MHZ G RGMII_RX/MII_RX LN MII_RST# RGMII_RX/MII_RXLK RGMII_RXTL/MII_RXV MII_VRF H0 U US0_P U US0_N U US_P U US_N W US_P W US_N US_RIS_ ST_0_TX_P ST_0_TX_N ST TX_P ST TX_N ST_TRMP P0 F0 P I_T_P0 L P I_T_P K P I_T_P K P I_T_P K P I_T_P J P I_T_P L P I_T_P L P I_T_P J P I_T_P K P0 I_T_P L P I_T_P0 J P I_T_P J P I_T_P L P I_T_P K P I_T_P G0 I_T_P XTLIN_RT MP H H_ITLK H_OK_N#/GPIO_(V_S) H_OK_RST#/GPIO(V_S) H_ST_IN0/GPIO_(V_S) H_ST_OUT/GPIO_(V) H_ST_IN/GPIO_(V_S)/MGPIO_0 H_SYN/GPIO_(V) H_ST_IN/GPIO_(V_S)/MGPIO_ H_RST# US_P US_N US0_P US0_N US_P US_N L ST_0_TX_P L ST_0_TX_N J ST TX_P J ST TX_N H XTLOUT_RT US US_O0#/GPIO_(V_S) T US_O#/GPIO_(V_S) T US_O#/GPIO_(V_S) T US_O#/GPIO_(V_S)/MGPIO_ T US_O#/GPIO_(V_S)/MGPIO_ T ST PT RT US_P U US_N U US_P V US_N V US_P Y US_N Y US_P US_N US_P US_N ST_0_RX_P G ST_0_RX_N G ST RX_P ST RX_N ST_0_RX_P H ST_0_RX_N H ST RX_P F ST RX_N F ST_0_RX_P L ST_0_RX_N K ST RX_P K ST RX_N K ST_L#/GPIO_(V) I_R_P0 I_R_P I_R_P I_S_P# J I_S_P# K I_K_P# J I_IOW_P# J0 I_INTR_P H0 I_RQ_P K I_IOR_P# L0 I_RY_P K0 L_T_P/GPIO_(V) F I_OMP_PV I_OMP_.V_VT RT_RST# G P0 P H P M K N M L: GMII_MHZ_R should <00mil,P R VRT R R R R T T T T T T T T RN0 USO# USO# USO# USO#0 R V *.K_ *0K_ R _ 0K_.K/F_.K/F_ R _ R R ST_RXP0 () ST_RXN0 () ST_L# () K_ /F_ /F_ MLK () MIO () LN_INT () MII_MHZ () MIIRST# () PS# () PS# () PK# () PIOW# () IRQ () PRQ () PIOR# () PIORY () V.V_RMGT MINI R XT US(PJ) NW R 0KX_PR 0K_ V_S H H_SOUT H_SYN H_ITLK H_RST# MII_MHZ MIIRST# H_SOUT 0 H_SYN H_RST# 0 H_ITLK 0 R 0_ US PULL-OWN USP0 RN USP0- USP USP- RN USP RN USP- USP RN USP- MP STRPPING H_RST# (LN) 0 MII RGMII (FULT) H_SOUT_R, LFRM# (IOS) 00 LP (FULT) 0 PI IOS 0 SPI IOS RSRV (SPI) MP_SPKR (oot MO) 0 USR TL (FULT) SF TL H_SYN_R (SIO LOK) 0.MHz (FULT) MHz SPI_O, SPI_LK (SPI LOK) 00 MHz 0 MHz 0 MHz MHz RT : MI Solution : MI Solution NOT: charger : RMOV R0 VPU 0MIL 0MIL VRT_ VRT_ R0 KX_ KX_ KX_ KX_ R K_ USP RN USP- USP RN USP- USP RN USP- USP0- RN USP0 V_S V V V V V_S V_S VRT LN_RXR LN_OL LN_RS RTRST# R R RT_HG RT_HG Q 0K_ 0K_ MMT0 N RT_ONN R _ R _ R0 _ R _ R _ R _ R0 _ R0 _ 0 0P_ *.K_ 0P_ 0P_ 0P_ 0P_ H00H.U_ U_ H00H RT_HG 0MIL H_SOUT_O () H_SOUT_M () H_SYN_O () H_SYN_M () H_ITLK_O () H_ITLK_M () H_RST#_O () H_RST#_M () KX_ KX_ KX_ KX_ R00 R0 R R R R R R R R R R R R R R R R R0 0K_ *0K_ *.K_.K_ *.K_.K_ *0K_ 0K_ *0K_ 0K_ 0K_ *0K_ *0K_ 0K_ M_.K/F_ USP- RN USP USP RN USP- USP USP- USP0 USP0- USP USP- USP USP- USP RN USP- H_RST# H_SOUT H_SYN *0K_ KX_ KX_ KX_ KX_ LFRM# (,,,) MP_SPKR (,) MP_SPI_O () MP_SPI_LK () SM_INTRUR# () G *SHORT_ P *0K_ *0K_ U_ VPU R.K_ R K_ PROJT : ZO Quanta omputer Inc. *KX_ Size ocument Number Rev MP(LN/H/US/H/RT) ate: Wednesday, pril, 00 Sheet 0 of 0

11 U0F (,,) PWROK_ () () RSMRST# elay 0ms after S powerok T (0) MP_SPI_O Strap pin only (0) MP_SPI_LK GT0 RIN# _SI# MP_LI# PLK_SM PT_SM SM_LRT# MSM_LK MSM_T MSM_LK MSM_T HTV_N PWRTN# RSTTN# SIO_PM# RI# MP_GPIO P MP_GPIO N MP_GPIO_I0 R MP_GPIO_I M MP_GPIO_I M0 XTL Y MHZ XTL HTV_V HTV_N () PLK_SM SM_LK0 SM_LK/MSM_LK MSM_LK () () PT_SM G SM_T0 SMUS SM_T/MSM_T F MSM_T () () () GT0 RIN# () NSWON# () PI_WK# () KSMI# () MP_LI# _SI# PU LGY PULL-UP SM/I PULL-UP U_ R _ : changed P value VPU R 0_ T T P_ R R R R R R R R R *0K_ *0K_ V V V_S HyperTransport Link. V_HT Power Valid.K_.K_.K_ *.K_ *.K_.K_.K_ T0 L Q N00 K 0GT/GPIO_(V) PU LGY K R0 PWRTN# P RSTTN# H P_WK#/GPIO_(V_S) P XT_SMI#/GPIO_(V_S) P M P PWRG PWRG_S KRRSTIN#/GPIO_(V) LI# RI#/GPIO(V_S) V R0 M_.V MX: PMU SIO_PM#/GPIO_(V_S)/SPI_S GPIO GPIO_(V_S)/PWRN_OK/SPI_S GPIO_(V_S)/NMI/PS_LK0 GPIO_(V_S)/SMI#/PS_T0 GPIO_(V_S)/SI/INTR/PS_LK GPIO_(V_S)/INIT#/PS_T MP MP PUV_N M OF MPV_N/HTV_N N MM_VL M PU_VL PWRGOO M MP_VL/HT_VL P LOK HT_VL SM_LRT# SUSR# SLP_RMGT# PM_T# MP_GPIO T SW_MP_VI SW_MP_VI0 SIO_LK THRM_LRT# () Q0 O0 SM_LRT#/GPIO_(V_S).V_HT MX:. 0U-.V_ SPKR INTRUR# SLP_S# SLP_S# SUS_LK/GPIO_(V_S) SLP_RMGT# LL# THRM#/GPIO_(V) F K L R R P P N0 K FNTL/GPIO_(V) F FNTL0/GPIO_(V) F FNRPM0/GPIO_0(V) F PMU PULL-UP R.V_HT SUSR# R 0_ R SUS_LK_R T0 T 0K_ HT_VL_R R0 R RSTTN# PI_WK# RI# MP_GPIO PM_T# KSMI# NSWON# VPU SIO_PM# HT_VL_V# PU_VRON () HWPG_.V (,) PU_ORPG (,) MP_SPKR (0,) SM_INTRUR# (0) SUS# () SUS# () *K_ k pull-down to on SW_MP_VI0 *0_ VOR.I VOR.I0 *0_.VSUS MP_GPIO THRM_SI/GPIO_(V_S)/PWR_L# R0 00_ MP_SI MIL_L# THRM_SI/GPIO_(V_S) R 00_ M MP_SI R 00_ SPI_I/GPIO_(V_S) THRM_SI0/GPIO_(V_S) J confirm by n-vidia F 0/ MP_GPIO0 SPI_O/GPIO_(V_S) K MP_GPIO T SPI_S0/GPIO_0(V_S) MP_VI/GPIO_(V) H T K VOR.I_R R0 0_ SPI_LK/GPIO_(V_S) MP_VI/GPIO_(V) H VOR.I0_R MP_VI0/GPIO_(V) H R 0_ MP_GPIO T M GPIO_(V)/SUS_STT/LMTR_XT_TRIG# P_ R 0K_ H H XTLIN XTLOUT Q N00 UF_SIO_LK LKOUT_MHZ J K R T *K_ R 0_ U_ R 0K_ R Q MMT0 R0 R R R R0 R R0 R0 K_ V R 0K_ VOR.I () VOR.I0 () HT_VL *0K_ *0K_ *0K_ *0K_ *0K_ *.K_ *0K_ *0K_ V_S : HNG P FROM 0.U TO U FOR LY HT_VL Q N00 FOR SLP MO OR POWR IRIUT.V_S SUS# SLP_RMGT# M/ I for "/"/" : Mount Q, unmount R SLP_RMGT# V_S VPU V_S I0 I I M/ " 0 0 X 0 0 " 0 0 " U 0 X 0 " " U.V_RMGT : Mount Q0,Q,R,R, unmount RR R 0K_ R *0K_ R0 *0_ R 0K_ R K_ R R 0K_ R *0K_ *0_ Q O0 O0 Q0 Q N00 R IV@0K_ R V@0K_ R *0_.V_RMGT MP_GPIO_I0 MP_GPIO_I MP_GPIO_I PROJT : ZO Quanta omputer Inc. Size ocument Number Rev MP(SM/GPIO/LK/PMU) ate: Wednesday, pril, 00 Sheet of 0

