TPS59611EVM-622

User's Guide SLUU465 – November 2010 An 8-V to 14-V Vin 2010 Atom™ E6xx Tunnel Creek Power System The TPS59610EVM-634 evaluation module (EVM) is a complete solution for the 2010 Atom™ E6xx Tunnel Creek Power System from a 12-V input bus. The EVM uses the TPS59610 for Atom CPU and GPU core, TPS51120 for 5-V and 3.3-V systems, TPS54326 for Topcliff IOH, TPS59124 for DDRII 1.8 V and CPU VTT 1.05 V, TPS51100 for 0.9 V VTT, TPS74801 for CPU 1.5-V PLL, and CPU C6 RAM 1.05 V. TPS59610EVM-634 also uses the 3-mm x 3-mm Texas Instruments (TI) power block MOSFET (CSD86330Q3D) for high-power density and superior thermal performance. 1 2 3 4 5 6 7 8 9 10 Contents Description ................................................................................................................... 4 1.1 Typical Applications ................................................................................................ 4 1.2 Features ............................................................................................................. 4 Atom Tunnel Creek Power System Block Diagram .................................................................... 4 Electrical Performance Specifications .................................................................................... 5 Schematics ................................................................................................................... 7 Test Setup .................................................................................................................. 12 5.1 Test Equipment ................................................................................................... 12 5.2 Recommended Test Setup ...................................................................................... 12 Configuration ............................................................................................................... 13 6.1 CPU and GPU Configuration ................................................................................... 13 6.2 5-V/3.3-V System Configuration ................................................................................ 15 6.3 DDR 1.8-V/1.05-V CPU VTT Configuration ................................................................... 15 6.4 0.9-V VTT and 0.9-V VTTREF Configuration ................................................................. 16 6.5 1.5-V CPU PLL Configuration ................................................................................... 16 6.6 1.05-V CPU C6 RAM Configuration ............................................................................ 16 6.7 1.2-V IOH Configuration ......................................................................................... 17 Test Procedure ............................................................................................................ 17 7.1 Line/Load Regulation and Efficiency Measurement Procedure ............................................ 17 7.2 Onboard Transient Response Measurement ................................................................. 17 7.3 Loop Gain/Phase Measurement ................................................................................ 18 7.4 Equipment Shutdown ............................................................................................ 18 Performance Data and Typical Characteristic Curves ................................................................ 19 8.1 CPU ................................................................................................................ 19 8.2 GPU ................................................................................................................ 23 8.3 5-V/3.3-V System ................................................................................................. 26 8.4 1.8-V DDR/1.05-V CPU VTT .................................................................................... 30 8.5 1.2-V IOH .......................................................................................................... 33 EVM Assembly Drawings and PCB Layout ............................................................................ 35 Bill of Materials ............................................................................................................. 37 List of Figures 1 2 3 .......................................... TPS59610EVM-634 Schematic, Sheet 1 of 5 ........................................................................... TPS59610EVM-634 Schematic, Sheet 2 of 5 ........................................................................... 8-V to 14-V Vin 2010 Atom Tunnel Creek Power System Block Diagram 4 7 8 OSR is a trademark of Texas Instruments. Atom is a trademark of Intel Corporation. SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 1 www.ti.com 4 TPS59610EVM-634 Schematic, Sheet 3 of 5 ........................................................................... 9 5 TPS59610EVM-634 Schematic, Sheet 4 of 5 ......................................................................... 10 6 TPS59610EVM-634 Schematic, Sheet 5 of 5 ......................................................................... 11 7 TPS59610EVM-634 Recommended Test Setup ...................................................................... 12 8 CPU Efficiency 9 CPU Load Regulation ..................................................................................................... 19 10 CPU Enable Turnon 11 Enable Turnoff ............................................................................................................. 19 12 CPU Switching Node 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 2 ............................................................................................................ ...................................................................................................... ..................................................................................................... CPU Vcore Ripple ......................................................................................................... CPU Output Load Release Without Overshoot Reduction .......................................................... CPU Output Load Release With Maximum Overshoot Reduction .................................................. CPU Transient From DCM to CCM .................................................................................... CPU Transient From CCM to DCM ..................................................................................... CPU Bode Plot 12 Vin, 1 V/5 A .......................................................................................... CPU Top Board ........................................................................................................... CPU Bottom Board ........................................................................................................ CPU Efficiency ............................................................................................................. GPU Load Regulation ..................................................................................................... GPU Enable Turnon....................................................................................................... GPU Enable Turnoff....................................................................................................... GPU Switching Node ..................................................................................................... GPU Vcore Ripple ......................................................................................................... GPU Output Load ReleaseWithout Overshoot Reduction ........................................................... GPU Output Load ReleaseWith Maximum Overshoot Reduction................................................... GPU Transient From DCM to CCM ..................................................................................... GPU Transient From CCM to DCM ..................................................................................... GPU Bode Plot 12 Vin, 1 V/5 A ......................................................................................... CPU Top Board ........................................................................................................... CPU Bottom Board ........................................................................................................ 5-V Efficiency .............................................................................................................. 5-V Load Regulation ...................................................................................................... 5-V Enable Turnon ........................................................................................................ 5-V Enable Turnoff ........................................................................................................ 5-V Switching Node ....................................................................................................... 5-V Vo Ripple .............................................................................................................. 