12 .V_UL.V_PLL_SP_SS.V_HMI.V_PLL.V_PLL_SP_V.V_RMGT.V_HT_PLL.V_R.V_PLL.V_RMGT.V_PLL_M_UL V_UL.V_P.V_P.V_HT_MP.V_SP_.V_SP_.V_PLL.V_PLL.V_PLL V.V_IFP.V_PLL_IFPP.V_PLLP.V_PLLP_SS.V_US_UL.V_SP_ V V.V_HT V.V_S.V.V.V.V_RMGT.V.V_HT.V_RMGT V V V_S.V.V.V_OR.V.V.V.V_HT.V_RMGT.V.V_OR V_S.V V.V V.V.V_OR Size ocument Number Rev ate: Sheet of MP(POWR/) 0 Wednesday, pril, 00 Size ocument Number Rev ate: Sheet of MP(POWR/) 0 Wednesday, pril, 00 Size ocument Number Rev ate: Sheet of MP(POWR/) 0 Wednesday, pril, 00.V_R m V m mil / 0mil mil / 0mil mil / 0mil 0m mil / 0mil.V_HMI V mil / 0mil 00m.V_PLLP m.v_us_ul.v_sp_ mil / 0mil mil / 0mil MP POWR PLN/ & YPSS.V_PLL_SP_V mil / 0mil.V_IFP mil / 0mil m m m mil / 0mil 00m.V_PLLP_SS mil / 0mil 0m 00m MP Unused UM Power mil / 0mil m 0m.V_P m.v_rmgt.v_ul.v_ifp.v_p V_UL 0m.V_PLL_IFPP.V_PLL_SP_SS mil / 0mil m 0m.V_HMI.V_PLL_M_UL m TR WITH / SPING : 0m.V_PLL mil / 0mil mil / 0mil 0m.V_SP_ omponent.v_pll_ifpp.v_pll MP Signal Name.V_HT_PLL mil / 0mil.V_RMGT m La Lb : reserv for.v power source : HNG TO 00, L HNG TO X0U0000, R HNG TO 00 L TI00U00_ L TI00U00_ U_.U_ R 0_ R 0_ L TI00U00_ L TI00U00_ L *TI00U00_ L *TI00U00_.U_.U_.U_.U_ L TI00U00_ L TI00U00_.U_.U_ POWR MP OF PI- ST PU UM PI- ST LN US U0 MP POWR MP OF PI- ST PU UM PI- ST LN US U0 MP.V_P V.V_P W.V_P W.V_P V.V_P Y.V_P Y.V_P Y.V_P Y.V_P Y.V_P W.V_P W.V_P Y.V.V Y.V.V.V.V W.V 0.V.V V0.V0 V.V W0.V Y0.V Y.V V.V.V.V Y0.V U.V U.V0 W.V Y.V U.V.V V.V.V.V.V W.V.V_HT Y.V_HT Y.V_HT Y.V_P W.V_SP_.V_SP_.V_SP_.V_SP_.V_SP_.V_SP_ 0.V_SP_ 0.V_SP_ 0.V_SP_ 0 0 H 00 0 Y 0 0 M U 0 0 V R 0 N G Y F V M M F 0 H M F F M G L P 0 V L P.V_PLL_PU_HT.V_PLL_PU._PLL_ISP N.V_RG_.V_TV_ F.V_IFP.V_IFP.V_HMI H.V_IFP_HV.V_HMI_PLL_HV.V_PLL_P_SS P.V_PLL_P_SS P0.V_PLL_SP_V W.V_PLL_SP_SS V.V_PLL_SP_SS R.V_PLL_LG P.V_UL_RMGT N.V_UL_RMGT L.V_PLL_M_UL N.V_R V.V_R V.V_R W.V_R W.V_UL N.V_UL N.V_PLL_P R0.V_PLL_P R.V_PLL_P_SS U.V_PLL_P_SS U0.V_UL L.V_UL L.V J.V G.V F.V H.V_US_UL Y.V_US_UL Y.U_.U_ *U_ *U_ 0.U_ 0.U_ L TI00U00_ L TI00U00_ U_ 0.U_ U-.V_ 0 0U-.V_ R *0_ R *0_ 0 0 U-0V_ U-0V_ L TI00U00_ L TI00U00_ 0 0 U_ U_ 0 0 *U_ *U_ R 0_ R 0_ *U_ *U_ R 0_ R 0_ U_ U_ 0 0U-.V_ 0 0U-.V_ 00 0U-.V_ 00 0U-.V_ *U_ *U_ U_ U_ R0 TI00U00_ R0 TI00U00_ R0 TI00U00_ R0 TI00U00_ U_ U_ L TI00U00_ L TI00U00_ U-0V_ U-0V_ 00.U_ 00.U_.U_.U_ L PY00T_ L PY00T_ U_ U_ 0 0 U_ U_ 0 U-0V_ 0 U-0V_ U_ U_ L 0_ L 0_ L *0_ L *0_ *U_ *U_ L 0_ L 0_ 0.U_ 0.U_ U-0V_ U-0V_ U_ U_ Quanta omputer Inc. PROJT : ZO Quanta omputer Inc. PROJT : ZO L PY00T_ L PY00T_ *U_ *U_ R TI00U00_ R TI00U00_ * * U-0V_ U-0V_ MP OF U0G MP MP OF U0G MP J J Y Y N M J 0 U N M R R U H M H T 0 R H R G G J R T 0 T J W M R V N M 0 F N L G H N R R 0 F H P V0 J N WUS_T0 0 WUS_T WUS_T Y0 WUS_T Y WUS_T W WUS_T W0 WUS_T W WUS_T V WUS_V WUS_VRF WUS STTUS WUS_T_N WUS_PLK WUS_PHY_RST# WUS_RX_N WUS_SRIL_T WUS_STOP WUS_TX_N M K 0 N H V L 0 J 0 N G G P T J J 0 U T0 M F J G F F 0 G M R G N0 N M M 0 V J L P H L M U U0 N 0 L J J 0 J G G0 V F 0 F0 0 V J F T J Y 0 T Y P J R N T WUS_PHY_TIV.U_.U_ U_ U_.U_.U_ * * *U_ *U_ U_ 0.U_.U_.U_.U_.U_ 0 *U_ 0 *U_ 0U_ 0U_ 0U-.V_ 0U-.V_ * * *U_ *U_ U_ U_ L TI00U00_ L TI00U00_.U_.U_ 0 0.U_.U_ L 0_ L 0_.U_.U_ * *.U_.U_ 0 0U-.V_ 0 0U-.V_ L V@PY00T_ L V@PY00T_ * * U/.V_0 U/.V_0 L PY00T_ L PY00T_ U_ U_

13 VIN N N mp 0.mp.mp 0.mp.mp V V 0.V.V PWR_SR PWR_SR PWR_SR PWR_SR PWR_SR PWR_SR PWR_SR PWR_SR VRUN VRUN VRUN VRUN VRUN VRUN VRUN VRUN VRUN VRUN VRUN VRUN PWR MXM_ONN_RVS PI-xpress LK_RQ# PX_RST# PX_RFLK# PX_RFLK PX_RX0# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX0# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX# PX_RX0 PX_RX PX_RX PX_RX PX_RX PX_RX PX_RX PX_RX PX_RX PX_RX PX_RX0 PX_RX PX_RX PX_RX PX_RX PX_RX PX_TX0# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX0# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX# PX_TX0 PX_TX PX_TX PX_TX PX_TX PX_TX PX_TX PX_TX PX_TX PX_TX PX_TX0 PX_TX PX_TX PX_TX PX_TX PX_TX SPIF/I PRSNT# PRSNT# PG_RXN0 PG_RXN PG_RXN PG_RXN PG_RXN PG_RXN PG_RXN PG_RXN PG_RXN PG_RXN PG_RXN0 PG_RXN PG_RXN PG_RXN PG_RXN PG_RXN PG_RXP0 PG_RXP PG_RXP PG_RXP PG_RXP PG_RXP PG_RXP PG_RXP PG_RXP PG_RXP PG_RXP0 PG_RXP PG_RXP PG_RXP PG_RXP PG_RXP PG_TXN0 PG_TXN PG_TXN PG_TXN PG_TXN PG_TXN PG_TXN PG_TXN PG_TXN PG_TXN PG_TXN0 PG_TXN PG_TXN PG_TXN PG_TXN PG_TXN PG_TXP0 PG_TXP PG_TXP PG_TXP PG_TXP PG_TXP PG_TXP PG_TXP PG_TXP PG_TXP PG_TXP0 PG_TXP PG_TXP PG_TXP PG_TXP PG_TXP PI_RST# () LK_MXM# () LK_MXM () PG_RXN[:0] () PG_RXP[:0] () PG_TXN[:0] () PG_TXP[:0] () (,) (,) MT MLK () () V_LVS_LLK# V_LVS_LLK () V_LVS_VN () V_LVS_LON () () () () () () () () () () () () V_LVS_LK V_LVS_T V_RT_HSYN V_RT_VSYN () () () () () () V_LVS_LTX#0 V_LVS_LTX# V_LVS_LTX# V_LVS_LTX0 V_LVS_LTX V_LVS_LTX V_RT_R V_RT_G V_RT_ V_RT_LK V_RT_T V V_TV_Y/G V_TV_/R V_TV_OMP Q V@N00 N pin "" for S/PIF input.an unconnected to V.V.V P0_PRSNTX_R R 0_ P0_PRSNTX () R *0_ R V@.K_ LVS_ULK# 0 LVS_ULK LVS_UTX0# LVS_UTX# LVS_UTX# LVS_UTX# LVS_UTX0 LVS_UTX LVS_UTX LVS_UTX LVS_LLK# LVS_LLK LVS_LTX0# LVS_LTX# LVS_LTX# LVS_LTX# LVS_LTX0 LVS_LTX LVS_LTX LVS_LTX LVS_PPN LVS_LN LVS_L_RGHT _LK _T VG_HSYN VG_VSYN VG_R VG_GRN VG_LU _LK _T TV_Y/HTV_Y/TV_VS TV_/HTV_Pr TV_VS/HTV_Pb LVS RT TV VI VI- VI- IGP & RSV VI LK# 0 VI LK 0 VI TX0# VI TX# VI TX# VI TX0 VI TX VI TX VI HP 0 _LK 0 _T Remove IGP/VI LK# IGP/VI LK IGP/VI TX0# 0 IGP/VI TX# IGP_/VI TX# IGP/VI TX0 0 IGP/VI TX IGP_VI TX VI HP/ IGP T IGP IGP T IGP T T IGP T IGP IGP T IGP T0 T IGP IGP T IGP T T RSV RSV RSV RSV RSV RSV R V@0_ () THRM_LRT_VG# R *V@0_ THRM# RUNPWROK MT_MXM MLK_MXM SM_T /TT# R *.K_ Q V@N00 SM_LK V@S R V@.K_ V@0U-V_ V@ PWROK_MXM () PWROK_ (,,) V IN (,) MXM_ONN_RVS : for MXM power up sequence, use PWROK_ to MXM PWROK, Mount R VIN V V@.U-V_ V@.U-V_ V@.U-V_ V@.U/V_ V@U_ V@ V@0U-V_ V@ V@U_ V@ PROJT : ZO Quanta omputer Inc. Size ocument Number Rev MXM Wednesday, pril, 00 ate: Sheet of 0

14 LVS SINGL_H RT () () () () () () () () () () () () () () V_RT_HSYN V_RT_VSYN V_RT_LK V_RT_T () () V_RT_R V_RT_G V_RT_ INT_RT_R INT_RT_GRN INT_RT_LU INT_HSYN INT_VSYN INT_RT_LK INT_RT_T () () () () () () () () () () () () () () () () () () () () L POWR V_TV_Y/G V_TV_/R V_TV_OMP V_LVS_LLK# V_LVS_LLK V_LVS_LTX#0 V_LVS_LTX0 V_LVS_LTX# V_LVS_LTX V_LVS_LTX# V_LVS_LTX INT_TV_Y/G INT_TV_/R INT_TV_OMP () () INT_LVS_IGON V_LVS_VN lose MXM ONN <demo circuit> restline suggest 00K G suggest 0K(ZS efault) Unstuff R for V_LVS_VN signal lose MXM ONN TV Out (SVHS) MiniIN -pin R0 R R R R R R R R R R R R R R R R R R0 R IV@0X_ IV@0X_ IV@0X_ IV@0X_ V@0X_ V@0X_ V@0X_ V@0X_ V@0_ V@0_ V@0_ IV@0_ IV@0_ IV@0_ V@0_ V@0_ V@0_ V@0_ V@0_ V@0_ V@0_ IV@0_ IV@0_ IV@0_ IV@0_ IV@0_ IV@0_ IV@0_ R R RN RN RN RN0 RN RN RN RN IV@0_ V@0_ SYS_TV_Y/G SYS_TV_/R SYS_TV_OMP V ISP_ON R IV@0K_ SYS_VG_R SYS_VG_GRN SYS_VG_LU HSYN VSYN RTLK RTT U IN IN ON/OFF T0 SYS_TV_/R V V OUT LV_ RTV SYS_VG_R SYS_VG_GRN SYS_VG_LU V (0) (0) : hange L,L,L0 P/N L0 R 0/F_ TXLLKOUT TXLLKOUT- INT_TXLLKOUT- INT_TXLLKOUT INT_TXLOUT0- INT_TXLOUT0 INT_TXLOUT- INT_TXLOUT INT_TXLOUT- INT_TXLOUT USP- USP TXLOUT- TXLOUT TXLOUT- TXLOUT TXLOUT0- TXLOUT0 TXLLKOUT- TXLLKOUT TXLOUT TXLOUT- TXLOUT0 TXLOUT0- TXLOUT TXLOUT- lose to ONN N dison-- 0 Modify the LVS pin difinition L_V 0U-.V_ : dd,, for MI solution U V_SYN V_ YP V_VIO VIO_ VIO_ VIO_ M00 VSYN HSYN VSYN HSYN RTLK RTT LK_ T_ L_ILK L_IT L_ON RIGHTNSS R 0/F_ P_ R 0/F_ VIN_L L_V _PWR RTV RT_R RT_G RT_ L_ON () _PWR RTVSYN RTHSYN N0 K0LL0_ S_VIO L K0LL0_ TV-HROM TV-LUM SYS_TV_Y/G P_ R 0_ 0U-.V_ R0 0/F_.U_ 0P_ 0P_ 0P_ 0.0U_ NHW L L L SYN_OUT SYN_OUT SYN_IN SYN_IN _IN _IN _OUT _OUT N ON0X_0 K0LL0_ K0LL0_ K0LL0_ L L 0P_ R R P_ 0 0P_ 0P_ LM0SN_ LM0SN_ P_ V V RIGHTNSS V VIN RTV R *0_ R 0 PWR VIN_L : unstuff Q, mount R for saving Q.K_.K_ 0 R 0/F_ N RT_ONN T_ RTHSYN RTVSYN LK_ R.K_.U-V_ R 0_ R.K_ R0 0_ R 0_ Q *O 000P-V_ RT_SNS# () 0U-.V_ 000P_ Remove HMI L_KLT_TRL () _L_KLT_TRL () () () () () V V_LVS_LK INT_LVS_ILK V_LVS_T INT_LVS_IT RTV RTVSYN RTHSYN LK_ T POWRON () V V L_ILK L_IT MR MOUL POWR R US UR'S SUGGSTION, *.K_ TI HNG FROM TO HIGH. onfirm by Joms Q *TU *0P_ *0P_ 0P_ 0P_ R R R R V@0_ IV@0_ V@0_ IV@0_ R.K_ R.K_ S Protect TV-OMP L K0LL0_ SYS_TV_OMP V V V R P_ P_ 0/F_ TV-OMP *0U TV-HROM *0U TV-LUM *0U PROJT : ZO Quanta omputer Inc. Size ocument Number Rev LVS/RT/TV-OUT/HMI Wednesday, pril, 00 ate: Sheet of 0