3.3-V Efficiency ............................................................................................................ 3.3-V Load Regulation .................................................................................................... 3.3-V Enable Turnon ...................................................................................................... 3.3-V Enable Turnoff ...................................................................................................... 3.3-V Switching Node ..................................................................................................... 3.3-V Vo Ripple ............................................................................................................ 5-V/3.3-V TOP Board ..................................................................................................... 5-V/3.3-V Bottom Board .................................................................................................. 1.8-V Efficiency ............................................................................................................ 1.8-V Load Regulation .................................................................................................... 1.8-V Enable Turnon ...................................................................................................... 1.8-V Enable Turnoff ...................................................................................................... An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 19 19 20 20 20 20 21 21 21 22 22 23 23 23 23 24 24 24 24 25 25 25 26 26 26 26 27 27 27 27 28 28 28 28 29 29 29 29 30 30 30 30 SLUU465 – November 2010 Submit Documentation Feedback www.ti.com 52 1.8-V Switching Node ..................................................................................................... 31 53 1.8-V Vo Ripple ............................................................................................................ 31 54 1.05-V Efficiency ........................................................................................................... 31 55 1.05-V Load Regulation 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 .................................................................................................. 1.05-V Enable Turnon .................................................................................................... 1.05-V Enable Turnoff .................................................................................................... 1.05-V Switching Node ................................................................................................... 1.05-V Vo Ripple .......................................................................................................... 1.8-V/1.05-V Top Board .................................................................................................. 1.8-V/1.05-V Bottom Board .............................................................................................. 1.2-V Efficiency ............................................................................................................ 1.2-V Load Regulation .................................................................................................... 1.2-V Enable Turnon ...................................................................................................... 1.2-V Enable Turnoff ...................................................................................................... 1.2-V Switching Node ..................................................................................................... 1.2-V Vo Ripple ............................................................................................................ 1.2-V Top BoardTest Condition: 12 Vin, 1.2 V/3 A, No Airflow ...................................................... TPS59610EVM-634 Top Layer Assembly Drawing, Top View ...................................................... TPS59610EVM-634 Bottom Assembly Drawing, Bottom View ...................................................... TPS59610EVM-634 Top Copper, Top View .......................................................................... TPS59610EVM-634 Internal Layer 2, Top View ...................................................................... TPS59610EVM-634 Internal Layer 3, Top View ...................................................................... TPS59610EVM-634 Bottom Layer, Bottom View ..................................................................... 31 32 32 32 32 33 33 33 33 34 34 34 34 34 35 35 35 36 36 36 List of Tables 1 TPS59610EVM-634 Electrical Performance Specifications ........................................................... 5 2 Current-Limit Trip Selection .............................................................................................. 13 3 Frequency Selection ...................................................................................................... 13 4 Overshoot Reduction Selection .......................................................................................... 13 5 CPU VID Bits Selection ................................................................................................... 14 6 GPU VID Bits Selection 7 C4 Exit Rate Selection .................................................................................................... 14 8 Overvoltage Protection selection 9 10 11 12 13 14 15 16 17 .................................................................................................. ....................................................................................... Onboard Dynamic Load Selection ...................................................................................... Enable Selection ........................................................................................................... 5-V/3.3-V Enable Selection .............................................................................................. 1.8-V/1.05-V Enable Selection .......................................................................................... SW400(S5), SW401(S3) Enable Selection ............................................................................ 1.5-V Enable Selection ................................................................................................... 1.05-V CPU C6 RAM Enable Selection ................................................................................ 1.2-V Enable selection ................................................................................................... Bill of Materials............................................................................................................. SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 14 15 15 15 15 16 16 16 16 17 37 3 Description 1 www.ti.com Description The TPS59610EVM-634 is designed to use a regulated 12-V (8-V to 14-V) bus to produce 10 regulated outputs for an Atom™ E6xx Tunnel Creek Power System. The TPS59610EVM-634 is specially designed to demonstrate the TPS59610 Atom E6xx CPU and GPU Vcore regulators while providing a number of test points to evaluate their static and dynamic performance. 1.1 Typical Applications • 1.2 8-V to 14-V Vin Atom E6xx Tunnel Creek Power System for embedded computing platforms Features The TPS59610EVM-634 features: • Complete solution for 8-V to 14-V Vin Atom Tunnel Creek Power System • Selectable 200/300/400/500-kHz switching frequency for CPU and GPU power • Selectable current limit for CPU and GPU power • Selectable output overshoot reduction ( OSR™) for CPU and GPU power • Switches or jumpers for each output enable • Onboard dynamic load for CPU, GPU Vcore output • High efficiency and high density by using TI power block MOSFET • Convenient test points for probing critical waveforms • Four-layer printed-circuit board with 2 oz of copper on the outside layers 2 Atom Tunnel Creek Power System Block Diagram VIN = 8 V -14 V TI Power Block ATOM CPU CORE TPS59610 ATOM CPU CORE (5A) 5V SYSTEM (5A) SYSTEM 5V,3.3V TPS51120 3.3V SYSTEM (5A) MOSFETs used TI Power Block CSD86330Q3D GPU CORE TPS59610 GPU CORE (5A) TOPCLIFF IOH TPS54326 1.2V IOH CORE (3A) LDO TPS74801 1.8V DDR CORE (5A) DDRII 1.8V AND CPU VTT 1.05V TPS59124 1.05V CPU VTT (5A ) DDRII VTT LDO TPS51100 LDO TPS74801 1.5V CPU PLL (0.4A) 0.9V VTT (2A) 1.05V CPU C6 RAM (0.1A) Figure 1. 