15 LN (0) LN_RXLK_R R _ LN_RXLK *P_ *P_ Transformer.V_RMGT R R R R.V_RMGT R 0_.V_RMGT.V_RMGT.0U_ (0) (0).0U_ *.K_ *.K_.K_.K_ MLK 0.0U_ MIO LN_TXLY LN_RXLY LN_LK (0) (0) (0) (0) (0) (0) L PY00T-00Y-N V_LN. LN_RX0_R LN_RX_R LN_RX_R LN_RX_R LN_RXTL_R.V_RMGT R 0_ R 0_ Q *N00.V_RMGT MII_MHZ (0) (0) (0) (0) (0) (0) R _ LN_RX0 R _ LN_RX R _ LN_RX R _ LN_RX LN_RXLK R _ LN_RXTL LN_RXLY LN_TX0 LN_TX LN_TX LN_TX LN_TXLK LN_TXTL :L HNG TO PY00T-00Y-N,(00) 0 Q *N00 T *P_ Y *MHZ *P_ R 0_ TRL LN_TXLY NS0:GIGIT U LNPHY_V_0 LN_MT0 TT MT LNPHY_MI0 LN_MX0 T MX LNPHY_MI0- LN_MX0- T- MX- LNPHY_V_ LN_MT TT MT LNPHY_MI LN_MX T MX 0 LNPHY_MI- LN_MX- T- MX- LNPHY_V_ LN_MT TT MT LNPHY_MI LN_MX T MX LNPHY_MI- LN_MX- T- MX- LNPHY_V_ 0 LN_MT TT MT LNPHY_MI LN_MX T MX LNPHY_MI- LN_MX- T- MX- NS0 0.0U_ : MI Solution LNPHY_MI0 LNPHY_MI0- LNPHY_MI LNPHY_MI- LNPHY_MI LNPHY_MI- LNPHY_MI LNPHY_MI- LN_TX# LN_RX# LN_GLINK0# LN_GLINK00# LN_GLINK000# MLK- MIO- LN_LK LN_GXTL LN_GXTL.V_RMGT V TRL TRL V 0 V V 0 V 0 V V V V V LN_FG0 LN_FG LN_FG LN_FG LN_FG LN_GRS LN_GOL LN_INT LN_FG LN_FG LNRST# LN_RST V LN_FG R.K_ LN_FG R.K_ LN_FG R0.K_ LN_FG R0.K_ PHY ddress:0000 R _ LNMT_G R00 _ R *M_ Q SK 000P-KV_0 R _ m 0U-.V_ 0U-.V_ R _ U RX0 RX RX RX RXLK RX_TL RXLY TX0 TX TX TX TXLK TX_TL TXLY TX/0 TX-/0- RX/ N/ N/- RX-/- N/ N/- MI0 MI0- MI MI- MI MI- MI MI- L_TX# L_RX# L_UPLX# L_LINK0# L_LINK00# L_LINK000# MLK MI/O LK XTL XTL RTL RTL 0/00/000--LN PHY m V0 V V V V V V0 V TRL V0 V V V V0 TRL V0 V V V LN_TX# LN_RX# LN_GLINK0# LN_GLINK00# LN_GLINK000# V_LN TRL.V_RMGT L onfiguration L_LINK000 L_TX 0 0 ONFIG0 ONFIG ONFIG ONFIG ONFIG RS/ONFIG OL/ONFIG INT/ONFIG ONFIG ONFIG PHYRST RST.V_RMGT Q SK 0U-.V_ 0m LN_INT (0) Set Register ontrol it= =LINK UP (NY SP) LINKING=TRNSMITTING OR RIVING R R 0_ R 0_.K_ *R00 *R00 *R00 *R00 *R00 LN_TL# LN_LINKL# 0 0P_ : MI solution RJ-.V_RMGT.V_RMGT LN_FG0 LN_GRS LN_GOL LN_INT LN_FG LN_RS LN_OL LN_INT ONFIG LN_FG :RGMII/MII TO OPPR LNRST# R 0_ R 0_ R R R R R0 R auto-na auto-na auto-na auto-na NVidia=.K Realtek=0K MIO R.K_ *R00 R 0_ 0P_ : MI solution R0 0P-KV_0 0P-KV_0 LN_TL# TIPL RINGL.K_.K_.K_.K_.K_.K_ RINGL TIPL LN_LINKL# LN_V LN_V 0 *0K/F_ LN_MX0 LN_MX LN_MX LN_MX N.V_RMGT.V_RMGT dvertise ll apabilities, Prefer Slave FI_SP_HF_J.V_RMGT.V_RMGT.V_RMGT MIIRST# (0) 0 N RING TIP L_GRN L_P_ L_ORNG L_YL L_P_ LN_MX- LN_MX- LN_MX0- LN_MX- RJ-&RJ- PROJT : ZO Quanta omputer Inc. Size ocument Number Rev RTL (GigaLN) Wednesday, pril, 00 ate: Sheet of 0

16 V_S (,) USON# U IN OUT IN OUT OUT N# - O# TPS0GNR R *.K/F_ USPWR 00U-.V_ 000P_ U VR_IRM-V0/TRI-P IRRX_ IR R R /F_ */F_ V_S V_S LI SWITH V : H/W Solution MINI ard (0) (0) (0) (0) H h-tcbcdp H h-cd0p- USP USP- T_L USP0- USP0 USP- USP H h-cd0p- : Hanged to 00 PU R0 0_ *RFM00M L R0 0_ USPWR US M port MXM FN USP0-_R USP0_R USP-_R USP_R H h-cdp- M LFT US LFT US H H H-TP H-TP H H H H H H0 h-tcbcdp h-tcbcdp h-tcbcdp h-tcbcdp h-tcbcdp h-tcbcdp H h-cd0p- H h-cdp H h-tcbcdp H h-cd0p- R 0_ *RFM00M L R 0_ H h-tcbcdp H H-P H H-P- H H-P- 00U-.V_ H H-P- 0 H h-tcbcdp H H-P- N H H-N N SYUIN_US 0 000P_ SYUIN_US H H-P- H H-P- IRRX_ : dd a Hole H0 H H0 h-cdp H-N H-N IRRX_ V_S V_S V_S : dd MI solution IRRX IRRX () () T_POWRON# P *MIP H h-cdn P *MIP P P *MIP *MIP P *MIP R0 0_ Q *MMT0 P0 P P P *MIP *MIP *MIP *MIP R *.K_ Q O# V Y R *.K_ P P *MIP *MIP *NSZPX P *MIP (0) (0) () S check MPLI# power VPU nda GPIO list have internal PU R *0K_ SS *SS R 0_ 0 VSUS R 0_ VSUS LUTOOTH MOUL ONNTOR Q O R 0_ R 0_ R *0K_ 0 000P_ R 00K_ SS R0 T_POWR 0U-.V_ 0.P_ T_POWR USP_R USP-_R T_L 0.P_ R R : Mount MI solution V@0K_/IV@.K_ Q TU V@0_ IV@0_ L_ON () MP_LI# () LI# () LI# () N T_ONN V_LVS_LON () INT_LVS_LON () _FPK# () H h-cd0p- H H-P- H H-P- H h-cd0p- P *MIP PROJT : ZO Quanta omputer Inc. Size ocument Number Rev US/LUTOOTH//IR ate: Wednesday, pril, 00 Sheet of 0

17 MINI-ard VSUS V : Modify net to close device side. V L K0LM-T_ If M.P must N all debug R L0 K0LM-T_ R R0 VMINI WS_LKR : add 0 for MI request. New card () 0 0P_ PI_WK# PI_WK# V_S () R 0_ VSUS Q *TU PP#_ () () Q *TU R0 *.K_ () () () () (,0,,) SRIRQ () LRQ#0 (,,) LP_RST# () PI_LK_UG () () () () () () () PI_TXP PI_TXN PI_RXP PI_RXN LK_PI_NW_ LK_PI_NW_# () PP# () NW_LKRQ# (0) (0) PI_TXP PI_TXN PI_RXP PI_RXN LK_PI_MINI LK_PI_MINI# MINI_LKRQ# PP# NW_V PRST# NW_VUX NW_.V R 0_ R 0_ R 0_ R 0_ NW_SMT NW_SMLK SRIRQ_RR LRQ#0_RR WS_TR WS_LKR MINI_RQ_LK Need reserve G pin define heck Footprint : dd R for NW card PP# R 0_ R 0_ PUS# R 0_USP_R R 0_USP-_R 0 0 N N PTp0 PTn0 PRp0 PRn0 MINIPI ONN_WL.V 0.V L_WPN# L_WLN# L_WWN# 0 US_ US_- SM_T SM_LK 0.V.Vaux PRST# 0 PTp0 0 PTn0 PRp0 PRn0 RFLK RFLK- PP# LKRQ#.V.V PRST#.VUX WK#.V.V SM_T SM_LK RSRV RSRV PUS# US_ US_- XPR-FOXONN 0 USP USP- RFLK RFLK- LKRQ# WK# 0.V.V V V_S.V V_S.V VMINI PI_RST# VSUSMINI V RF_L# RF_L# () USP (0) USP- (0) PT_SM () PLK_SM () PI_RST# () RF_N () LFRM# (,0,,) L (,,) L (,,) L (,,) L0 (,,) NW R'S POWR SWITH NW_VUX PP# PUS# PRST#_R R0 NW_VUX.V NW_V NW_.V PP# : ( Internal Pull Up, active low when card support PI ) PUS# : ( Internal Pull Up, active low when card support US ) SHN# : ( Internal Pull Up ) 0_ 0 R *0_ 0 S RP 0X_ RP 0X_ R 0_ U TPSPWG.VIN.VOUT.VIN.VOUT UXIN.VIN.VIN SYSRST# SHN# RLKN N *00U-.V_ *0_ UXOUT.VOUT.VOUT STY# PP# PUS# PRST# O# T 0.K/F 0 VSUSMINI PRST# 00P_ NW_V.V PT_SM PLK_SM 0 0 *.U_ NW_V.U_ Q N00 NW_V Q0 N00 00 NW_.V RP0.KX_ NW_SMT NW_SMLK.U_ PROJT : ZO Quanta omputer Inc. Size ocument Number Rev MINI PI- card & NW R Wednesday, pril, 00 ate: Sheet of 0

18 ST H TP SWITH N0 RXP RXN TXN TXP.V.V.V 0 V V V RSV V 0 V V ST-H ST_RXN0_.0U_ ST_RXP0_.0U_.VST R V V HV (0,) P[..0] (0,) P[..0] R R R R R *0_.0U_ 0K_ *0K_ 0K_.K_.K_ V.0U_ IRQ P PRQ PIORY ST_TXP0 (0) ST_TXN0 (0) ST_RXN0 (0) ST_RXP0 (0).VST HV () () IRST# IL# *.U_ 0.U_ *.U_ R 0_ TU V * V V 00U-.V_ Q R0 *0_ R 0K_ (0) (0) (0) (0) V R 0K_ IRST#_R P P P P P P P P0 PIOW# PIOW# PIORY PIORY IRQ IRQ P P0 PS# PS# V_O 0 RSL 000P_ R 0_ P P P0 P P P P P PRQ PIOR# PIG# R P PS# () () O (PT) N LFT# RIGHT# TPT TPLK SR_UP# TP ONN PK# MI near N V_O TPT TPLK SW MISKI_SWITH_. SW MISKI_SWITH_. SW MISKI_SWITH_. R R : dd MI solution PRQ (0) PIOR# (0) PK# (0) *0K_ PS# (0) 00mil V 00U-.V_ V SR_N# SR_LFT# SR_RIGHT# SW MISKI_SWITH_. SW MISKI_SWITH_. SW MISKI_SWITH_. mil L KP0HST. TP_V V.K_ V.K_ N L LZ0-0MT 0. TPT_R L0 LZ0-0MT 0. TPLK_R RIGHT# SR_RIGHT# SR_UP# P_ SR_LFT# 0 SR_N# 0 P_ LFT# L 0_ TOUH_P_TP_P O_ONN PROJT : ZO Quanta omputer Inc. Size ocument Number Rev ST-H & PT-O ate: Wednesday, pril, 00 Sheet of 0