8-V to 14-V Vin 2010 Atom Tunnel Creek Power System Block Diagram 4 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Electrical Performance Specifications www.ti.com 3 Electrical Performance Specifications Table 1. TPS59610EVM-634 Electrical Performance Specifications (1) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT S 8 12 14 V 10 A 5 mA INPUT CHARACTERISTICS VIN input voltage range VIN Maximum input current VIN = 8 V, all full load No load input current VIN = 14 V, Io = 0 A OUTPUT CHARACTERISTICS CPU (TPS59610) Output voltage Vcore Output voltage regulation Output voltage ripple VID0 = VID1 = VID2 = VID4 = VID6 = 0, VID3 = VID5 = 1 1.00 Line regulation V 0.1% Load regulation (droop) load line –5.7 VIN = 12 V, Io = 5 A at 300 kHz Output load current mΩ 30 0 Output over current mVpp 5 A 7.2 Switching frequency Selectable 200 Full load efficiency VIN = 12 V, 1 V/5 A at 300 kHz 300 A 500 kHz 85.5% GPU (TPS59610) Output voltage Vcore Output voltage regulation Output voltage ripple VID0 = VID2 = VID4 = VID5 = 0, VID1 = VID3 = 1, VID6 = 5 V 1.00 Line regulation V 0.1% Load regulation(droop) load line –5.7 VIN = 12 V, Io = 5 A at 300 kHz 30 Output load current 0 Output over current mΩ mVpp 5 A 7.2 Switching frequency Selectable 200 Full load efficiency VIN = 12 V, 1 V/5 A at 300 kHz 300 A 500 kHz 86.7% 5-V AND 3.3-V SYSTEM (TPS51120) Output voltage Output voltage regulation Output voltage ripple 5/3.3 Line regulation 0.1% Load regulation 0.1% VIN = 12 V, Io = 5 A V 45 Output load current 0 Output over current mVpp 5 A 10 Switching frequency Selectable Full load efficiency VIN = 12 V, 5 V/5 A, 3.3 V/5 A A 280/430 kHz 94.7/92.1% DDR 1.8-V and 1.05-V CPU VTT (TPS59124) Output voltage Output voltage regulation Output voltage ripple 1.8/1.05 Line regulation Load regulation 1% VIN = 12 V, Io = 5 A 30 Output load current 0 Output over current mVpp 5 A 10 Switching frequency Selectable Full load efficiency VIN = 12 V, 1.8 V/5 A, 1.05 V/5 A (1) V 0.1% 300/360 A kHz 90.3/85.1% Jumpers set to default locations, see Section 6 of this user’s guide. SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 5 Electrical Performance Specifications www.ti.com Table 1. TPS59610EVM-634 Electrical Performance Specifications (1) (continued) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT S 1.2-V IOH(TPS54326) Output voltage Output voltage regulation Output voltage ripple 1.2 Line regulation Load regulation 1% VIN = 12 V, 1.2 Vout, Io = 3 A Output load current 20 0 Output over current Switching frequency Full load efficiency V 0.1% 12 Vin, 1.2 V/3 A mVpp 3 A 4.1 A 700 kHz 75.4% 1.5-V CPU PLL(TPS74801) Output voltage Output voltage regulation Output voltage ripple 1.5 Line regulation Load regulation 1% VIN = 1.8 V,1.5 Vout, Io = 0.4 A Output load current V 0.1% 10 0 Output over current mVpp 0.4 2 Switching frequency A N/A Full load efficiency A kHz N/A% 0.9-V VTT (TPS51100) Output voltage Output voltage regulation Output voltage ripple 0.9 V Line regulation 0.1% Load regulation ±40 mV 10 mVpp VIN = 1.8 V, 0.9 VTT, Io = 2 A Output load current 0 Output over current 2 3 Switching frequency A N/A Full load efficiency A kHz N/A% 1.05-V CPU C6 RAM (TPS74801) Output voltage Output voltage regulation Output voltage ripple 1.05 Line regulation Load regulation 10 0 Output over current N/A Full load efficiency mVpp 0.1 2 Switching frequency A A kHz N/A% Operating temperature 6 1% VIN = 1.8 V, 1.05 Vout, Io = 0.1 A Output load current V 0.1% 25 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated °C SLUU465 – November 2010 Submit Documentation Feedback TP104 SLUU465 – November 2010 Submit Documentation Feedback TP107 © 2010, Texas Instruments Incorporated An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System 7 TP103 RT101 150K 1uF C108 C105 1 R106 6.19k 7 Bits VIDSetting J107 R123 1 VID3_C TP129 TP130 TP131 VID2_C VID1_C VID0_C TP128 VID4_C THERM_C TP113 DROOP_C ISLEW_C TP126 VID5_C TP127 VID6_C VID5_C VID4_C VID3_C VID2_C VID1_C VID0_C VID6_C 2.00k R110 R108 1 TP124 R109 0 AGND_C C104 68pF VREF_C R104 45.3k TP105 10.0k R102 R115 100k 1uF C103 R116 100k TPS59610RHB U101 8 J106 4 DRVH_C TP108 C119 0.01uF R117 10.0k R118 10.0k R119 10.0k R120 10.0k TRIPSEL: Current limit selection C117 10uF D101 MBR0530T VBST_C TP112 C110 1uF DRVL_C TP110 GND DPRSLPVRand DPRSTP# setting DPRSTP#_C DPRSLPVR_C R111 5.9 GND TP118 TP117 R121 1.00k J104 2 TP119 R122 1.00k TP121 5 R112 3mohm + C111 220uF J105 9 VR_ONEnable TP120 OFF TP122 S101 ON VR_TT#_C DPRSTP#_C TP123 PGOOD_C C120 0.01uF CLKEN#_C OFF MIN MED MAX 9 8 7 6 5 4 3 2 1 6 3 1 1 VCORE_C 500kHz 400kHz 300kHz 200kHz GND TONSEL: Frequency selection: Jumper on pin5 and pin6 of J103: 300KHz(Default) 7 bits VIDsetting: Jumper short=High, Open=Low Default: VID5=VID3=1, Others=0, sets 1.00Vcore The combination of DPRSLPVRand DPRSTP# sets C4 fast exit rate: 1. No jumper on pin1 and pin2 of J106(Default) 2. Jumper on pin3 and pin4 of J106(Default) VR_ON: Switch to ON: Enable U101, Switch to OFF: Disable U101 OSRSEL: Overshoot reduction selection: Jumper on pin7 and pin8 of J105: MAX(Default) (CHA) OUTPUT: 1.00V@5A J103 TP116 J102 TONSEL: Frequency selection 1 (CHB) Loop Injection Loop Injection R107 10 C121 C122 C123 J101 R105 10 Not used OVPdisable option: No Jumper on JP101 and enable OVP(Default) Loop injection and bode plot measurement TRIPSEL: Current limit selection: Jumper on pin3 and pin4 of J104: 7.2A(Default) Note1: 10uF 10uF 10uF 10uF 10uF C115 C116 C102 100pF CSN_C TP102 C112 C113 C114 C101 100pF TP109 GND TP114 GND 10uF C107 TP106 Vin R103 475 R101 475 OSRSEL: Overshoot reduction selection 10uF C106 TP125 C118 1800pF R113 1 1uH L101 VR_ON_C DPRSLPVR_C 8.9A 7.2A 6.0A 4.6A LL_C TP111 1000pF C109 OVPSEL: OVPdisable option R114 78.7k JP101 CSP_C TP101 4 PWRMON_C TP115 www.ti.com Schematics Schematics Figure 2. TPS59610EVM-634 Schematic, Sheet 1 of 5 7 8 0 R209 AGND TP207 TP204 45.3k TP203 ISLEW_G An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated TP227 15 VID4_G VID3_G VID2_G VID1_G VID0_G VID3_G VID4_G TP226 TP230 VID0_G R223 1 TP229 VID1_G R215 100k 5 Bits VIDSetting J207 VID2_G TP213 THERM_G RT201 150K C208 1uF TP205 DROOP_G C205 1 TP228 R210 2.00k R208 1 C204 68pF R206 6.19k VREF_G R204 10.0k R202 U201 J206 12 R211 5.9 VBST_G TP212 C217 10uF D201 MBR0530T C210 1uF R217 10.0k R218 R219 R220 R221 10.0k 10.0k 10.0k 1.00k R222 1.00k OFF C220 0.01uF S201 ON GND TP209 C206 10uF C207 10uF R212 3mohm Vin TP206 GND OFF MIN MED MAX TP214 J205 C211 VR_ON_G TP220 TP223 DPRSLPVR_G TP201 14 1 1 OSRSEL: Overshoot reduction selection: Jumper on pin7 and pin8 of J205: MAX(Default) Loop injection and bode plot measurement TRIPSEL: Current limit selection: Jumper on pin3 and pin4 of J204: 7.2A(Default) (CHA) J202 GND VCORE_G OUTPUT: 1.00V@5A TP216 500kHz 400kHz 300kHz 200kHz (CHB) Loop Injection Loop Injection R207 10 R205 10 7 bits VIDsetting: Jumper short=High, Open=Low Default: VID3=VID1=1, Others=0, sets 1.00Vcore The combination of DPRSLPVRand DPRSTP# sets C4 fast exit rate: 16 1. No jumper on pin1 and pin2 of J206(Default) 2. Jumper on pin3 and pin4 of J206(Default) 17 VR_ON: Switch to ON: Enable U201, Switch to OFF: Disable U201 15 1 J203 14 TONSEL: Frequency selection: Jumper on pin5 and pin6 of J203: 300KHz(Default) 13 12 11 11 C222 C223 J201 TONSEL: Frequency selection 10uF 10uF C215 C216 C221 C202 100pF CSN_G TP202 CSP_G Not used OVPdisable option: 10 No Jumper on JP201 and enable OVP(Default) 1 Note2: 10uF C213 C214 10uF 10uF C201 100pF R203 475 R201 475 + 220uF C212 OSRSEL: Overshoot reduction selection C218 1000pF TP224 13 1uH L201 R213 1 LL_G TP211 C209 1000pF CLKEN#_G PG_G TP221 DPRSTP#_G TP219 VR_TT#_G TP225 8.9A 7.2A 6.0A 4.6A 78.7k R214 JP201 10 OVPSEL: OVPdisable option 17 VR_ONEnable J204 3.3VBIAS TP222 TP208 DRVH_G TP210 DRVL_G GND GND TRIPSEL: Current limit selection 16 DPRSLPVRand DPRSTP# setting DPRSLPVR_G DPRSTP#_G TPS59610RHB R216 100k C203 1uF C219 0.01uF TP218 TP217 PWRMON_G TP215 Schematics www.ti.com Figure 3. TPS59610EVM-634 Schematic, Sheet 2 of 5 SLUU465 – November 2010 Submit Documentation Feedback GND 5Vout J305 GND GND TP304 Vin TP303 C310 10uF TP309 5Vout TP305 Vin GND 1 21 © 2010, Texas Instruments Incorporated + C312 1000pF R308 1 SW_5V TP307 33uF + C305 + R302 10.0k Option input capacitor for hold up + L301 4.7uH C304 22uF C302 C311 + 330uF R301 10.0k 5VEnable J304 18 J301 C308 0.1uF 5V_BIAS TP311 R306 2.05 R305 0 TP301 PG_5V PwPd SKIPSEL TONSEL PGOOD1 EN1 VBST1 DRVH1 LL1 DRVL1 C316 1uF 33 32 31 30 29 28 27 26 25 VREF2 TP314 VO1 TP313 C301 1000pF U301 TPS51120RHB COM P1 1 2 3 VFB1 4 5 VREF2 GND 6 7 VFB2 R310 3.48k C317 10uF 5.11 R312 C318 1uF 8 9 10 11 12 13 R307 14 2.05 15 16 C319 10uF R311 3.48k EN5 EN3 PGOOD2 EN2 VBST2 DRVH2 LL2 DRVL2 VO2 PGND2 COM P2 24 PGND1 23 CS1 22 V IN 21 VREG5 20 V 5 F IL T 19 VREG3 18 CS2 SLUU465 – November 2010 Submit Documentation Feedback 17 V5FILT R303 10.0k EN_3.3VBIAS 20 3.3V_BIASEnable C309 0.1uF 3.3V_BIAS TP312 TP302 PG_3.3V TP308 C313 1000pF Not used C315 10uF C307 22uF 3.3VEnable J306 3.3Vout GND 21 Option input capacitor for hold up 20 3.3VBIASEnable: 1. No Jumper : Always enable internal 3.3VLDOof U301 for CPUand GPUcircuit 3.3VEnable: 19 1. Jumper on(Default): Disable 3.3Vout of U301 2. No Jumper : Enable 3.3Vout of U301 GND TP310 3.3Vout TP306 J302 5VEnable: 18 1. Jumper on(Default): Disable 5Vout of U301 2. No Jumper : Enable 5Vout of U301 1 C306 33uF C314+ 330uF L302 4.7uH R309 1 Note3: SW_3.3V + 19 1 C303 R304 10.0k www.ti.com Schematics Figure 4. TPS59610EVM-634 Schematic, Sheet 3 of 5 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System 9 10 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated GND R419 10.0k 330uF R423 10.0k 25 1.05V_C6RAMEnable TP407 R412 1 10 IN OUT 9 2 IN OUT 8 3 PG FB 7 4 D.N.C BIAS 6 5 GND EN 11 1 U403 TPS74801DRC 2 3 4 5 1 PwPd R418 7.87k R416 6.81k R404 75.0k R422 7.87k R420 2.49k C401 10uF R405 28.7k U402 TPS74801DRC 10 OUT IN 9 IN OUT 8 FB PG 7 BIAS D.N.C 6 GND EN 11 SW_1.05V C412 1000pF 2.2uH L402 + C408 J406 J408 EN_1.05V_C6RAM C423 1uF C421 4.7uF EN_1.5V C417 10uF 24 1.5VEnable C420 1uF C418 4.7uF GND TP409 1.05Vout TP408 1.05VEnable J403 1.05Vout 22 1 C414 R414 10.0k PwPd J401 GND TP413 GND 1.5Vout 3.30 R410 0 R402 VTT PG_1.05V_C6RAM J407 TP414 GND GND TP416 1.05V_C6RAM 1.05V_C6RAM C427 10uF C424 10uF C428 10uF C426 10uF C413 1000pF R413 1 S3, S5 control: 26 1. S0 state: S3 and S5 ON: VTTREFand VTTON 2. S3 state: S3 OFF and S5 ON, VTTREF on and VTTOFF 3. S4/S5 state: S3 and S5 OFF, VTTREF and VTTOFF 1.05_C6RAMEnable: 25 1. Jumper on(Default): Disable 1.05Vof U403 2. No Jumper : Enable 1.05Vof U403 2 3 4 5 1 Vtt_Ref_GND TP420 Vtt_Ref TP419 9 8 7 6 10 C416 10uF U404 TPS51100DGQ VDDQSNS VIN VINLDO S5 GND VTT S3 PGND VTTREF VTTSNS 11 C406 + 330uF 2.2uH L401 SW_1.8V TP406 Not used 1.05VEnable: 22 1. Jumper on(Default): Disable 1.05Vout of U401 2. No Jumper: Enable 1.05Vout of U401 1.8VEnable: 23 1. Jumper on (Default): Disable 1.8Vout of U401 2. No Jumper: Enable 1.8Vout of U401 1.5VEnable: 24 1. Jumper on(Default): Disable 1.5Vof U402 2. No Jumper : Enable 1.5Vof U402 1 Note4: VTT_GND VTT VTT_GND J409 TP417 VDDQ C411 22pF 3.48k C410 1uF C404 10uF 3.48k R408 R411 C405 0.1uF 0.9VVTT/ 2A C409 4.7uF 1.5VCPUPLL @0.4A 1.05VCPUC6 RAM@100mA J405 TP412 1.5Vout 5V_BIAS TP405 U401 TPS59124RGE 24 VO1 PGOOD1 23 EN1 VFB1 22 VBST1 GND 21 TONSEL DRVH1 20 LL1 VFB2 19 DRVL1 VO2 18 PGOOD2 PGND1 17 TRIP1 EN2 16 VBST2 V5IN 15 DRVH2 V5FILT 14 TRIP2 LL2 13 DRVL2 PGND2 PwPd 100k R401 C403 10uF PG_1.5V C422 4.7uF C419 4.7uF R409 0 1 2 3 4 5 6 7 8 9 10 11 12 TP401 PG_1.8V TP418 TP415 R421 100k TP402 PG_1.05V TP410 R417 100k C407 0.1uF R407 100k 75.0k R406 102k R403 C402 10uF SW401 S3 SW400 S5 C425 4.7uF TP404 GND J404 TP403 1.8Vout 1.8VEnable GND 1.8Vout J402 26 S3 and S5 Control C429 0.1uF 23 1 C415 R415 10.0k 1.8V@5A Schematics www.ti.com Figure 5. TPS59610EVM-634 Schematic, Sheet 4 of 5 SLUU465 – November 2010 Submit Documentation Feedback SLUU465 – November 2010 Submit Documentation Feedback © 2010, Texas Instruments Incorporated R513 100k R511 8.06k R503 10.0k R502 5.62k R501 68.1 C508 0.01uF C501 1uF D501 BAT54 R512 10.0k C509 1uF EN_1.2V TP504 PG_1.2V TP503 C502 0.01uF GND TP502 17 16 15 14 13 R504 100k An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System 28 R508 10.0k R507 10.0k 9 12 11 10 J501 TP505 1 R506 1 C506 SW_1.2V SW501 OFF ON U504A:A SN74HC08D SW502 GPUDyn Load OFF CPUDyn. Load ON 27 1.2VEnable C505 0.1uF On Board Dynamic Load C510 0.1uF TP508 DL_CLK C504 22nF 5 6 7 8 R505 10.0k 1 VBST VFB 2 VREG5 U501 SW 3 SS TPS54326RGT SW 4 SW GND C503 22uF P w rP d Vin VO VCC V IN V IN PG EN PGND PGND TP501 U504D:D U504C:C U504B:B L501 1.5uH C513 1uF C507 47uF U503 UCC37324DR C511 1uF J502 R509 330 D502 GREEN GND TP507 1.2Vout GND 1.2V TP506 R510 330 D503 GREEN 100 R515 100 R514 1 C512 R516 0.001 Q501 CSD16407Q5 R518 0.100 R517 0.100 1 C514 R521 0.001 R520 0.100 R519 0.100 Q502 CSD16407Q5 28 On Board Dynamic Load: 1. SW501: ONEnable CPUCore Dynamic load OFFDisable CPUCore Dynamic load 2. SW502: ONEnable CPUCore Dynamic load OFFDisable GPUCore Dynamic load 27 1.2VEnable: 1. Jumper on(Default): Disable 1.2Vof U501 2. No Jumper : Enable 1.2Vof U501 Not used Note5: 1 www.ti.com Schematics Figure 6. TPS59610EVM-634 Schematic, Sheet 5 of 5 11 Test Setup www.ti.com 5 Test Setup 5.1 Test Equipment Voltage Source VIN: The input voltage source VIN must be a 0-V to 14-V variable dc source capable of supplying 10 Adc. Connect VIN to J304 as shown in Figure 7. Multimeters: V1: Vin at TP303 (VIN) and TP304 (GND) V2: Vout at each output test point. For example: CPU at J101 A1: Vin input current Output Load: The output load must be an electronic constant resistance mode load capable of 0 Adc to 10 Adc. Oscilloscope: A digital or analog oscilloscope can be used to measure the output ripple. The oscilloscope must be set for 1-MΩ impedance, 20-MHz bandwidth, ac coupling, 2-µs/division horizontal resolution, 50-mV/division vertical resolution. Test points on each output can be used to measure the output ripple voltage. Do not use a leaded ground connection as this may induce additional noise due to the large ground loop. Recommended Wire Gauge: 1. VIN to J304 (12-V input): The recommended wire size is AWG 16 per input connection, with the total length of wire less than 4 feet (2-foot input, 2-foot return). 2. Each outputs to LOAD: The minimum recommended wire size is AWG 16, with the total length of wire less than 4 feet (2-foot output, 2-foot return) 5.2 Recommended Test Setup DC Source VIN + - 1.05VC6 1.5V 0.9V 1.8V 1.05V 5V 3.3V CPU V2 + GPU + 1.2V V1 + - - - A1 Load Figure 7. TPS59610EVM-634 Recommended Test Setup Figure 7 is the recommended test setup to evaluate the TPS59610EVM-634. Working at an ESD workstation, ensure that wrist straps, bootstraps, or mats are connected referencing the user to earth ground before handling the EVM. 12 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Configuration www.ti.com Input Connections: 1. Prior to connecting the dc input source VIN, it is advisable to limit the source current from VIN to 10 A maximum. Ensure that VIN is initially set to 0 V and connected as shown in Figure 7. 2. Connect a voltmeter V1 at TP303 (VIN) and TP304 (GND) to measure VIN input voltage. 3. Connect a current meter A1 between VIN dc source and J304. Output Connections (For example, CPU testing) 1. Connect the load to J102, and set the load to constant resistance mode to sink 0 Adc before VIN is applied. 2. Connect a voltmeter V2 at J101 to measure CPU 1-Vcore voltage as shown in Figure 7. 6 Configuration All jumper selections must be made prior to applying power to the EVM. Users can configure this EVM per the following configurations. 6.1 6.1.1 CPU and GPU Configuration Current-Limit Trip Selection (J104 for CPU and J204 for GPU) The current-limit trip can be set by J104 and J204 TRIPSEL. Default setting: 7.2 A. Table 2. Current-Limit Trip Selection 6.1.2 Jumper set to TRIPSEL OCP Limit, Typ. (A) Top (1-2 pin shorted) 5VFILT 8.9 Second (3-4 pin shorted) 3.3VBIAS 7.2 Third (5-6 pin shorted) VREF 6 Bottom (7-8 pin shorted) GND 4.6 Frequency Selection (J103 for CPU and J203 for GPU) The operating frequency can be set by J103 and J203 TONSEL. Default setting: 300 kHz. Table 3. Frequency Selection 6.1.3 Jumper set to TONSEL Frequency (kHz) Top (1-2 pin shorted) 5VFILT 500 Second (3-4 pin shorted) 3.3VBIAS 400 Third (5-6 pin shorted) VREF 300 Bottom (7-8 pin shorted) GND 200 Overshoot Reduction Selection (J105 for CPU and J205 for GPU) The overshoot reduction can be set by J105 and J205 OSRSEL. Default setting: Maximum Table 4. Overshoot Reduction Selection Jumper set to OSR Overshoot Voltage Reduction Top(1-2 pin shorted) 5VFILT OFF Second (3-4 pin shorted) 3.3VBIAS Minimum Third (5-6 pin shorted) VREF Medium Bottom (7-8 pin shorted) GND Maximum SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 13 Configuration 6.1.4 www.ti.com VID Bits Selection The CPU Vcore voltage can be set by J107( 7-Bit CPU VID). Default setting: 0101000 for 1.000V Jumper = 1 No Jumper = 0 Table 5. CPU VID Bits Selection 7-Bit VID Table (1 = 1.05 V, 0 = GND) VID6 VID5 VID4 VID3 VID2 VID1 VID0 Vcore(V) 0 0 0 0 0 0 0 1.500 0 0 1 1 0 0 0 1.200 0 1 0 1 0 0 0 1.000 0 1 1 1 0 0 0 0.800 1 0 0 1 0 0 0 0.600 1 0 1 1 0 0 0 0.400 1 1 0 0 0 0 0 0.300 See data sheet for details. The GPU Vcore voltage can be set by J207 (5-bit GPU VID). Default setting: 01010 for 1.000V Table 6. GPU VID Bits Selection 5-Bit VID Table (1 = 1.05 V, 0 = GND) VID4 VID3 VID2 VID1 VID0 Vcore(V) 0 0 0 0 0 1.250 0 0 1 1 0 1.100 0 1 0 1 0 1.000 1 0 0 1 0 0.800 1 1 0 1 0 0.600 1 1 1 1 1 0.400 See data sheet for details. 6.1.5 Deep Sleep Mode Selection (DPRSLPVR) The combination of DPRSTP# and DPRSLPVR sets C4 exit rate. These can be set by J106 for CPU and J206 for GPU. Default setting: Jumper on DPRSLPVR and no jumper on DPRSTP# of J106 and J206 Table 7. C4 Exit Rate Selection 6.1.6 Jumper set to C4 exit rate Jumper on DPRSLPVR No jumper on DPRSTP# C4 exit fast No jumper on DPRSLPVR No jumper on DPRSTP# C4 exit slow Overvoltage Protection Selection (JP101 for CPU and JP201 for GPU) The overvoltage protection selection can be set by JP101 and JP201, OVPSEL Default setting: No jumper shorts on JP101 and JP201 to enable OVP 14 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Configuration www.ti.com Table 8. Overvoltage Protection selection Jumper set to 6.1.7 Selection No jumper OVP enabled Jumper shorted OVP disabled Onboard Dynamic Load Selection (SW501 for CPU and SW502 for GPU) The onboard dynamic load can be set by SW501 and SW502. Default setting: Push SW501 and SW502 to the right to disable the onboard dynamic load. Table 9. Onboard Dynamic Load Selection 6.1.8 Switch set to Dynamic Load Selection Push SW501 to left (On position) Enable 5-A onboard dynamic load at CPU Push SW501 to right (Off position) Disable 5-A onboard dynamic load at CPU Push SW502 to left (On position) Enable 5-A onboard dynamic load at GPU Push SW502 to right (Off position) Disable 5-A onboard dynamic load at GPU Enable Selection (S101 for CPU and S201 for GPU) The Vcore of CPU and GPU can be enabled and disabled by S101 and S201. Default setting: Push S101 and S201 to the TOP(Off position) to disable both CPU and GPU Table 10. Enable Selection 6.2 6.2.1 Switch set to Dynamic Load Selection Push S101 to bottom (On position) Enable CPU Vcore Push S101 to top (Off position) Disable CPU Vcore Push S201 to bottom (On position) Enable GPU Vcore Push S201 to top (Off position) Disable GPU Vcore 5-V/3.3-V System Configuration 3.3VBIAS Enable Selection (J303) 3.3VBIAS Enable can be set by J303, EN_3.3VBIAS Default setting: No Jumper shorts on J303 to enable the 3.3VBIAS Note: 3.3VBIAS needs to always be enabled for CPU and GPU circuit 6.2.2 5-V/3.3-V Enable Selection (J301 for 5 V and J302 for 3.3 V) 5-V/3.3-V Enable can be set by J301 and J302, EN_5V and EN_3.3V Default setting: Jumper shorts on J301 and J302 to disable 5 V/3.3 V. Table 11. 