19 O(L) V L V_O INT MI array V.V SPK SPK OUT eep O O V_O SPIFO R0 0_ R0 R 0_ L_JRF P L SPIF_OUT_ K00LL 0. PP O HP Jack R00 FRONT-L FRONT-R 0K/F_ Z_V INSPKR-N INSPKRN INSPKL-N INSPKLN V P_ SURR-L SURR-R O MI-VRFO-R Z_SIN MI-VRFO-L L_VRF MP_SPKR (0,) V_O PP Z_V LIN-R LIN-L MI-R MI-L MI_INT_R MI_INT_L SNS MI_R MI-VRFO MI_L O :hanged, to.u H_SIN0 (0) () LIN-R_ LIN-L_ MI_R MI_L MI_INTL H_RST#_O (0) H_SYN_O (0) H_ITLK_O (0) H_SOUT_O (0) : MI Solution : hange power to VSUS SP_STY ON/OFF & HP_STY ON/OFF.V SP_STY ( pin) SP_STY ( pin) SP_STY ON/OFF ON M N R0 *0_ M VSUS OFF R 0_ OFF RSV OFF (0) H_SOUT_M _SO RSV.V VSUS HP_STY ( pin) HP_STY ( pin) HP_STY ON/OFF (0) H_SYN_M R _ H_SIN_M _SYN ON (0) H_SIN _SI 0 OFF (0) H_RST#_M _RST# _LK H_ITLK_M (0) OFF OFF 0 R 0P_ 0_ FRONT-L U_ FRONT-L- L L L L *0_ 0U-.V_ K0LL_ K0LL_ K0LL_ K0LL_ 0 U : MI Solution *P_ U_ 00P_ MONO-OUT V SURR-L JRF SURR-R VSS N N N MI-LK P SPIFO 0U-.V_ *P_ FRONT-R FRONT-L Sense V R0 R0 K_ MI-//GPIO0 0 *P_ MI-//GPIO N MI-VRFO-R GPIO MI-VRFO 0 L VSS 0K_ ST-OUT IT-LK VSS LIN-VRFO ST-IN MI-VRFO-L V VRF SYN 0 VSS RST# V PP 0P_ : MI Solution N SPKR_H. *P_ R0 0_ 0P_ LIN-R LIN-L MI-R MI-L -R 0 - -L MI-R MI-L N Sense N R0 _ 0P_ R0 R 0U_.K_.K_.U_.U_ U-V_ U-V_ U_ U_ SPK FRONT-R V () MP_MUT# MUT FUNTION P HP_MUT# *0U-.V_ R 0_ U_ 0U-.V_ FRONT-R- R V V R *0_ () () V_V O O IGVOL_N IGVOL_UP O V_V MUT_SPK MUT_HP V VN MI_L MI_R LIN-L_ LIN-R_ SPIFO SNS HPR HPL O G_Lv G_Lv G_ttack G_ON/OFF G_Recovery 0 G_Recovery FRONT-L- 0K_ 0P_ PROUT-L FRONT-R- 0K_ 0P_ PROUT-R V_O O O Vo=.*(RR)/R=.V O(L) Power G-attack-time selection G_ttack ( pin) ttack time ms ms G ON/OFF selection G_ON/OFF ( pin) G ON/OFF ON OFF R R U TSH0FU U TSH0FU *0_ TI00G 0 U_ R 0K_ 0K_ 0U-.V_ U_ *0_ R R 0 U_ U_ 0 0 N 0 0 SW-0P 0U-.V_ G-recovery-time selection G_Recovery (0 pin) G_Recovery ( pin) U_ U VN VIN *G-JTU VOUT U G_Lv G_Lv G_ttack V_V G_ON/OFF G_Recovery G_Recovery SP_INL PROUT_L SP_INR PROUT_R VRFSP N N J 0 V SP_STY SP_STY HP_STY HP_STY U_ V_P O V_HP R *K_ O Test V_SPR Panasonic _P 0 N _SPL R *K_ U_ Test R 0_ R 0_ R 0 SPR Test Test P P P P_ 000P_ 000P_ 000P_ V_O V_SPL P_ O Recovery Time.0 s.0 s.0 s.0 s P P P P P P 0 VSS VSS_P SP_OUTL SP_OUTL SP_OUTL SP_OUTL 0 SP_OUTR SP_OUTR SP_OUTR SP_OUTR HP_OUTL HP_INL HP_INR HP_OUTR P 0 P P V_V O HPINR MI_INTL O O : add, for MI request. N N0 INT_MI R *0K_ R 0K_ G-on-level selection INSPKL INSPKR- INSPKL- INSPKR- INSPKR INSPKL- INSPKL O SURR-R HPR MI-VRFO G_Lv G_Lv G_ttack G_ON/OFF G_Recovery G_Recovery G_Lv ( pin) G_Lv ( pin) G ON Level Output Po (RL= ohm). dv. W.0 dv.0 W. dv 0. W.0 dv 0. W INSPKR and R change from 0kohm to 0kohm HP HPL R 0K_.U_ HPINL R 0K_ SURR-L SURR-L P_ R 0K_ R *0K_ U_ U_ R R *P_ R *0K_ R 0K_ 0K_ 0K_ R *0K_ R 0K_ R.K_ R *0K_ R 0K_.U_ R *0K_ R 0K_ P -- ISOLT Richard 0/ -- Modify P to P_~ SURR-R PROJT : ZO Quanta omputer Inc. Size ocument Number Rev RLTK L & M Wednesday, pril, 00 ate: Sheet of 0

20 V U R : J0H R : J0H0 VSUS IN R RR RRR POWR 0 VSUS V_PI V_V 0 V_X V_X V_PI V_PI N 0U_.0U_.0U_ V_PI.0U_ 0U_ VSUS V_PI X_0/MS_0/S_0 ()S-V Q R V_PI X_/MS_/S_ ()S-T0 X_/MS_/S_ ()S-T 0 X_/MS_/S_ ()S-T ()X-V N00 0K_ Q V_RIN M_PWR_TRL_0# V_ROUT_ X_R#/LK ()S-T X_Z V_ROUT X_W#/MS_S/S_M ()S-LK ()X- X_R/#/S_WP# S_Z ()S-M ()X-R/ O0 0U_.0U_.0U_ V_ROUT X_R#/LK 0 V_ROUT X_R/#/S_WP# S- ()X-R X_#.0U_.0U_.U_.U_ V_ROUT S-WP ()X- 0 X_L V_ROUT ()X-L X_L 0mil V_X ()X-L V_X X_W#/MS_S/S_M M_PWR_TRL_0 V_M ()X-W X_WPO# ()X-WP R X_0/MS_0/S_0 (,) [..0] X_0/MS_0/S_0 ()MS-V (0)X-0 X_/MS_/S R.U_ X_/MS_/S R ()MS-T0 ()X- 0K_ X_/MS_/S R 0 0 X_/MS_/S R ()MS-T ()X-.0U_.0U_.0U_ X_/MS_/S_ 0 X_/MS_/S_ ()MS-T ()X- X_ X_R#/LK ()MS-T ()X- X_ MS_Z ()MS-SLK ()X- 0 X_ X_W#/MS_S/S_M ()MS-INS ()X- X_ VSUS ()MS-S ()X- U M_PWR_TRL_0 0 ()S/()MS/()X- SIO- IN N VSUS ()S/(0)MS/()X- SIO- 0 V_X 0 0 R_RR_TTN_R0-0-XX- IN VO 0 When HWSPN# is RQ# 0 *U_ *GTU GNT# INT#,# controlled by system, the R 0K_ pull-up resistor(r0) dose not need to apply. R 0/F_ PM_ISL 0 0 _SUS# V_X V_X 0 HWSPN# VSUS N X_0/MS_0/S_0 S-V PowerOnReset for Vccore MSN R 0K_ X_/MS_/S_ S-T0 X_/MS_/S_ S-T When GRST# is controlled by system, XN R 0K_ X_/MS_/S_ S-T X-V 0 R 00K_ X_R#/LK S-T X_Z the pull-up resistor(r0) and X_W#/MS_S/S_M S-LK X- X_R/#/S_WP# capacitor(0) do not need to apply. 0 UIO R *00K_ S_Z S-M X-R/ X_R#/LK PR 0 X_R/#/S_WP# S-/ X-R X_# () PR : pin pull-up can saving the # PR SL_R S-WP X- X_L () # # /# UIO S_R PROM, remove R, stuff R X-L X_L VSUS () # # /# UIO S-VSS X-L X_W#/MS_S/S_M () # PLK_PM 0# /# S-VSS X-W X_WPO# (,) 0# 0 PM_ISL /0# UIO S- X-WP R ISL X_0/MS_0/S_0 UIO 0 X_0/MS_0/S_0 MS-V X-0 X_/MS_/S R () RQ0# RQ# X_/MS_/S R MS-T0 X- 00K_ X_/MS_/S R () GNT0# SRIRQ (,,,) FRM# X_/MS_/S R MS-T X- 0 R GNT# UIO0/SRIRQ# X_/MS_/S_ () FRM# 0 GRST#_ IRY# FRM# X_/MS_/S_ MS-T X- X_ () IRY# TRY# X_R#/LK MS-T X- *_ IRY# X_ () TRY# VSL# TRY# MS_Z MS-SLK X- X_ () VSL# STOP# VSL# X_W#/MS_S/S_M MS-INS X- X_ () STOP# INT# () PRR# STOP# INT# MS-S X- 0 () PRR# 0 U_ SRR# PRR# () SRR# SRR# INT# INT# () 0 *P_ MS-VSS GRST#_ MS-VSS XG- PIRST# GRST# X- () PIRST# PIRST# () RT_V00 L U _V : changed P value K0HS0_ TPIS0 V_PHY R _XIN V_PHY 0 0_ V_PHY 0 R R0 XI 000P_ P_ V_PHY 0U_.0U_ Q.U_.0U_ Y TPIS0 X_/MS_/S R X_/MS_/S_ TPIS0./F_./F_.MHz TP0N X_/MS_/S_ TPN0 0 TP0P _XOUT TPP0 0 TP0N XO TPN0 0 *N00 TP0P TPP0 0 R *0K_ *L-M0-00JT P_ V X_ FIL0_PWR MIO X_ FIL0 MIO L X_ *.0U_ MIO X_ Q S LOS S TP0P L_TP0 MIO X_/MS_/S_ S_Z POSSIL TO TP0N L_TP0- RXT MIO 0 R 0 X_/MS_/S R *N00 RN 0X_ RXT MIO R X_/MS_/S R TP0P L_TP0 MIO RN 0X_ 0K/F_ X_0/MS_0/S_0 TP0N L_TP0- MIO0 0 VRF_PWR 00 X_WPO# VRF MIO0 X_W#/MS_S/S_M OMMON MO HOK MIO0 Q R0 R L.0U_ X_L X_/MS_/S R MIO X_L NR ONN. MIO X_# MIO0./F_./F_ S LOS S POSSIL TO X_R/#/S_WP# _OM MIO0 *N00 *L-M0-00JT R R and GUR S_Z X_Z VSUS R MIO00 0 R 0_ S MS_Z MIO0 0P_ S 0K_.K/F_ MS_S_LK X_R#/LK MIO0 R./F_ M_PWR_TRL_0 MIO0 TP_X_L# X_R#/LK should MIO0 T RSV MIO0 shield. N > ms >0 ns PROM L_TP0- L_TP0- RT_V00 0 0P_ L_TP0 MS_S_LK VSUS * NOT Use PROM : L_TP0 R0 : installed V R0,U,0 : NOT installed : MI Solution * Use PROM : R0,U,0 : installed GRST# R0 R _ONN R0 : NOT installed PRST# > 00 ns lose to ONN. 0K_ 0K_ U S_R S_Z MS_Z SL_R S 0 SL VSUS WP HWSPN# *0P_ *0P_ PROJT : ZO V PLK(MHz) PI_PM# () (,) PLK_PM R LKRUN# *0_ PLK_PM LKRUN# 0 PILK PM# LKRUN# PI / OTHR I/S TST Reduced external noise by F confirm VSUS Reserve MS UO card issue *L0 * : Remove U, PROONN-MXP N Quanta omputer Inc. Size ocument Number Rev R/(IN/) Wednesday, pril, 00 ate: Sheet of 0 0

Σχετικά έγγραφα

ZO3 SYSTEM BLOCK DIAGRAM

ZO3 SYSTEM BLOCK DIAGRAM ZO SYSTM LOK IGRM TV-OUT TFT L Panel WXG RT P P P INT or V selector Resistor P LVS TV-out RT H (ST) MXM P P PI-xpress X TV-out LVS VG ST0 M Sg ufpg Turion ual-ore/ Sempron Single-ore n-vidia MP P,,, HT

Διαβάστε περισσότερα

Z05 SYSTEM BLOCK DIAGRAM

Z05 SYSTEM BLOCK DIAGRAM Z0 SYSTEM LOK IGRM PU ORE / VN (ISL) PGE N_ORE.V (RT0) PGE.V_N (RT0) PGE RII-SOIMM PGE RII-SOIMM PGE RII /00 MHz RII /00 MHz Lion Sabie SG Processor P (upg)/w PGE,,, M Griffin PU THERML SENSOR PGE PU Fan

Διαβάστε περισσότερα

Kirin (FX2 with NS) VER : 1A

Kirin (FX2 with NS) VER : 1A Kirin (FX with NS) VR : RII-SOIMM PG, RII-SOIMM PG, MHz R II M S Turion Rev.F ual-ore/ Sempron Rev.F Single-ore ual-ore W / Single-ore W ( Sg socket) PG,,, PU VR PG LOKS PG Thermal Monitor SYSTM VP R II

Διαβάστε περισσότερα

COMPONENTS LIST BASE COMPONENTS

COMPONENTS LIST BASE COMPONENTS ITLIN TEHNOLOGY grifo PPENIX : R SSEMLY The GP F can be ordered in two different mode: completely mounted, tested and ready to use or in assembly kit. In this final condition the user can directly use

Διαβάστε περισσότερα

DISPLAY SUPPLY: FILTER STANDBY

DISPLAY SUPPLY: FILTER STANDBY ircuit iagrams and PW Layouts. ircuit iagrams and PW Layouts J.0 P. 0 isplay Supply P: ilter Standby MNS NPUT -Vac 00 P-V- V_OT 0 0 0 0 0 0 0 0 SPLY SUPPLY: LT STNY 0 M0 V 0 T,/0V MSU -VOLTS NOML... STNY

Διαβάστε περισσότερα

+3V3 Supply. +3V0 Flash + VCCPGMy +2V5 FPGA VCC + FPGA I/O +1V1 FPGA Core. Overview. abaxor engineering GmbH

+3V3 Supply. +3V0 Flash + VCCPGMy +2V5 FPGA VCC + FPGA I/O +1V1 FPGA Core. Overview. abaxor engineering GmbH 6 7 8 Supply +V0 Flash + PGMy +V FPG + FPG I/O +V FPG ore Overview 6 7 8 6 7 8 I0NK_ IO H IO P IO L IO J VRFN0 N IO/IFFIO_TX_L9N/IFFOUT_L9N IO/IFFIO_RX_L0N/IFFOUT_L0N/QL J IO/IFFIO_TX_L9P/IFFOUT_L9P/QL

Διαβάστε περισσότερα

HOST 133/166MHz PCIE 100MHz VGA 96MHz USB 48MHz REF 14MHz PG 4,5,6,7 PCI-E, 1X PCI-E, 1X. LAN 25MHz Xtal PG 10,11,12,13 USB2.

HOST 133/166MHz PCIE 100MHz VGA 96MHz USB 48MHz REF 14MHz PG 4,5,6,7 PCI-E, 1X PCI-E, 1X. LAN 25MHz Xtal PG 10,11,12,13 USB2. ES LOK IGRM RII-SOIMM PG, RII-SOIMM PG, / MHZ R II M S Sempron Rev.F Single-ore.G Single-ore W Normal, up to W ( Sg socket) PG,,, HOST /MHz PIE MHz VG MHz US MHz REF MHz LOK GENERTOR IS PG V_ORE +.V +VP

Διαβάστε περισσότερα

10. Circuit Diagrams and PWB Layouts

10. Circuit Diagrams and PWB Layouts ircuit iagrams and W ayouts Q... ircuit iagrams and W ayouts mbilight nterface: nterf. + Single / TR + S - V _SS RV_ SW_ T_ V T_ V_UT SW_T _S V STU VRSTS R / TR See the stuffing diversities table in the

Διαβάστε περισσότερα

HOST 133/166MHz PCIE 100MHz VGA 96MHz USB 48MHz REF 14MHz PCI-E, 1X PCI-E, 1X. PCIE3 & PCI Express Mini Card PG 19 PCI-E, 1X USB2.

HOST 133/166MHz PCIE 100MHz VGA 96MHz USB 48MHz REF 14MHz PCI-E, 1X PCI-E, 1X. PCIE3 & PCI Express Mini Card PG 19 PCI-E, 1X USB2. P P/N N ESRIPTI P E M(L,0X, REV) P/N: 0EM P E M(L,0X,REV) P/N: 0EM P E US/(L,.X., REV) P/N: 0ES P E US/(L,.X.,REV) P/N: 0ES E ST E ST SSY P/N E M S/S SSY P/N: ESS00 E M /S SSY P/N: ES00 E M SSY P/N: EM00

Διαβάστε περισσότερα

GND_COLD. +12Vd GND_COLD 1P15 GND_COLD GND_COLD. +12Vd B6B-PH-K 1M12. 3u3 F V I820 1M09. 3u3. +12Vd 1M0 F Vd 5406.

GND_COLD. +12Vd GND_COLD 1P15 GND_COLD GND_COLD. +12Vd B6B-PH-K 1M12. 3u3 F V I820 1M09. 3u3. +12Vd 1M0 F Vd 5406. ircuit iagrams and W Layouts Q. L.. ircuit iagrams and W Layouts isplay Supply ( ): art SLY SULY: RT TSK MS LTR MS UT -Vac T V K TS M n V R R R p V OT ROU OL ROU _OL _OL S VS V MO VM V OS OSOUT VSS OT

Διαβάστε περισσότερα

(#5 5::%%%$ " (#5 5::%%%$" %

(#5 5::%%%$ (#5 5::%%%$ % !" "#! " # $ "! "#" "" ""! % %! % " &"#!! "' (%)* (% (%! "' + "',! "' $% " %! "'% " %!"! #!" " $ #!" #$ #! #!#!" -%$!"#!".! "!"#!"! "!" " " "!!" "! %!"!#/ "%! %! #! )0+! *.." )0)!- % 67&* 6**&7*0.8 67&*67&*90&0.8

Διαβάστε περισσότερα

1951 {0, 1} N = N \ {0} n m M n, m N F x i = (x i 1,..., xi m) x j = (x 1 j,..., xn j ) i j M M i j x i j m n M M M M T f : F m F f(m) f M (f(x 1 1,..., x1 m),..., f(x n 1,..., xn m)) T R F M R M R x

Διαβάστε περισσότερα

QUANTA COMPUTER. Page Title of schematic page Rev. Date

QUANTA COMPUTER. Page Title of schematic page Rev. Date Page of schematic page Rev. ate 0 0 0 0 0 0 0 0 0 0 0 Index lock iagram hange ist OK NRTOR PROSSOR /(MI&HOST&PI) PROSSOR /(R) PROSSOR /(POWR) PROSSOR /() PH / (MI&VIO) PH / (ST/P/zalia) PH / (PI/PI/K/US)

Διαβάστε περισσότερα

RSDW08 & RDDW08 series

RSDW08 & RDDW08 series /,, MODEL SELECTION TABLE INPUT ORDER NO. INPUT VOLTAGE (RANGE) NO LOAD INPUT CURRENT FULL LOAD VOLTAGE CURRENT EFFICIENCY (Typ.) CAPACITOR LOAD (MAX.) RSDW08F-03 344mA 3.3V 2000mA 80% 2000μF RSDW08F-05

Διαβάστε περισσότερα

Network Neutrality Debate and ISP Inter-Relations: Traffi c Exchange, Revenue Sharing, and Disconnection Threat

Network Neutrality Debate and ISP Inter-Relations: Traffi c Exchange, Revenue Sharing, and Disconnection Threat Network Neutrality Debate and ISP Inter-Relations: Traffi c Exchange, Revenue Sharing, and Disconnection Threat Pierre Coucheney, Patrick Maillé, runo Tuffin To cite this version: Pierre Coucheney, Patrick

Διαβάστε περισσότερα

d dx x 2 = 2x d dx x 3 = 3x 2 d dx x n = nx n 1

d dx x 2 = 2x d dx x 3 = 3x 2 d dx x n = nx n 1 d dx x 2 = 2x d dx x 3 = 3x 2 d dx x n = nx n1 x dx = 1 2 b2 1 2 a2 a b b x 2 dx = 1 a 3 b3 1 3 a3 b x n dx = 1 a n +1 bn +1 1 n +1 an +1 d dx d dx f (x) = 0 f (ax) = a f (ax) lim d dx f (ax) = lim 0 =

Διαβάστε περισσότερα

Q π (/) ^ ^ ^ Η φ. <f) c>o. ^ ο. ö ê ω Q. Ο. o 'c. _o _) o U 03. ,,, ω ^ ^ -g'^ ο 0) f ο. Ε. ιη ο Φ. ο 0) κ. ο 03.,Ο. g 2< οο"" ο φ.

Q π (/) ^ ^ ^ Η φ. <f) c>o. ^ ο. ö ê ω Q. Ο. o 'c. _o _) o U 03. ,,, ω ^ ^ -g'^ ο 0) f ο. Ε. ιη ο Φ. ο 0) κ. ο 03.,Ο. g 2< οο ο φ. II 4»» «i p û»7'' s V -Ζ G -7 y 1 X s? ' (/) Ζ L. - =! i- Ζ ) Η f) " i L. Û - 1 1 Ι û ( - " - ' t - ' t/î " ι-8. Ι -. : wî ' j 1 Τ J en " il-' - - ö ê., t= ' -; '9 ',,, ) Τ '.,/,. - ϊζ L - (- - s.1 ai

Διαβάστε περισσότερα

Visual Systems Division Technical Bulletin MultiSync MT820/MT1020 Installation Data Desk Top and Ceiling Mount

Visual Systems Division Technical Bulletin MultiSync MT820/MT1020 Installation Data Desk Top and Ceiling Mount Visual Systems ivision ontents Notes and Formulas Page 1 Projection istances and Screen Sizes eiling Mount (Lens Wide) Page 2 eiling Mount (Lens Telephoto) Page 3 esktop Setup (Lens Wide) Page 4 esktop

Διαβάστε περισσότερα

ichip CO2128 with EBI Flash and Siemens HC25 GSM Modem

ichip CO2128 with EBI Flash and Siemens HC25 GSM Modem Reference Design ichip CO with EBI Flash and Siemens HC GSM Modem Revision History Version Date Description.0 May 00 Initial version.0 September 00 Changed from Mb Flash to Mb Flash Introduction This Reference

Διαβάστε περισσότερα

ΚΥΠΡΙΑΚΗ ΕΤΑΙΡΕΙΑ ΠΛΗΡΟΦΟΡΙΚΗΣ CYPRUS COMPUTER SOCIETY ΠΑΓΚΥΠΡΙΟΣ ΜΑΘΗΤΙΚΟΣ ΔΙΑΓΩΝΙΣΜΟΣ ΠΛΗΡΟΦΟΡΙΚΗΣ 19/5/2007

ΚΥΠΡΙΑΚΗ ΕΤΑΙΡΕΙΑ ΠΛΗΡΟΦΟΡΙΚΗΣ CYPRUS COMPUTER SOCIETY ΠΑΓΚΥΠΡΙΟΣ ΜΑΘΗΤΙΚΟΣ ΔΙΑΓΩΝΙΣΜΟΣ ΠΛΗΡΟΦΟΡΙΚΗΣ 19/5/2007 Οδηγίες: Να απαντηθούν όλες οι ερωτήσεις. Αν κάπου κάνετε κάποιες υποθέσεις να αναφερθούν στη σχετική ερώτηση. Όλα τα αρχεία που αναφέρονται στα προβλήματα βρίσκονται στον ίδιο φάκελο με το εκτελέσιμο

Διαβάστε περισσότερα

Modbus basic setup notes for IO-Link AL1xxx Master Block

Modbus basic setup notes for IO-Link AL1xxx Master Block n Modbus has four tables/registers where data is stored along with their associated addresses. We will be using the holding registers from address 40001 to 49999 that are R/W 16 bit/word. Two tables that

Διαβάστε περισσότερα

7. Schematic Diagram. 7-1 Overall Block Diagram FRONT MAIN MAIN CD SMPS (MAX-A54U)...

7. Schematic Diagram. 7-1 Overall Block Diagram FRONT MAIN MAIN CD SMPS (MAX-A54U)... 7. Schematic Diagram 7- Overall Block Diagram... 7-7- FRONT... 7-7- MAIN-... 7-7- MAIN-... 7-5 7-5 CD... 7-7- SM (MAX-A5U)... 7-7 7-7 SM (MAX-A55U)... 7- Samsung Electronics This Document can not be used

Διαβάστε περισσότερα

AC 1 = AB + BC + CC 1, DD 1 = AA 1. D 1 C 1 = 1 D 1 F = 1. AF = 1 a + b + ( ( (((

AC 1 = AB + BC + CC 1, DD 1 = AA 1. D 1 C 1 = 1 D 1 F = 1. AF = 1 a + b + ( ( ((( ? / / / o/ / / / o/ / / / 1 1 1., D 1 1 1 D 1, E F 1 D 1. = a, D = b, 1 = c. a, b, c : #$ #$ #$ 1) 1 ; : 1)!" ) D 1 ; ) F ; = D, )!" D 1 = D + DD 1, % ) F = D + DD 1 + D 1 F, % 4) EF. 1 = 1, 1 = a + b

Διαβάστε περισσότερα

ichip CO2128 with EBI Flash and Siemens MC39i GSM Modem

ichip CO2128 with EBI Flash and Siemens MC39i GSM Modem Reference Design 0 ichip CO with EBI Flash and Siemens MCi GSM Modem Revision History Version Date Description.0 May 00 Initial version.0 September 00 Changed from Mb Flash to Mb Flash Introduction This

Διαβάστε περισσότερα

Electrical Specifications at T AMB =25 C DC VOLTS (V) MAXIMUM POWER (dbm) DYNAMIC RANGE IP3 (dbm) (db) Output (1 db Comp.) at 2 f U. Typ.