5-V/3.3-V Enable Selection 6.3 6.3.1 Jumper set to Selection Jumper on J301 5-V Disabled No jumper on J301 5-V Enabled Jumper on J302 3.3-V Disabled No jumper on J302 3.3-V Enabled DDR 1.8-V/1.05-V CPU VTT Configuration 1.8-V/1.05-V Enable can be set by J402 for 1.8 V and J401 for 1.05 V, EN_1.8V and EN_1.05V Default setting: Jumper shorts on J402 to disable 1.8 V. No Jumper on J401 to enable 1.05 V SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 15 Configuration www.ti.com Note: 1.05V enable is for VID setting of CPU and GPU Table 12. 1.8-V/1.05-V Enable Selection 6.4 6.4.1 Jumper set to Selection Jumper on J402 1.8V Disabled No Jumper on J402 1.8V Enabled Jumper on J401 1.05V Disabled No Jumper on J401 1.05V Enabled 0.9-V VTT and 0.9-V VTTREF Configuration 0.9-V VTT and 0.9-V VTTREF Enable Selection (SW401 for S3, SW400 for S5) Default setting: Push SW400 and SW401 to bottom to disable both 0.9VTT and 0.9VTTREF. Table 13. SW400(S5), SW401(S3) Enable Selection 6.5 6.5.1 State SW401 set to SW400 set to VTT, VTTREF S0 S3 Top(on) S5 Top(on) VTT and VTTREF on S3 S3 Bottom(off) S5 Top(on) VTT off and VTTREF on S4/S5 S3 Bottom(off) S5 Bottom(off) VTT and VTTREF off 1.5-V CPU PLL Configuration 1.5-V Enable Selection (J406) 1.5-V Enable can be set by J406, EN_1.5V Default setting: Jumper shorts on J406 to disable 1.5 V Table 14. 1.5-V Enable Selection 6.6 6.6.1 Jumper set to Selection No Jumper 1.5V Enabled Jumper on 1.5V Disabled 1.05-V CPU C6 RAM Configuration 1.05-V CPU C6 RAM Enable Selection (J408) 1.05-V Enable can be set by J408, EN_1.05V_C6RAM Default setting: Jumper shorts on J408 to disable 1.05-V CPU C6 RAM Table 15. 1.05-V CPU C6 RAM Enable Selection Jumper set to 16 Selection No Jumper 1.05V CPU R6 RAM Enabled Jumper on 1.05V CPU C6 RAM Disabled An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Test Procedure www.ti.com 6.7 6.7.1 1.2-V IOH Configuration 1.2-V Enable Selection (J501) 1.2-V Enable can be set by J501, EN_1.2V Default setting: Jumper shorts on J501 to disable 1.2 V Table 16. 1.2-V Enable selection Jumper set to Selection No Jumper 1.2V Enabled Jumper on 1.2V Disabled 7 Test Procedure 7.1 Line/Load Regulation and Efficiency Measurement Procedure The CPU measurement is performed in the following manner. 1. Set up EVM as described in Section 5.1 and Figure 7. 2. Ensure that the Load is set to constant resistance mode and sink 0 A. 3. Ensure that all the jumper configuration settings are per Section 6 4. Ensure that the S101 VR_ON enable switch is set to OFF before VIN is applied. 5. Increase VIN from 0 V to 12 V. Use V1 to measure VIN voltage. 6. Set switch S101 to ON to enable the controller. 7. Use V2 to measure Vcore_c voltage. 8. Vary Load from 0 Adc to 5 Adc; Vcore_c must remain in load regulation. 9. Vary VIN from 8 V to 14 V; Vcore_c must remain in line regulation. 10. Set switch S101 to OFF to disable the controller. 11. Decrease Load to 0 A. 12. Decrease VIN to 0 V. Other output testing is the same. 7.2 Onboard Transient Response Measurement CPU and GPU Only 1. Set up EVM as described in Section 5.1 and Figure 7. 2. Ensure that all the jumper configuration settings are per Section 6 3. Remove the load from J102 for CPU or J202 for GPU 4. Ensure that VR_ON (S101 for CPU and S201 for GPU) is on OFF before VIN is applied. 5. Increase VIN from 0 V to 12 V. Use V1 to measure VIN voltage. 6. Use TP508 (DL_CLK) and TP209 (GND) to measure transient timing signal. 7. Push switch SW501 (CPU) or SW502 (GPU) to ON position (left), and dynamic load LED D503 for CPU and D502 for GPU illuminate. 8. Measure the Vcore_c or Vcore_G transient response by using TP116 (CPU) or TP216 (GPU). SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 17 Test Procedure 7.3 www.ti.com Loop Gain/Phase Measurement CPU and GPU Only 1. Set up EVM as described in Section 5.1 and Figure 7. 2. CPU: Connect the isolation transformer to VSNS of J101 (CPU) and Vcore_C (+)(CPU) of J102. GPU: Connect the isolation transformer to VSNS of J201 (GPU) and Vcore_G (+)(GPU) of J202 3. CPU: Connect input signal CHA to VSNS pin of J101 and connect output signal CHB to Vcore_C(+) of J102. GPU: Connect input signal CHA to VSNS pin of J201, and connect output signal CHB to Vcore_G(+) of J202. 4. Connect the GND lead of CHA and CHB to GND of TP116 (CPU) and TP216 (GPU). 5. Inject around 50-mV or less signal through the isolate transformer. 6. Sweep the frequency from 100 Hz to 1 MHz with 10-Hz or lower post filter. The control loop gain and phase margin can be measured. 7. Disconnect isolate transformer from the bode plot setup before making other measurements (signal injection into feedback may interfere with accuracy of other measurement). 7.4 Equipment Shutdown 1. Shut down Load. 2. Shut down VIN. 18 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com 8 Performance Data and Typical Characteristic Curves Figure 8 through Figure 68 present typical performance curves for TPS59610EVM-634. Jumpers set to default locations; see Section 6 of this user’s guide 8.1 CPU 100 1.04 VI = 12 V 90 VI = 8 V 1.02 VO - Output Voltage - V 80 Efficiency - % 70 VI = 14 V 60 50 40 30 VI = 12 V VI = 8 V SPEC_nom SPEC_max 1 0.98 VI = 14 V 0.96 20 SPEC_min 10 0.94 0 0.001 0.01 0.1 1 IO - Output Current - A Figure 8. CPU Efficiency TPS9610EVM-634 CPU Enable Start Up 10 0 0.5 1 1.5 2 2.5 3 3.5 IO - Output Current - A 4 4.5 5 Figure 9. CPU Load Regulation TPS9610EVM-634 CPU Enable Shut Down Test Condition: 12 Vin, 1 V/5 A Test Condition: 12 Vin, 1 V/5 A CH1: VR_ON CH1: VR_ON CH2: 1 Vcore CH2: 1 Vcore CH3: PGOOD CH3: PGOOD CH4: CLKEN# CH4: CLKEN# Figure 10. CPU Enable Turnon SLUU465 – November 2010 Submit Documentation Feedback Figure 11. Enable Turnoff An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 19 Performance Data and Typical Characteristic Curves TPS9610EVM-634 CPU Switching Node www.ti.com TPS9610EVM-634 CPU Output Ripple Test Condition: 12 Vin, 1 V/5 A Test Condition: 12 Vin, 1 V/5 A CH1: LL_C CH1: 1 Vcore Output Ripple Figure 13. CPU Vcore Ripple Figure 12. CPU Switching Node TPS9610EVM-634 CPU Over Shoot Reduction (OSR) CH1: 1 Vcore Test Condition: 12 Vin, 1 V/5 A-0 A Load Release TPS9610EVM-634 CPU Over Shoot Reduction (OSR) OSR = OFF Test Condition: 12 Vin, 1 V/5 A-0 A Load Release OSR = MAX CH1: 1 Vcore CH2: DRVL_C CH2: DRVL_C CH3: LL_C CH3: LL_C Figure 14. CPU Output Load Release Without Overshoot Reduction 20 Figure 15. CPU Output Load Release With Maximum Overshoot Reduction An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com TPS9610EVM-634 CPU Output Transient TPS9610EVM-634 CPU Output Transient Test Condition: 12 Vin, 1 V/0.04 A-5 A Transient CH1: 1 V core Output Test Condition: 12 Vin, 1 V/0.04 A-5 A Transient CH1: 1 V core Output CH3: LL CH3: LL CH4: 1 Vcore Output Current CH4: 1 Vcore Output Current Figure 16. CPU Transient From DCM to CCM Figure 17. CPU Transient From CCM to DCM Figure 18. CPU Bode Plot 12 Vin, 1 V/5 A SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 21 Performance Data and Typical Characteristic Curves www.ti.com TPS59610 Figure 19. CPU Top Board Figure 20. CPU Bottom Board Test condition: 12 Vin, 1 V/5 A, no airflow 22 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com 8.2 GPU 100 90 VI = 12 V VI = 8 V 1.04 80 Efficiency - % VO - Output Voltage - V SPEC_max 70 VI = 14 V 60 50 40 30 1.02 VI = 14 V VI = 8 V 1 SPEC_nom 20 SPEC_min VI = 12 V 10 0 0.001 0.01 0.1 1 IO - Output Current - A 10 0.98 0 0.5 1 1.5 2 2.5 3 3.5 IO - Output Current - A 4 4.5 5 NOTE: Intel spec calls for 3% offset at the VID setting Figure 21. CPU Efficiency Figure 22. GPU Load Regulation TPS9610EVM-634 GPU Enable Start Up Test Condition: 12 Vin, 1 V/5 A TPS9610EVM-634 GPU Enable Shut Down CH1: VR_ON CH1: VR_ON CH2: 1 Vcore CH2: 1 Vcore CH3: PGOOD CH3: PGOOD CH4: CLKEN# CH4: CLKEN# Figure 23. GPU Enable Turnon SLUU465 – November 2010 Submit Documentation Feedback Test Condition: 12 Vin, 1 V/5 A Figure 24. GPU Enable Turnoff An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 23 Performance