Electrical Specifications at T AMB =25 C DC VOLTS (V) MAXIMUM POWER (dbm) DYNAMIC RANGE IP3 (dbm) (db) Output (1 db Comp.) at 2 f U. Typ. Surface Mount Monolithic Amplifiers High Directivity, 50Ω, 0.5 to 5.9 GHz Features 3V & 5V operation micro-miniature size.1"x.1" no external biasing circuit required internal DC blocking at RF input &

Διαβάστε περισσότερα

Electronic Analysis of CMOS Logic Gates

Electronic Analysis of CMOS Logic Gates Electronic Analysis of CMOS Logic Gates Dae Hyun Kim EECS Washington State University References John P. Uyemura, Introduction to VLSI Circuits and Systems, 2002. Chapter 7 Goal Understand how to perform

Διαβάστε περισσότερα

k k ΚΕΦΑΛΑΙΟ 1 G = (V, E) V E V V V G E G e = {v, u} E v u e v u G G V (G) E(G) n(g) = V (G) m(g) = E(G) G S V (G) S G N G (S) = {u V (G)\S v S : {v, u} E(G)} G v S v V (G) N G (v) = N G ({v}) x V (G)

Διαβάστε περισσότερα

Technical Specifications

Technical Specifications FLX-8X8A Chassis Technical Specifications Modular Input Cards... FLX-BI4, FLX-DI4, FLX-HI4, FLX-RI4 Analog Audio... Balanced or Unbalanced Stereo Audio (20 Hz to 20 khz) Supported Outputs Modular Output

Διαβάστε περισσότερα

Econ 2110: Fall 2008 Suggested Solutions to Problem Set 8 questions or comments to Dan Fetter 1

Econ 2110: Fall 2008 Suggested Solutions to Problem Set 8 questions or comments to Dan Fetter 1 Eon : Fall 8 Suggested Solutions to Problem Set 8 Email questions or omments to Dan Fetter Problem. Let X be a salar with density f(x, θ) (θx + θ) [ x ] with θ. (a) Find the most powerful level α test

Διαβάστε περισσότερα

(REV:01) RYOBI 48 Volt Lawn Mower Model No. RY14110 Replacement Parts List

(REV:01) RYOBI 48 Volt Lawn Mower Model No. RY14110 Replacement Parts List 9800-86 2-0-0 (REV:0) RYOBI 48 Volt Lawn Mower Model No. RY0 Replacement Parts List RYOBI RY0 48 volt lawn mower 3 38 39 44 39 36 34 36 42 38 39 3 4 37 34 3 43 2 32 0 8 9 2 4 33 8 7 6 3 6 7 22 8 20 3 30

Διαβάστε περισσότερα

SERVICE MANUAL RE-2 PROJECTION TV CHASSIS. KP-41S5K RM-862 OIRT SCC-N62D-A KP-41S5R RM-862 Russian SCC-N62C-A KP-41S5U RM-862 UK SCC-N61B-A

SERVICE MANUAL RE-2 PROJECTION TV CHASSIS. KP-41S5K RM-862 OIRT SCC-N62D-A KP-41S5R RM-862 Russian SCC-N62C-A KP-41S5U RM-862 UK SCC-N61B-A SV MNU - SSS M MMN ST. SSS N. M MMN ST. SSS N......................... P-S M- P S-N- P-S M- rench S-N- P-S M- reek S-N- P-S M- T S-N- P-S M- ussian S-N- P-SU M- U S-N- MM Please file according to model

Διαβάστε περισσότερα

SMD Transient Voltage Suppressors

SMD Transient Voltage Suppressors SMD Transient Suppressors Feature Full range from 0 to 22 series. form 4 to 60V RMS ; 5.5 to 85Vdc High surge current ability Bidirectional clamping, high energy Fast response time

Διαβάστε περισσότερα

LS01-15B09SS LS01-15B12SS LS01-15B15SS LS01-15B24SS LS03-15B03SR2S LS03-15B05SR2S LS03-15B09SR2S LS03-15B12SR2S LS03-15B15SR2S LS03-15B24SR2S

LS01-15B09SS LS01-15B12SS LS01-15B15SS LS01-15B24SS LS03-15B03SR2S LS03-15B05SR2S LS03-15B09SR2S LS03-15B12SR2S LS03-15B15SR2S LS03-15B24SR2S LS0 SS & LS0RS _ onverter. W SIP economic LS series.... W High performance & compact size series.... W ~0V wide input voltage LH series.... W 0 Low temperature & high reliability L0_LT series.... 00W LH

Διαβάστε περισσότερα

Mohon Peak BETA BRD B1. Intel Corporation. 001_Cover Page. Mohon Peak CRB Wednesday, August 28, 2013 ODM PROJECT CODE : S

Mohon Peak BETA BRD B1. Intel Corporation. 001_Cover Page. Mohon Peak CRB Wednesday, August 28, 2013 ODM PROJECT CODE : S Mohon Peak ET R OM PROJET OE : S0-0 Intel orporation 00_over Page 000 W HNLER LV HNLER, Z Size ocument Number Rev eta Mohon Peak R Wednesday, ugust, 0 ate: Sheet of Note:VN = voton and RGY = Rangeley PGE

Διαβάστε περισσότερα

Development and Verification of Multi-Level Sub- Meshing Techniques of PEEC to Model High- Speed Power and Ground Plane-Pairs of PFBS

Development and Verification of Multi-Level Sub- Meshing Techniques of PEEC to Model High- Speed Power and Ground Plane-Pairs of PFBS Rose-Hulman Institute of Technology Rose-Hulman Scholar Graduate Theses - Electrical and Computer Engineering Graduate Theses Spring 5-2015 Development and Verification of Multi-Level Sub- Meshing Techniques

Διαβάστε περισσότερα

!!! )!)(!,!! )!! )! (!!)!

!!! )!)(!,!! )!! )! (!!)! ! # %&!!!!! # %& (!!! # %&! ( ) # %&!! )! )!!!!! (! )! +!!! )!)(!,!! )!! )! (!!)!!!!,!!!!! + (!!)! ).!!!)( / ) 0!!!!!!! + (!!!,! + ( ( 5 % 6! & ) & 7 8!+ 9 ## 78 ## # #5! 7! /, #:6 ;! 7 )! & 9 ) 5< 7 )

Διαβάστε περισσότερα

M p f(p, q) = (p + q) O(1)

M p f(p, q) = (p + q) O(1) l k M = E, I S = {S,..., S t } E S i = p i {,..., t} S S q S Y E q X S X Y = X Y I X S X Y = X Y I S q S q q p+q p q S q p i O q S pq p i O S 2 p q q p+q p q p+q p fp, q AM S O fp, q p + q p p+q p AM

Διαβάστε περισσότερα

SPBW06 & DPBW06 series

SPBW06 & DPBW06 series /,, MODEL SELECTION TABLE INPUT ORDER NO. INPUT VOLTAGE (RANGE) NO LOAD INPUT CURRENT FULL LOAD VOLTAGE CURRENT EFFICIENCY (TYP.) CAPACITOR LOAD (MAX.) SPBW06F-03 310mA 3.3V 0 ~ 1500mA 81% 4700μF SPBW06F-05

Διαβάστε περισσότερα

Surface Mount Multilayer Chip Capacitors for Commodity Solutions

Surface Mount Multilayer Chip Capacitors for Commodity Solutions Surface Mount Multilayer Chip Capacitors for Commodity Solutions Below tables are test procedures and requirements unless specified in detail datasheet. 1) Visual and mechanical 2) Capacitance 3) Q/DF

Διαβάστε περισσότερα

MAX4147ESD PART 14 SO TOP VIEW. Maxim Integrated Products 1 MAX4147 EVALUATION KIT AVAILABLE ; Rev 1; 11/96 V CC V EE OUT+ IN+ R t SENSE IN-

MAX4147ESD PART 14 SO TOP VIEW. Maxim Integrated Products 1 MAX4147 EVALUATION KIT AVAILABLE ; Rev 1; 11/96 V CC V EE OUT+ IN+ R t SENSE IN- -; Rev ; / EVALUATION KIT AVAILABLE µ µ PART ESD TEMP. RANGE - C to +5 C PPACKAGE SO TOP VIEW V EE V CC SENSE+ SENSE- R t R t R t R t MAX SENSE OUT SENSE+ SENSE- N.C. SHDN N.C. 3 5 R f R G R f 3 VDSL TRANSFORMER

Διαβάστε περισσότερα

IGBT Modules. VCES Amps Digi-Key C2E1 E2 G1E1 E2G2. Powerex. Powerex. RoHS Compliant. Kits. Description. RoHS Compliant.

IGBT Modules. VCES Amps Digi-Key C2E1 E2 G1E1 E2G2. Powerex. Powerex. RoHS Compliant. Kits. Description. RoHS Compliant. 22 pioneer in high power semiconductor applications, POWRX offers a broad line of products, including IT, MOST Modules, Intelligent Power Modules (IPM), IP-IPM, Module ccessories (including gate drivers

Διαβάστε περισσότερα

jqa=mêççìåíë=^âíáéåöéëéääëåü~ñí= =p~~êäêωåâéå= =déêã~åó

jqa=mêççìåíë=^âíáéåöéëéääëåü~ñí= =p~~êäêωåâéå= =déêã~åó L09 cloj=klk=tsvjmosopa jqa=mêççìåíë=^âíáéåöéëéääëåü~ñí= =p~~êäêωåâéå= =déêã~åó 4 16 27 38 49 60 71 82 93 P Éå Ñê ÇÉ áí dbq=ql=hklt=vlro=^mmif^k`b mo pbkq^qflk=ab=slqob=^mm^obfi ibokbk=pfb=feo=dboûq=hbkkbk

Διαβάστε περισσότερα

CPU Merom 478 PIN (micro FC-PGA) P3,4. FSB 667 MHz(166X4) FSB 800MHz(200X4) UNBUFFERED DDRII SODIMM DDRII 533/667 UNBUFFERED DDRII SODIMM P11

CPU Merom 478 PIN (micro FC-PGA) P3,4. FSB 667 MHz(166X4) FSB 800MHz(200X4) UNBUFFERED DDRII SODIMM DDRII 533/667 UNBUFFERED DDRII SODIMM P11 WK lock iagram.mhz VRM GR P- Mx PS PU Merom PIN (micro F-PG) P, LOK GEN ISLPR P VI P FS MHz(X) FS MHz(X) TI M P- LVS R/G/ L P RT P PIE Lanes LVS R/G/ restline GM/PM PIN (micro FG) mm x mm P- RII / RII

Διαβάστε περισσότερα

ΑΝΑΛΥΤΙΚΟΣ ΤΙΜΟΚΑΤΑΛΟΓΟΣ BMW / MINI (Ισχύει από 15/01/2018) ΚΙΒΩΤΙΟ ΤΑΧΥΤΗΤΩΝ ΚΥΒΙΣΜΟΣ ΙΣΧΥΣ (HP)

ΑΝΑΛΥΤΙΚΟΣ ΤΙΜΟΚΑΤΑΛΟΓΟΣ BMW / MINI (Ισχύει από 15/01/2018) ΚΙΒΩΤΙΟ ΤΑΧΥΤΗΤΩΝ ΚΥΒΙΣΜΟΣ ΙΣΧΥΣ (HP) Υ F21 LCI - Σειρά 1 3θυρη 1W11 120i ΧΚ 1.998 184 131 21.941,48 33.000 1W31 125i ΑΚ 1.998 224 130 26.407,03 42.040 1W91 M140i ΧΚ 2.998 340 179 31.878,02 52.790 1P91 M140i xdrive ΑΚ 2.998 340 169 35.428,74

Διαβάστε περισσότερα

(REV:01) RYOBI 48 Volt Lawn Mower Model No. RY14110A Replacement Parts List

(REV:01) RYOBI 48 Volt Lawn Mower Model No. RY14110A Replacement Parts List 9000-7 9-- (REV:0) RYOBI 4 Volt Lawn Mower Model No. RY0A Replacement Parts List RYOBI RY0A 4 VOLT LAWN MOWER 3 3 39 44 39 3 34 3 42 3 39 3 4 37 34 3 43 2 0 37 2 33 32 3 9 7 22 30 4 7 3 20 9 3 2 2 27 2

Διαβάστε περισσότερα

PCB Footprint Library

PCB Footprint Library PCB Tantalum Capacitors EIA Standard Low Inductance MLCs Chip Film Capacitors SuperCaps Filters TVS Diodes Couplers Crossovers Inductors Timing Devices Resistive Products http://www.avx.com Tantalum Capacitors

Διαβάστε περισσότερα

Spare Parts. Cartridges. Chipbreakers Wrenches / Spanners Springs / Washers / Plugs / Nuts / Punches

Spare Parts. Cartridges. Chipbreakers Wrenches / Spanners Springs / Washers / Plugs / Nuts / Punches 1~20 Screws ins Shims artridges lamps lamp Sets hipbreakers Wrenches / Spanners Springs / Washers / lugs / Nuts / unches 2~6 7 8~11 12 13 14~15 16 17~18 19 1 Screws escription imension (mm) ngle ( ) H

Διαβάστε περισσότερα

ASL BS ,00 ASL BS ,00 ASL BS ,80 ASL BS ,60 ASL TP SET 1 817,20 ASL TP SET 2 997,20 ASL TP SET ,20

ASL BS ,00 ASL BS ,00 ASL BS ,80 ASL BS ,60 ASL TP SET 1 817,20 ASL TP SET 2 997,20 ASL TP SET ,20 www.asl-inter.com BASIC SERIES ASL BS 217 Κεντρική μονάδα intercom 2 καναλιών. Κάθε κανάλι διαθέτει φωτιζόμενο κουμπί Talk και Call και volume για τον έλεγχο της έντασης. Στην πίσω πλευρά διαθέτει μια

Διαβάστε περισσότερα

Το άτομο του Υδρογόνου

Το άτομο του Υδρογόνου Το άτομο του Υδρογόνου Δυναμικό Coulomb Εξίσωση Schrödinger h e (, r, ) (, r, ) E (, r, ) m ψ θφ r ψ θφ = ψ θφ Συνθήκες ψ(, r θφ, ) = πεπερασμένη ψ( r ) = 0 ψ(, r θφ, ) =ψ(, r θφ+, ) π Επιτρεπτές ενέργειες

Διαβάστε περισσότερα

Project: 296 File: Title: CMC-E-600 ICD Doc No: Rev 2. Revision Date: 15 September 2010

Project: 296 File: Title: CMC-E-600 ICD Doc No: Rev 2. Revision Date: 15 September 2010 Project: 296 File: Title: CMC-E-600 ICD Doc No: 21029100-406 Rev 2. Revision Date: 15 September 2010 Contract No.: Revisions Table ECR/ECN LTR Description Date 0 Pre Contract draft 29 July 2010 1 Replace

Διαβάστε περισσότερα

Siemens AG Rated current 1FK7 Compact synchronous motor Natural cooling. I rated 7.0 (15.4) 11.5 (25.4) (2.9) 3.3 (4.4)

Siemens AG Rated current 1FK7 Compact synchronous motor Natural cooling. I rated 7.0 (15.4) 11.5 (25.4) (2.9) 3.3 (4.4) Synchronous motors Siemens 2009 FK7 Compact motors Nural cooling Selection and ordering da Red speed Shaft height n red S P red ΔT=00 K rpm kw (P) Red power Stic torque M 0 ΔT=00 K Red torque ) M red ΔT=00

Διαβάστε περισσότερα

Quick Installation Guide

Quick Installation Guide A Installation 1 F H B E C D G 2 www.trust.com/17528/faq Quick Installation Guide C C D Freewave Wireless Audio Set 17528/ 17529 D Installation Configuration Windows XP 4 5 8 Windows 7/ Vista 6 7 9 10

Διαβάστε περισσότερα

M3 System Block Diagram

M3 System Block Diagram M System lock iagram M/ M socket LE Panel L Panel (LVS) R-SOMM & R-SOMM & LOK GEN SLGSP.MHz R 0/ MT/s R 0/ MT/s PU M thlon HT-Link N M RS0M PE.0 X 0~ ~ MXM.0 Type MUX PPE - MUX PPE - UM_P UM_P UM_LVS MXM_LVS

Διαβάστε περισσότερα

Capacitors - Capacitance, Charge and Potential Difference

Capacitors - Capacitance, Charge and Potential Difference Capacitors - Capacitance, Charge and Potential Difference Capacitors store electric charge. This ability to store electric charge is known as capacitance. A simple capacitor consists of 2 parallel metal

Διαβάστε περισσότερα

[1] P Q. Fig. 3.1

[1] P Q. Fig. 3.1 1 (a) Define resistance....... [1] (b) The smallest conductor within a computer processing chip can be represented as a rectangular block that is one atom high, four atoms wide and twenty atoms long. One

Διαβάστε περισσότερα

MIL-DTL Micro-D Connector R04J Series Straight to PCB Type

MIL-DTL Micro-D Connector R04J Series Straight to PCB Type MIL-TL-353 Micro- onnector R4J Series Straight to P Type Specication MIL-TL-353 Micro- onnector nvironment temperature: ~ Vibration: Hz~Hz, 6m/s Random vibration: Power spectrum density.4g Hz root mean

Διαβάστε περισσότερα

k k ΚΕΦΑΛΑΙΟ 1 G = (V, E) V E V V V G E G e = {v, u} E v u e v u G G V (G) E(G) n(g) = V (G) m(g) = E(G) G S V (G) S G N G (S) = {u V (G)\S v S : {v, u} E(G)} G v S v V (G) N G (v) = N G ({v}) x V (G)

Διαβάστε περισσότερα

LAr ROD boards. TM - TBM - CarteP3. Pierre Matricon LAL - Orsay

LAr ROD boards. TM - TBM - CarteP3. Pierre Matricon LAL - Orsay LAr ROD boards TM - TBM - CarteP3 Pierre Matricon LAL - Orsay October 2002 matricon@in2p3.fr Connections between the ROD boards TBM Crate Busy Trigger Timing Control CarteP3 Configuration TM to ROS 8 FEBs

Διαβάστε περισσότερα

Instruction Execution Times

Instruction Execution Times 1 C Execution Times InThisAppendix... Introduction DL330 Execution Times DL330P Execution Times DL340 Execution Times C-2 Execution Times Introduction Data Registers This appendix contains several tables

Διαβάστε περισσότερα

Buck Solution_20W LED Driver for T8 LD7835_T8_20W_R00_TEST. Key Features

Buck Solution_20W LED Driver for T8 LD7835_T8_20W_R00_TEST. Key Features Subject LD7835 T8 Demo Board Manual Model Name LD7835_20W_R00_TEST (60V/300mA) Key Features Buck Topology Current Ripple Reduction (CRR) Current Accuracy < 5% Single Stage PFC > 0.9 @ Normal Line Efficiency

Διαβάστε περισσότερα

Buck Solution_9W LED Driver for Bulb LD9852_9W_R00_TEST. Size 34.2mm(L)ⅹ26mm(W)ⅹ18mm(H) Key Features

Buck Solution_9W LED Driver for Bulb LD9852_9W_R00_TEST. Size 34.2mm(L)ⅹ26mm(W)ⅹ18mm(H) Key Features Subject LD9852 Demo Board Manual Model Name (45V/200mA) TOP VIEW BOTTOM VIEW Size 34.2mm(L)ⅹ26mm(W)ⅹ18mm(H) Key Features Buck Topology Current Accuracy < 5% Single Stage PFC > 0.9 @ Normal Line Efficiency

Διαβάστε περισσότερα

LTC RO R 2 RE 3 DE 1 RO 2 3 DE 4 DI 2000 FEET OF TWISTED-PAIR WIRE 7 RECEIVER INPUT DI. 4.7nF RO

LTC RO R 2 RE 3 DE 1 RO 2 3 DE 4 DI 2000 FEET OF TWISTED-PAIR WIRE 7 RECEIVER INPUT DI. 4.7nF RO µ µ µ LTC1487 µ µ TYPICL PPLICTI UO LTC1487 LTC1487 1 2 E 3 7 4 D 6 12Ω 2 FEET OF TWISTED-PI WIE 33Ω 7 12Ω 6 D 1 2 E 3 4 ECEIVE INPUT 4.7nF EQUIVLENT LOD OF 256 LTC1487 TNSCEIVES LTC1487 T1 LTC1487 T2

Διαβάστε περισσότερα

The Simply Typed Lambda Calculus

The Simply Typed Lambda Calculus Type Inference Instead of writing type annotations, can we use an algorithm to infer what the type annotations should be? That depends on the type system. For simple type systems the answer is yes, and

Διαβάστε περισσότερα

BENQ(EL3) LCDPC Block Diagram

BENQ(EL3) LCDPC Block Diagram P STK UP ENQ(EL) LP lock iagram LYER : TOP LYER : GN LYER : IN LYER : IN LYER : V LYER : OT RJ-." panel UO/MO RII M//G/G/G 0/00 Ethernet RTL0EL H LVS PI-E PI-E M VORE:+0.V ~ +.V 0 VLT:+.V V:+.V 0. -PIN

Διαβάστε περισσότερα

Phys460.nb Solution for the t-dependent Schrodinger s equation How did we find the solution? (not required)

Phys460.nb Solution for the t-dependent Schrodinger s equation How did we find the solution? (not required) Phys460.nb 81 ψ n (t) is still the (same) eigenstate of H But for tdependent H. The answer is NO. 5.5.5. Solution for the tdependent Schrodinger s equation If we assume that at time t 0, the electron starts

Διαβάστε περισσότερα

HΛΕΚΤΡΙΚΟΣ ΙΑ ΡΟΜΟΣ UPOWER 202

HΛΕΚΤΡΙΚΟΣ ΙΑ ΡΟΜΟΣ UPOWER 202 HΛΕΚΤΡΙΚΟΣ ΙΑ ΡΟΜΟΣ UPOWER 202 Ευχαριστούµε που διαλέξατε τα όργανα γυµναστικής µας. Για καλύτερα αποτελέσµατα και για αποφυγή τραυµατισµών, πάντα να κάνετε ασκήσεις προθέρµανσης πριν χρησιµοποιήσετε τον

Διαβάστε περισσότερα

5V/9V/12V Output QC2.0+USB Auto Detect+USB-PD Type-C Application Report ACT4529

5V/9V/12V Output QC2.0+USB Auto Detect+USB-PD Type-C Application Report ACT4529 FEATURES 5V/9V/12V Output QC2.0+USB Auto Detect+USB-PD Type-C Application Report ACT4529 Wide input voltage range from 6V to 32V Transparent input voltage surge up to 40V QC2.0 decoding, 5V/9V/12V output

Διαβάστε περισσότερα

Long 3000 hour life at 105 C with high ripple current capability 2 and 3 pin versions available Can vent construction

Long 3000 hour life at 105 C with high ripple current capability 2 and 3 pin versions available Can vent construction TS-HA/HB Series 105 C, 3000 hours Long 3000 hour life at 105 C with high ripple current capability 2 and 3 pin versions available Can vent construction RoHS Compliant Rated Working Voltage: Operating Temperature:

Διαβάστε περισσότερα

NEC Silicon RFIC Amplifiers Low Power, Wideband & SiGe/SiGeC

NEC Silicon RFIC Amplifiers Low Power, Wideband & SiGe/SiGeC NEC Silicon RFIC Amplifiers Low Power, Wideband & SiGe/SiGeC Low Power Amplifiers ELECTRICAL CHARACTERISTICS (TA = 25 C) Range VCC ICC NF Gain RLIN RLOUT PdB ISOL @ 3dB (V) (ma) (dbm) Part down Package

Διαβάστε περισσότερα

ITU-R P (2012/02) &' (

ITU-R P (2012/02) &' ( ITU-R P.530-4 (0/0) $ % " "#! &' ( P ITU-R P. 530-4 ii.. (IPR) (ITU-T/ITU-R/ISO/IEC).ITU-R http://www.itu.int/itu-r/go/patents/en. ITU-T/ITU-R/ISO/IEC (http://www.itu.int/publ/r-rec/en ) () ( ) BO BR BS

Διαβάστε περισσότερα

Photomultiplier Tube Assemblies

Photomultiplier Tube Assemblies hotomultiplier Tube Assemblies hotomultiplier Tube Assemblies hotomultiplier tube assemblies are made up of a photomultiplier tube, a voltagedivider circuit and other components, all integrated into a

Διαβάστε περισσότερα

Operating Instructions and Parts Manual Drum Sander Model PM2244

Operating Instructions and Parts Manual Drum Sander Model PM2244 Operating Instructions and Parts Manual Drum Sander Model PM2244 Powermatic 427 New Sanford Road LaVergne, Tennessee 37086 Part No. M-1792244 Ph.: 800-274-6848 Edition 1 08/2015 www.powermatic.com Copyright

Διαβάστε περισσότερα

Molekulare Ebene (biochemische Messungen) Zelluläre Ebene (Elektrophysiologie, Imaging-Verfahren) Netzwerk Ebene (Multielektrodensysteme) Areale (MRT, EEG...) Gene Neuronen Synaptische Kopplung kleine

Διαβάστε περισσότερα

Homework 8 Model Solution Section

Homework 8 Model Solution Section MATH 004 Homework Solution Homework 8 Model Solution Section 14.5 14.6. 14.5. Use the Chain Rule to find dz where z cosx + 4y), x 5t 4, y 1 t. dz dx + dy y sinx + 4y)0t + 4) sinx + 4y) 1t ) 0t + 4t ) sinx

Διαβάστε περισσότερα

AT Surface Mount Package SOT-363 (SC-70) I I Y. Pin Connections B 1 C 1 E 1 E 2 C 2 B , 7:56 PM

AT Surface Mount Package SOT-363 (SC-70) I I Y. Pin Connections B 1 C 1 E 1 E 2 C 2 B , 7:56 PM AT-3263 Surface Mount Package SOT-363 (SC-7) I I Y Pin Connections B 1 C 1 E 1 E 2 C 2 B 2 Page 1 21.4., 7:6 PM Absolute Maximum Ratings [1] Absolute Thermal Resistance [2] : Symbol Parameter Units Maximum

Διαβάστε περισσότερα

ο ο 3 α. 3"* > ω > d καΐ 'Ενορία όλις ή Χώρί ^ 3 < KN < ^ < 13 > ο_ Μ ^~~ > > > > > Ο to X Η > ο_ ο Ο,2 Σχέδι Γλεγμα Ο Σ Ο Ζ < o w *< Χ χ Χ Χ < < < Ο

ο ο 3 α. 3* > ω > d καΐ 'Ενορία όλις ή Χώρί ^ 3 < KN < ^ < 13 > ο_ Μ ^~~ > > > > > Ο to X Η > ο_ ο Ο,2 Σχέδι Γλεγμα Ο Σ Ο Ζ < o w *< Χ χ Χ Χ < < < Ο 18 ρ * -sf. NO 1 D... 1: - ( ΰ ΐ - ι- *- 2 - UN _ ί=. r t ' \0 y «. _,2. "* co Ι». =; F S " 5 D 0 g H ', ( co* 5. «ΰ ' δ". o θ * * "ΰ 2 Ι o * "- 1 W co o -o1= to»g ι. *ΰ * Ε fc ΰ Ι.. L j to. Ι Q_ " 'T