Data and Typical Characteristic Curves TPS9610EVM-634 GPU Switching Node www.ti.com TPS9610EVM-634 GPU Output Ripple Test Condition: 12 Vin, 1 V/5 A Test Condition: 12 Vin, 1 V/5 A CH1: LL_G 1 Vcore Output Ripple Figure 25. GPU Switching Node TPS9610EVM-634 GPU Over Shoot Reduction (OSR) Test Condition: 12 Vin, 1 V/5 A-0A Load Release Figure 26. GPU Vcore Ripple TPS9610EVM-634 GPU Over Shoot Reduction (OSR) OSR = MAX OSR = OFF CH1: 1 Vcore CH1: 1 Vcore CH2: DRVL_G CH2: 1 DRVL_G CH3: LL_G CH3: LL_G Figure 27. GPU Output Load Release Without Overshoot Reduction 24 Test Condition: 12 Vin, 1 V/5 A-0A Load Release Figure 28. GPU Output Load Release With Maximum Overshoot Reduction An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com TPS9610EVM-634 GPU Output Transient: OSR max TPS9610EVM-634 GPU Output Transient Test Condition: 12 Vin, 1 V/0 A-5 A Transient Test Condition: 12 Vin, 1 V/0 A-5 A Transient CH1: 1 Vcore CH2: 1 Vcore CH3: LL CH3: LL CH4: 1 Vcore Output Current CH4: 1 Vcore Output Current Figure 29. GPU Transient From DCM to CCM Figure 30. GPU Transient From CCM to DCM Figure 31. GPU Bode Plot 12 Vin, 1 V/5 A SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 25 Performance Data and Typical Characteristic Curves www.ti.com CSD86330Q3 TPS59610 Figure 33. CPU Bottom Board Figure 32. CPU Top Board Test condition: 12 Vin, 1 V/5 A, no airflow 8.3 5-V/3.3-V System 5.6 100 VI = 8 V 90 80 VI = 12 V 5.4 VI = 14 V VO - Output Voltage - V Efficiency - % 70 60 50 40 30 20 5.2 VI = 12 V VI = 14 V 5 VI = 8 V 4.8 4.6 10 0 0.001 0.01 0.1 1 IO - Output Current - A 10 Figure 34. 5-V Efficiency 26 4.4 0 1 2 3 IO - Output Current - A 4 5 Figure 35. 5-V Load Regulation An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com TPS9610EVM-634 5 V Enable Start Up Test Condition: 12 Vin, 5 V/5 A TPS9610EVM-634 5 V Enable Shut Down Test Condition: 12 Vin, 5 V/5 A CH1: EN_5 V CH1: EN_5 V CH2: 5 Vout CH2: 5 Vout CH3: PG_5 V CH3: PG_5 V Figure 36. 5-V Enable Turnon TPS9610EVM-634 5 V Switching Node Figure 37. 5-V Enable Turnoff TPS9610EVM-634 5 V Output Ripple Test Condition: 12 Vin, 5 V/5 A Test Condition: 12 Vin, 5 V/5 A CH1: 5 V Output Ripple CH1: SW_5 V Figure 38. 5-V Switching Node SLUU465 – November 2010 Submit Documentation Feedback Figure 39. 5-V Vo Ripple An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 27 Performance Data and Typical Characteristic Curves www.ti.com 3.35 100 VI = 8 V 90 80 VI = 12 V VO - Output Voltage - V Efficiency - % 70 VI = 14 V 60 50 40 30 VI = 14 V VI = 12 V 3.3 VI = 8 V 3.25 20 10 0 0.001 0.01 0.1 1 IO - Output Current - A 10 Figure 40. 3.3-V Efficiency TPS9610EVM-634 3.3 V Enable Start Up Test Condition: 12 Vin, 3.3 V/5 A 3.2 0 1 2 3 IO - Output Current - A 4 5 Figure 41. 3.3-V Load Regulation TPS9610EVM-634 3.3 V Enable Shut Down Test Condition: 12 Vin, 3.3 V/5 A CH1: EN_3.3 V CH1: EN_3.3 V CH2: 3.3 Vout CH2: 3.3 Vout CH3: PG_3.3 V CH3: PG_3.3 V Figure 42. 3.3-V Enable Turnon 28 Figure 43. 3.3-V Enable Turnoff An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com TPS9610EVM-634 3.3 V Switching Node TPS9610EVM-634 3.3 V Output Ripple Test Condition: 12 Vin, 3.3 V/5 A Test Condition: 12 Vin, 3.3 V/5 A CH1: 3.3 V Output Ripple CH1: SW_3.3 V Figure 45. 3.3-V Vo Ripple Figure 44. 3.3-V Switching Node TPS51120 Figure 46. 5-V/3.3-V TOP Board Figure 47. 5-V/3.3-V Bottom Board Test condition: 12 Vin, 5 V/5 A and 3.3 V/5 A, no airflow SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 29 Performance Data and Typical Characteristic Curves 8.4 www.ti.com 1.8-V DDR/1.05-V CPU VTT 100 1.95 VI = 12 V VI = 8 V 90 1.9 80 VI = 14 V VO - Output Voltage - V Efficiency - % 70 60 50 40 30 20 VI = 12 V 1.85 VI = 14 V 1.8 VI = 8 V 1.75 1.7 10 0 0.001 1.65 0.01 0.1 1 IO - Output Current - A 10 Figure 48. 1.8-V Efficiency TPS9610EVM-634 1.8 V Enable Start Up 0 1 2 3 IO - Output Current - A 4 5 Figure 49. 1.8-V Load Regulation Test Condition: 12 Vin, 1.8 V/5 A TPS9610EVM-634 1.8 V Enable Shut Down Test Condition: 12 Vin, 1.8 V/5 A CH1: EN_1.8 V CH1: EN_1.8 V CH2: 1.8 Vout CH2: 1.8 Vout CH3: PG_1.8 V CH3: PG_1.8 V Figure 50. 1.8-V Enable Turnon 30 Figure 51. 1.8-V Enable Turnoff An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com TPS9610EVM-634 1.8 V Switching Node TPS9610EVM-634 1.8 V Output Ripple Test Condition: 12 Vin, 1.8 V/5 A Test Condition: 12 Vin, 1.8 V/5 A CH1: 1.8 V Output Ripple CH1: SW_1.8 V Figure 52. 1.8-V Switching Node Figure 53. 1.8-V Vo Ripple 1.1 100 90 VI = 12 V VI = 8 V 80 VO - Output Voltage - V 1.08 Efficiency - % 70 VI = 14 V 60 50 40 30 20 VI = 14 V 1.06 VI = 12 V VI = 8 V 1.04 1.02 10 0 0.001 1 0.01 0.1 1 IO - Output Current - A Figure 54. 1.05-V Efficiency SLUU465 – November 2010 Submit Documentation Feedback 10 0 1 2 3 IO - Output Current - A 4 5 Figure 55. 1.05-V Load Regulation An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 31 Performance Data and Typical Characteristic Curves TPS9610EVM-634 1.05 V Enable Start Up TestCondition: Condition:12 12Vin, Vin,1.05 1.05V/5 V/5AA Test www.ti.com TPS9610EVM-634 1.05 V Enable Shut Down Test Condition: 12 Vin, 1.05 V/5 A CH1: EN_1.05 V CH1: EN_1.05 V CH2: 1.05 Vout CH2: 1.05 Vout CH3: PG_1.05 V CH3: PG_1.05 V Figure 56. 1.05-V Enable Turnon TPS9610EVM-634 1.05 V Switching Node Test Condition: 12 Vin, 1.05 V/5 A Figure 57. 1.05-V Enable Turnoff TPS9610EVM-634 1.05 V Output Ripple Test Condition: 12 Vin, 1.05 V/5 A CH1: SW_1.05 V CH1: 1.05 V Output Ripple Figure 58. 1.05-V Switching Node 32 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated Figure 59. 1.05-V Vo Ripple SLUU465 – November 2010 Submit Documentation Feedback Performance Data and Typical Characteristic Curves www.ti.com TPS59124 CSD86330Q3D Figure 60. 1.8-V/1.05-V Top Board Figure 61. 1.8-V/1.05-V Bottom Board Test condition: 12 Vin, 1.8 V/5 A and 1.05 V/5 A, no airflow 8.5 1.2-V IOH 1.3 100 90 VI = 8 V VI = 12 V 1.28 80 VO - Output Voltage - V 1.26 Efficiency - % 70 VI = 14 V 60 50 40 30 1.24 VI = 14 V 1.22 1.2 VI = 8 V 1.18 1.16 20 1.14 10 1.12 0 0.001 VI = 12 V 1.1 0.01 0.1 1 IO - Output Current - A Figure 62. 1.2-V Efficiency SLUU465 – November 2010 Submit Documentation Feedback 10 0 0.5 1 1.5 2 IO - Output Current - A 2.5 3 Figure 63. 1.2-V Load Regulation An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 33 Performance Data and Typical Characteristic Curves TPS9610EVM-634 1.2 V IOH Core Enable Start Up www.ti.com Test Condition: 12 Vin, 1.2 V/3 A TPS9610EVM-634 1.2 IOH Core Enable Shut Down CH1: EN_1.2 V CH1: EN_1.2 V CH2: 1.2 Vout CH2: 1.2 Vout CH3: PG_1.2 V CH3: PG_1.2 V Figure 64. 1.2-V Enable Turnon TPS9610EVM-634 1.2 V Switching Node Test Condition: 12 Vin, 1.2 V/3 A Test Condition: 12 Vin, 1.2 V/3 A Figure 65. 1.2-V Enable Turnoff TPS9610EVM-634 1.2 V IOH Output Ripple CH1: 1.2 V Switching Node Test Condition: 12 Vin, 1.2 V/3 A CH1: 1.2 V Output Ripple Figure 66. 1.2-V Switching Node Figure 67. 1.2-V Vo Ripple TPS54326 Figure 68. 1.2-V Top Board Test Condition: 12 Vin, 1.2 V/3 A, No Airflow 34 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback EVM Assembly Drawings and PCB Layout www.ti.com 9 EVM Assembly Drawings and PCB Layout The following figures (Figure 69 through Figure 74) show the design of the TPS59610EVM-634 printed circuit board. The EVM has been designed using 4 Layers circuit board with 2oz copper on outside layers. Figure 69. TPS59610EVM-634 Top Layer Assembly Drawing, Top View Figure 70. TPS59610EVM-634 Bottom Assembly Drawing, Bottom View Figure 71. TPS59610EVM-634 Top Copper, Top View SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 35 EVM Assembly Drawings and PCB Layout www.ti.com ` Figure 72. TPS59610EVM-634 Internal Layer 2, Top View Figure 73. TPS59610EVM-634 Internal Layer 3, Top View Figure 74. TPS59610EVM-634 Bottom Layer, Bottom View 36 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Bill of Materials www.ti.com 10 Bill of Materials Table 17 shows the EVM major components list according to the schematic shown in Figure 2 through Figure 6. Table 17. Bill of Materials Qty RefDes Description MFR Part Number 3 C1, C2, C3 Capacitor, Aluminum, 330uF, 16V, 20%, –40-85°C Panasonic-ECG ECA-1CM331B 4 C101, C102, C201, C202 Capacitor, Ceramic, 100pF, 50V, C0G, 10%, 0603 STD STD 6 C103, C108, C110, C203, C208, C210 Capacitor, Ceramic, 1uF, 16V, X7R, 20%, 0603 STD STD 2 C104, C204 Capacitor, Ceramic, 68pF, 50V, C0G, 10%, 0603 STD STD 8 C106, C107, C206, C207, C401– C404 Capacitor, Ceramic, 10uF, 25V, X5R, 20%, 1206 STD STD 3 C109, C209, C301 Capacitor, Ceramic, 1000pF, 50V, X7R, 20%, 0402 STD STD 2 C111, C211 Capacitor, Aluminum, 220uF, 2V, 20%, 9mohm, 7343 Panasonic-ECG EEF-SX0D221R 20 C112–C116, C212–C216, C310, C315, C317, C319, C416, C417, C424, C426–C428, Capacitor, Ceramic, 10uF, 6.3V, X5R, 20%, 0805 STD STD 2 C117, C217 Capacitor, Ceramic, 10uF, 6.3V, X5R, 20%, 0603 STD STD 1 C118 Capacitor, Ceramic, 1800pF, 50V, X7R, 20%, 0805 STD STD 5 C119, C120, C219, C220, C502 Capacitor, Ceramic, 0.01uF, 50V, X7R, 20%, 0603 STD STD 5 C218, C312, C313, C412, C413 Capacitor, Ceramic, 1000pF, 50V, X7R, 20%, 0805 STD STD 3 C304, C307, C503 Capacitor, Ceramic, 22uF, 16V, X5R, 