Διαβάστε περισσότερα

First Sensor Quad APD Data Sheet Part Description QA TO Order #

First Sensor Quad APD Data Sheet Part Description QA TO Order # Responsivity (/W) First Sensor Quad PD Data Sheet Features Description pplication Pulsed 16 nm laser detection RoHS 211/65/EU Light source positioning Laser alignment ø mm total active area Segmented in

Διαβάστε περισσότερα

Advanced Subsidiary Unit 1: Understanding and Written Response

Advanced Subsidiary Unit 1: Understanding and Written Response Write your name here Surname Other names Edexcel GE entre Number andidate Number Greek dvanced Subsidiary Unit 1: Understanding and Written Response Thursday 16 May 2013 Morning Time: 2 hours 45 minutes

Διαβάστε περισσότερα

EE101: Resonance in RLC circuits

EE101: Resonance in RLC circuits EE11: Resonance in RLC circuits M. B. Patil mbatil@ee.iitb.ac.in www.ee.iitb.ac.in/~sequel Deartment of Electrical Engineering Indian Institute of Technology Bombay I V R V L V C I = I m = R + jωl + 1/jωC

Διαβάστε περισσότερα

DC-DC Constant Current Step-Down LED driver LDD-300L LDD-350L LDD-500L LDD-600L LDD-700L CURRENT RANGE

DC-DC Constant Current Step-Down LED driver LDD-300L LDD-350L LDD-500L LDD-600L LDD-700L CURRENT RANGE SPECIFICATION ORDER NO. LDD-00L LDD-0L LDD-00L LDD-00L LDD-700L CURRENT RANGE 00mA 0mA 00mA VOLTAGE RANGE Note. ~ VDC for LDD-00~700L/LW ; ~ 8VDC for LDD-00~700LS CURRENT ACCURACY (Typ.) ±% at VDC input

Διαβάστε περισσότερα

H-2079 POLY STRAPPING MACHINE

H-2079 POLY STRAPPING MACHINE ON OFF 2 0 3 M 4 MAX 5 π POWER LENGTH RESET FEED CONTROL PANEL DIAGRAM AND PC BOARD HOUSING 51 51 34 21 22 51 19 2 4 7 53 8 1 3 20 6 52 62 51 5 12 14 2 30 16 9 64 15 PAGE 1 OF 17 1214 P CONTROL PANEL PARTS

Διαβάστε περισσότερα

P P Ó P. r r t r r r s 1. r r ó t t ó rr r rr r rí st s t s. Pr s t P r s rr. r t r s s s é 3 ñ

P P Ó P. r r t r r r s 1. r r ó t t ó rr r rr r rí st s t s. Pr s t P r s rr. r t r s s s é 3 ñ P P Ó P r r t r r r s 1 r r ó t t ó rr r rr r rí st s t s Pr s t P r s rr r t r s s s é 3 ñ í sé 3 ñ 3 é1 r P P Ó P str r r r t é t r r r s 1 t r P r s rr 1 1 s t r r ó s r s st rr t s r t s rr s r q s

Διαβάστε περισσότερα

Current Sense Metal Strip Resistors (CSMS Series)

Current Sense Metal Strip Resistors (CSMS Series) Features: Range: 1mΩ to 100mΩ Low TCR as low as 75PPM High power rating Custom Values available RoHS Compliant and Halogen Free Operating Temperature: -55 C to +170 C Part Number Structure CSMS 0805 -

Διαβάστε περισσότερα

ZR6 SYSTEM BLOCK DIAGRAM

ZR6 SYSTEM BLOCK DIAGRAM OM MRK IV@: INT VG EV@: STUFF FOR EXT VG SP@: STUFF FOR UM or VG REV: X'TL.MHz LOK GENERTOR IS: SELGO: SLGSPTTR RIII SO-IMM 0 SO-IMM P ZR SYSTEM LOK IGRM P ual hannel R /00 MHz Penryn ufpg N antiga P,

Διαβάστε περισσότερα

MOSFETs. MOSFETs. High Voltage MOSFET (THD Type) Max. Ratings R DS(ON) ( ) Q g (nc) Outline (Unit: mm) Type No.

MOSFETs. MOSFETs. High Voltage MOSFET (THD Type) Max. Ratings R DS(ON) ( ) Q g (nc) Outline (Unit: mm) Type No. MOFETs High age MOFET (TH Type) Ratings R (ON) ( ) Q g (nc) BV I P (W) V I V KMB050N60P 60 50 1 0.018 0.022 10 25 32 10 KMB075N75P 75 75 190 0.013 0.017 10 37.5 85 10 KHB95NP 0 9.5 72 0.29 0.36 10 4.75

Διαβάστε περισσότερα

± 20% (rated cap. [µf] ) 1000 Leakage Current: For capacitance values > 33000µF, add the value of:

± 20% (rated cap. [µf] ) 1000 Leakage Current: For capacitance values > 33000µF, add the value of: TS-UP Series 85 C, 3000 hours Compact size for general purpose and industrial applications 2 and 3 pin versions available 20mm lengths for low profile applications RoHS Compliant Rated Working Voltage:

Διαβάστε περισσότερα

RECIPROCATING COMPRESSOR CALCULATION SHEET ISOTHERMAL COMPRESSION Gas properties, flowrate and conditions. Compressor Calculation Sheet

RECIPROCATING COMPRESSOR CALCULATION SHEET ISOTHERMAL COMPRESSION Gas properties, flowrate and conditions. Compressor Calculation Sheet RECIPRCATING CMPRESSR CALCULATIN SHEET ISTHERMAL CMPRESSIN Gas properties, flowrate and conditions 1 Gas name Air Item or symbol Quantity Unit Item or symbol Quantity Unit Formula 2 Suction pressure, ps

Διαβάστε περισσότερα

w o = R 1 p. (1) R = p =. = 1

w o = R 1 p. (1) R = p =. = 1 Πανεπιστήµιο Κρήτης - Τµήµα Επιστήµης Υπολογιστών ΗΥ-570: Στατιστική Επεξεργασία Σήµατος 205 ιδάσκων : Α. Μουχτάρης Τριτη Σειρά Ασκήσεων Λύσεις Ασκηση 3. 5.2 (a) From the Wiener-Hopf equation we have:

Διαβάστε περισσότερα

ΠΑΡΑΡΤΗΜΑ ΠΡΩΤΟΝ ΝΟΜΟΘΕΣΙΑ

ΠΑΡΑΡΤΗΜΑ ΠΡΩΤΟΝ ΝΟΜΟΘΕΣΙΑ ΠΑΡΑΡΤΗΜΑ ΠΡΩΤΝ ΤΗΣ ΕΠΙΣΗΜΥ ΕΦΗΜΕΡΙΔΣ ΤΗΣ ΔΗΜΚΡΑΤΙΑΣ υπ Άρ. 62 τής 19ης ΜΑΙΥ 1961 ΝΜΘΕΣΙΑ ΜΕΡΣ III ΚΙΝΤΙΚΙ ΝΜΙ ΤΥΡΚΙΚΗΣ ΚΙΝΤΙΚΗΣ ΣΥΝΕΛΕΎΣΕΩς Ό κττέρ νόμς της Τυρκικής Κιντικής Συνελεύσεις όστις υπεγράφη

Διαβάστε περισσότερα

Multi-GPU numerical simulation of electromagnetic waves

Multi-GPU numerical simulation of electromagnetic waves Multi-GPU numerical simulation of electromagnetic waves Philippe Helluy, Thomas Strub To cite this version: Philippe Helluy, Thomas Strub. Multi-GPU numerical simulation of electromagnetic waves. ESAIM:

Διαβάστε περισσότερα

5 Ι ^ο 3 X X X. go > 'α. ο. o f Ο > = S 3. > 3 w»a. *= < ^> ^ o,2 l g f ^ 2-3 ο. χ χ. > ω. m > ο ο ο - * * ^r 2 =>^ 3^ =5 b Ο? UJ. > ο ο.

5 Ι ^ο 3 X X X. go > 'α. ο. o f Ο > = S 3. > 3 w»a. *= < ^> ^ o,2 l g f ^ 2-3 ο. χ χ. > ω. m > ο ο ο - * * ^r 2 =>^ 3^ =5 b Ο? UJ. > ο ο. 728!. -θ-cr " -;. '. UW -,2 =*- Os Os rsi Tf co co Os r4 Ι. C Ι m. Ι? U Ι. Ι os ν ) ϋ. Q- o,2 l g f 2-2 CT= ν**? 1? «δ - * * 5 Ι -ΐ j s a* " 'g cn" w *" " 1 cog 'S=o " 1= 2 5 ν s/ O / 0Q Ε!θ Ρ h o."o.

Διαβάστε περισσότερα

NMBTC.COM /

NMBTC.COM / Common Common Vibration Test:... Conforms to JIS C 60068-2-6, Amplitude: 1.5mm, Frequency 10 to 55 Hz, 1 hour in each of the X, Y and Z directions. Shock Test:...Conforms to JIS C 60068-2-27, Acceleration

Διαβάστε περισσότερα

Operating Instructions and Parts Manual 14-inch Woodworking Band Saw Models JWBS-14SF and JWBS-14SF-3

Operating Instructions and Parts Manual 14-inch Woodworking Band Saw Models JWBS-14SF and JWBS-14SF-3 Operating Instructions and Parts Manual 14-inch Woodworking Band Saw Models JWBS-14SF and JWBS-14SF-3 Model #714500 shown JET 427 New Sanford Road LaVergne, Tennessee 37086 Part No. M-714500 Ph.: 800-274-6848

Διαβάστε περισσότερα

r r t r r t t r t P s r t r P s r s r r rs tr t r r t s ss r P s s t r t t tr r r t t r t r r t t s r t rr t Ü rs t 3 r r r 3 rträ 3 röÿ r t

r r t r r t t r t P s r t r P s r s r r rs tr t r r t s ss r P s s t r t t tr r r t t r t r r t t s r t rr t Ü rs t 3 r r r 3 rträ 3 röÿ r t r t t r t ts r3 s r r t r r t t r t P s r t r P s r s r P s r 1 s r rs tr t r r t s ss r P s s t r t t tr r 2s s r t t r t r r t t s r t rr t Ü rs t 3 r t r 3 s3 Ü rs t 3 r r r 3 rträ 3 röÿ r t r r r rs

Διαβάστε περισσότερα

Summary of Specifications

Summary of Specifications Snap Mount Large High CV High Ripple 85 C Temperature The series capacitors are the standard 85 C, large capacitance, snap-in capacitors from United Chemi-Con. The load life for the series is 2,000 hours

Διαβάστε περισσότερα

Output Power: W. Exclusively distributed by Powerstax

Output Power: W. Exclusively distributed by Powerstax R Series, 50-150W Input Ranges : 9-75 VDC : Single - Dual /, / /, / Triple / ±, /, / ±0, Quad ± / ±, ± / : 50-150 W FEATURES General: to 100 Watts Wide Input Range : 10-7dc 2:1 & 3:1 Input Range High Conversion

Διαβάστε περισσότερα

ΤΕΧΝΙΚΕΣ ΠΡΟ ΙΑΓΡΑΦΕΣ ΕΞΟΠΛΙΣΜΟΥ

ΤΕΧΝΙΚΕΣ ΠΡΟ ΙΑΓΡΑΦΕΣ ΕΞΟΠΛΙΣΜΟΥ ΤΕΧΝΙΚΕΣ ΠΡΟ ΙΑΓΡΑΦΕΣ ΕΞΟΠΛΙΣΜΟΥ Α. κεντρικός εξυπηρετητής τεµάχια : 5 (πέντε) Ολα τα µέρη του προσφερόµενου εξοπλισµού να είναι του ιδίου κατασκευαστή. Αριθµός µονάδων. 5 Τα τµήµατα που συνθέτουν το σύστηµα

Διαβάστε περισσότερα

Numerical Analysis FMN011

Numerical Analysis FMN011 Numerical Analysis FMN011 Carmen Arévalo Lund University carmen@maths.lth.se Lecture 12 Periodic data A function g has period P if g(x + P ) = g(x) Model: Trigonometric polynomial of order M T M (x) =

Διαβάστε περισσότερα

0.635mm Pitch Board to Board Docking Connector. Lead-Free Compliance

0.635mm Pitch Board to Board Docking Connector. Lead-Free Compliance .635mm Pitch Board to Board Docking Connector Lead-Free Compliance MINIDOCK SERIES MINIDOCK SERIES Features Specifications Application.635mm Pitch Connector protected by Diecasted Zinc Alloy Metal Shell

Διαβάστε περισσότερα

SPEEDO AQUABEAT. Specially Designed for Aquatic Athletes and Active People

SPEEDO AQUABEAT. Specially Designed for Aquatic Athletes and Active People SPEEDO AQUABEAT TM Specially Designed for Aquatic Athletes and Active People 1 2 Decrease Volume Increase Volume Reset EarphonesUSBJack Power Off / Rewind Power On / Fast Forward Goggle clip LED Status

Διαβάστε περισσότερα
2024 © DocPlayer.gr Πολιτική Απορρήτου | Όροι Χρήσης | Σχόλια