20%, 1210 STD STD 2 C305, C306 Capacitor, Tant cap, 33uF, 16V, 0.045ohms, 20%, 7343D KEMET T520V336M016ATE045 3 C308, C309, C510 Capacitor, Ceramic, 0.1uF, 16V, X7R, 20%, 0402 STD STD 2 C311, C314 Capacitor, Tant cap, 330uF, 6.3V, 0.010ohms, 20%, 7343D KEMET T530D337M006ATE010 2 C316, C318 Capacitor, Ceramic, 1uF, 16V, X5R, 20%, 0402 STD STD 4 C405, C407, C429, C505 Capacitor, Ceramic, 0.1uF, 25V, X7R, 20%, 0603 STD STD 2 C406, C408 Capacitor, SP cap, 330uF, 2.5V, 0.015ohms, 20%, 7343D Panasonic-ECG EEF-CX0E331R 1 C409 Capacitor, Ceramic, 4.7uF, 10V, X5R, 20%, 0603 STD STD 7 C410, C420, C423, C501, C509, C511, C513 Capacitor, Ceramic, 1uF, 16V, X7R, 20%, 0603 STD STD 1 C411 Capacitor, Ceramic, 22pF, 50V, C0G, 20%, 0603 STD STD 4 C418, C419, C421, C422 Capacitor, Ceramic, 4.7uF, 6.3V, X5R, 20%, 0603 STD STD 1 C425 Capacitor, Ceramic, 4.7uF, 6.3V, X5R, 20%, 0805 STD STD 1 C504 Capacitor, Ceramic, 22nF, 16V, X7R, 20%, 0603 STD STD 1 C507 Capacitor, Ceramic, 47uF, 6.3V, X5R, 20%, 1210 STD STD 1 C508 Capacitor, Ceramic, 0.01uF, 25V, X7R, 20%, 0402 STD STD 2 D101, D201 Diode, Schottky, 0.5A, 30V, SOD-123, On Semi MBR0530T 1 D501 Diode, Schottky, 200mA, 30V, SOT-23, Vishay-Liteon BAT54-V-GS08 2 D502, D503 Diode, LED, Green Clear, 20mcd, 0.079x0.049 Lite On LTST-C170GKT 2 L101, L201 Inductor, SMT, 1uH, 11.1A , 7.81mohm, 0.256" x 0.280" TDK SPM6530T-1R0M120 2 L301, L302 Inductor, SMT, 4.7uH, 6.0A, 25mohm, 6.8mm x 6.8mm Coiltronics HCP0704-4R7-R 2 L401, L402 Inductor, SMT, 2.2uH, 10A, 13.6mohm, 0.255" x 0.270" Vishay IHLP2525EZER2R2M01 1 L501 Inductor, SMT, 1.5uH, 5.5A, 40.4mohm, 0.204" x 0.216" Vishay IHLP2020CZER1R5M11 6 Q101, Q201, Q301,Q302, Q401, Q402 MOSFET, Synchronous Buck NexFET Power Block SON 3.3 x 3.3mm TI CSD86330Q3D 2 Q501, Q502 MOSFET, Nchan, 25V, 31A, 2.5mohm, QFN5X6mm TI CSD16407Q5 4 R101, R103, R201, R203 Resistor, Chip, 475, 1/16W, 1%, 0402 STD STD 15 R102, R117–R120, R202, R217–R220, R503, R505, R507, R508, R512 Resistor, Chip, 10k, 1/16W, 1%, 0603 STD STD 2 R104, R204 Resistor, Chip, 45.3k, 1/16W, 1%, 0603 STD STD 4 R105, R107, R205, R207 Resistor, Chip, 10, 1/16W, 1%, 0603 STD STD 2 R514, R515 Resistor, Chip, 100, 1/16W, 1%, 0603 STD STD SLUU465 – November 2010 Submit Documentation Feedback An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated 37 Bill of Materials www.ti.com Table 17. Bill of Materials (continued) Qty RefDes Description MFR Part Number 2 R106, R206 Resistor, Chip, 6.19k, 1/16W, 1%, 0603 STD STD 3 R109, R209, R305 Resistor, Chip, 0, 1/16W, 5%, 0402 STD STD 2 R110, R210 Resistor, Chip, 2.00k, 1/16W, 1%, 0603 STD STD 2 R111, R211 Resistor, Chip, 5.90, 1/16W, 1%, 0603 STD STD 2 R402, R409 Resistor, Chip, 0, 1/16W, 1%, 0603 STD STD 2 R112, R212 Resistor, Metal Film, 0.003, 1/4W, 1%, 1206 STD STD 6 R113, R213, R308, R309, R412, R413 Resistor, Metal Film, 1, 1/4W, 5%, 1206 STD STD 2 R114, R214 Resistor, Chip, 78.7k, 1/16W, 1%, 0603 STD STD 3 R115, R116, R215 Resistor, Chip Array, 100k, 62.5mW, 5%, 612 Yageo TC164-JR-07100KL 4 R121, R122, R221, R222 Resistor, Chip, 1.00k, 1/16W, 1%, 0603 STD STD 2 R123, R223 Resistor, Chip, 1, 1/16W, 5%, 0603 STD STD 7 R216, R401, R407, R417, R421, R504, R513 Resistor, Chip, 100k, 1/16W, 1%, 0603 STD STD 8 R301, R302, R303, R304, R414, R415, R419, R423 Resistor, Chip, 10.0k, 1/16W, 1%, 0402 STD STD 2 R306, R307 Resistor, Chip, 2.05, 1/16W, 5%, 0603 STD STD 2 R310, R311 Resistor, Chip, 3.48k, 1/16W, 1%, 0402 STD STD 1 R312 Resistor, Chip, 5.11, 1/16W, 5%, 0402 STD STD 1 R403 Resistor, Chip, 102k, 1/16W, 1%, 0603 STD STD 2 R404, R406 Resistor, Chip, 75.0k, 1/16W, 1%, 0603 STD STD 1 R405 Resistor, Chip, 28.7k, 1/16W, 1%, 0603 STD STD 1 R416 Resistor, Chip, 6.81k, 1/16W, 1%, 0603 STD STD 2 R408, R411 Resistor, Chip, 3.48k, 1/16W, 1%, 0603 STD STD 1 R410 Resistor, Chip, 3.3, 1/16W, 5%, 0603 STD STD 2 R418, R422 Resistor, Chip, 7.87k, 1/16W, 1%, 0603 STD STD 1 R420 Resistor, Chip, 2.49k, 1/16W, 1%, 0603 STD STD 1 R501 Resistor, Chip, 68.1, 1/16W, 1%, 0603 STD STD 1 R502 Resistor, Chip, 5.62k, 1/16W, 1%, 0603 STD STD 2 R509, R510 Resistor, Chip, 330, 1/16W, 1%, 0603 STD STD 1 R511 Resistor, Chip, 8.06k, 1/16W, 1%, 0603 STD STD 2 R516, R521 Resistor, Chip, 0.001, 2W, 1%, 2512 STD STD 4 R517–R520 Resistor, Chip, 0.100, 2W, 1%, 2512 STD STD 2 RT101, RT210 NTC Thermistor, 150k, 0603, 5% Panasonic-ECG ERTJ1VV154J 2 U101, U210 IC, Single phase, D-CAP Synchronous Buck Controller, QFN-32 TI TPS59610RHB 1 U301 IC, Dual Synchronous PWM Controller, QFN-32 TI TPS51120RHB 1 U401 IC, Dual Synchronous Step down Controller, QFN-24 TI TPS59124RGE 2 U402, U403 IC, 1.5A LDO Regulator with soft start, SON-10 TI TPS74801DRC 1 U404 IC, High performance DDRI&II 3A LDO &buffered reference, MSOP-Power PAD TI TPS51100DGQ 1 U501 IC, 4.5-18V Input, 3A Step down Regulator with integrated Switcher, TI QFN-16 TPS54326RGT 1 U502 IC, Timer, Lower power CMOS, SO-8 TI TLC555CD 1 U503 IC, Dual 4A high speed low side MOSFET driver, SO-8 TI UCC37324DR 1 U504 IC, Quadruple 2 Input positive And Gates, SO-14 TI SN74HC08D 38 An 8-V to 14-V Vin 2010 Atom™ E6xx— Tunnel Creek Power System © 2010, Texas Instruments Incorporated SLUU465 – November 2010 Submit Documentation Feedback Evaluation Board/Kit Important Notice Texas Instruments (TI) provides the enclosed product(s) under the following conditions: This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR EVALUATION PURPOSES ONLY and is not considered by TI to be a finished end-product fit for general consumer use. Persons handling the product(s) must have electronics training and observe good engineering practice standards. As such, the goods being provided are not intended to be complete in terms of required design-, marketing-, and/or manufacturing-related protective considerations, including product safety and environmental measures typically found in end products that incorporate such semiconductor components or circuit boards. This evaluation board/kit does not fall within the scope of the European Union directives regarding electromagnetic compatibility, restricted substances (RoHS), recycling (WEEE), FCC, CE or UL, and therefore may not meet the technical requirements of these directives or other related directives. Should this evaluation board/kit not meet the specifications indicated in the User’s Guide, the board/kit may be returned within 30 days from the date of delivery for a full refund. THE FOREGOING WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY SELLER TO BUYER AND IS IN LIEU OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE. The user assumes all responsibility and liability for proper and safe handling of the goods. Further, the user indemnifies TI from all claims arising from the handling or use of the goods. Due to the open construction of the product, it is the user’s responsibility to take any and all appropriate precautions with regard to electrostatic discharge. EXCEPT TO THE EXTENT OF THE INDEMNITY SET FORTH ABOVE, NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR ANY INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES. TI currently deals with a variety of customers for products, and therefore our arrangement with the user is not exclusive. TI assumes no liability for applications assistance, customer product design, software performance, or infringement of patents or services described herein. Please read the User’s Guide and, specifically, the Warnings and Restrictions notice in the User’s Guide prior to handling the product. This notice contains important safety information about temperatures and voltages. For additional information on TI’s environmental and/or safety programs, please contact the TI application engineer or visit www.ti.com/esh. No license is granted under any patent right or other intellectual property right of TI covering or relating to any machine, process, or combination in which such TI products or services might be or are used. FCC Warning This evaluation board/kit is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION, OR EVALUATION PURPOSES ONLY and is not considered by TI to be a finished end-product fit for general consumer use. It generates, uses, and can radiate radio frequency energy and has not been tested for compliance with the limits of computing devices pursuant to part 15 of FCC rules, which are designed to provide reasonable protection against radio frequency interference. Operation of this equipment in other environments may cause interference with radio communications, in which case the user at his own expense will be required to take whatever measures may be required to correct this interference. EVM Warnings and Restrictions It is important to operate this EVM within the input voltage range of 8 V to 14 V and the output voltage range of 0.9 V to 5 V . Exceeding the specified input range may cause unexpected operation and/or irreversible damage to the EVM. If there are questions concerning the input range, please contact a TI field representative prior to connecting the input power. Applying loads outside of the specified output range may result in unintended operation and/or possible permanent damage to the EVM. Please consult the EVM User's Guide prior to connecting any load to the EVM output. If there is uncertainty as to the load specification, please contact a TI field representative. During normal operation, some circuit components may have case temperatures greater than 60° C. The EVM is designed to operate properly with certain components above 60° C as long as the input and output ranges are maintained. These components include but are not limited to linear regulators, switching transistors, pass transistors, and current sense resistors. These types of devices can be identified using the EVM schematic located in the EVM User's Guide. When placing measurement probes near these devices during operation, please be aware that these devices may be very warm to the touch. Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265 Copyright © 2010, Texas Instruments Incorporated EVALUATION BOARD/KIT/MODULE (EVM) ADDITIONAL TERMS Texas Instruments (TI) provides the enclosed Evaluation Board/Kit/Module (EVM) under the following conditions: The user assumes all responsibility and liability for proper and safe handling of the goods. Further, the user indemnifies TI from all claims arising from the handling or use of the goods. Should this evaluation board/kit not meet the specifications indicated in the User’s Guide, the board/kit may be returned within 30 days from the date of delivery for a full refund. THE FOREGOING LIMITED WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY SELLER TO BUYER AND IS IN LIEU OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE. EXCEPT TO THE EXTENT OF THE INDEMNITY SET FORTH ABOVE, NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR ANY INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES. Please read the User's Guide and, specifically, the Warnings and Restrictions notice in the User's Guide prior to handling the product. This notice contains important safety information about temperatures and voltages. For additional information on TI's environmental and/or safety programs, please visit www.ti.com/esh or contact TI. No license is granted under any patent right or other intellectual property right of TI covering or relating to any machine, process, or combination in which such TI products or services might be or are used. TI currently deals with a variety of customers for products, and therefore our arrangement with the user is not exclusive. TI assumes no liability for applications assistance, customer product design, software performance, or infringement of patents or services described herein. REGULATORY COMPLIANCE INFORMATION As noted in the EVM User’s Guide and/or EVM itself, this EVM and/or accompanying hardware may or may not be subject to the Federal Communications Commission (FCC) and Industry Canada (IC) rules. For EVMs not subject to the above rules, this evaluation board/kit/module is intended for use for ENGINEERING DEVELOPMENT, DEMONSTRATION OR EVALUATION PURPOSES ONLY and is not considered by TI to be a finished end product fit for general consumer use. It generates, uses, and can radiate radio frequency energy and has not been tested for compliance with the limits of computing devices pursuant to part 15 of FCC or ICES-003 rules, which are designed to provide reasonable protection against radio frequency interference. Operation of the equipment may cause interference with radio communications, in which case the user at his own expense will be required to take whatever measures may be required to correct this interference. General Statement for EVMs including a radio User Power/Frequency Use Obligations: This radio is intended for development/professional use only in legally allocated frequency and power limits. Any use of radio frequencies and/or power availability of this EVM and its development application(s) must comply with local laws governing radio spectrum allocation and power limits for this evaluation module. It is the user’s sole responsibility to only operate this radio in legally acceptable frequency space and within legally mandated power limitations. Any exceptions to this are strictly prohibited and unauthorized by Texas Instruments unless user has obtained appropriate experimental/development licenses from local regulatory authorities, which is responsibility of user including its acceptable authorization. For EVMs annotated as FCC – FEDERAL COMMUNICATIONS COMMISSION Part 15 Compliant Caution This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. Changes or modifications not expressly approved by the party responsible for compliance could void the user's authority to operate the equipment. FCC Interference Statement for Class A EVM devices This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. FCC Interference Statement for Class B EVM devices This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures: • Reorient or relocate the receiving antenna. • Increase the separation between the equipment and receiver. • Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. • Consult the dealer or an experienced radio/TV technician for help. For EVMs annotated as IC – INDUSTRY CANADA Compliant This Class A or B digital apparatus complies with Canadian ICES-003. Changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. Concerning EVMs including radio transmitters This device complies with Industry Canada licence-exempt RSS standard(s). Operation is subject to the following two conditions: (1) this device may not cause interference, and (2) this device must accept any interference, including interference that may cause undesired operation of the device. Concerning EVMs including detachable antennas Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type and maximum (or lesser) gain approved for the transmitter by Industry Canada. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that necessary for successful communication. This radio transmitter has been approved by Industry Canada to operate with the antenna types listed in the user guide with the maximum permissible gain and required antenna impedance for each antenna type indicated. Antenna types not included in this list, having a gain greater than the maximum gain indicated for that type, are strictly prohibited for use with this device. Cet appareil numérique de la classe A ou B est conforme à la norme NMB-003 du Canada. Les changements ou les modifications pas expressément approuvés par la partie responsable de la conformité ont pu vider l’autorité de l'utilisateur pour actionner l'équipement. Concernant les EVMs avec appareils radio Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio exempts de licence. L'exploitation est autorisée aux deux conditions suivantes : (1) l'appareil ne doit pas produire de brouillage, et (2) l'utilisateur de l'appareil doit accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible d'en compromettre le fonctionnement. Concernant les EVMs avec antennes détachables Conformément à la réglementation d'Industrie Canada, le présent émetteur radio peut fonctionner avec une antenne d'un type et d'un gain maximal (ou inférieur) approuvé pour l'émetteur par Industrie Canada. Dans le but de réduire les risques de brouillage radioélectrique à l'intention des autres utilisateurs, il faut choisir le type d'antenne et son gain de sorte que la puissance isotrope rayonnée équivalente (p.i.r.e.) ne dépasse pas l'intensité nécessaire à l'établissement d'une communication satisfaisante. Le présent émetteur radio a été approuvé par Industrie Canada pour fonctionner avec les types d'antenne énumérés dans le manuel d’usage et ayant un gain admissible maximal et l'impédance requise pour chaque type d'antenne. Les types d'antenne non inclus dans cette liste, ou dont le gain est supérieur au gain maximal indiqué, sont strictement interdits pour l'exploitation de l'émetteur. SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER 【Important Notice for Users of this Product in Japan】 】 This development kit is NOT certified as Confirming to Technical Regulations of Radio Law of Japan If you use this product in Japan, you are required by Radio Law of Japan to follow the instructions below with respect to this product: 1. 2. 3. Use this product in a shielded room or any other test facility as defined in the notification #173 issued by Ministry of Internal Affairs and Communications on March 28, 2006, based on Sub-section 1.1 of Article 6 of the Ministry’s Rule for Enforcement of Radio Law of Japan, Use this product only after you obtained the license of Test Radio Station as provided in Radio Law of Japan with respect to this product, or Use of this product only after you obtained the Technical Regulations Conformity Certification as provided in Radio Law of Japan with respect to this product. Also, please do not transfer this product, unless you give the same notice above to the transferee. Please note that if you could not follow the instructions above, you will be subject to penalties of Radio Law of Japan. Texas Instruments Japan Limited (address) 24-1, Nishi-Shinjuku 6 chome, Shinjuku-ku, Tokyo, Japan http://www.tij.co.jp 【ご使用にあたっての注】 本開発キットは技術基準適合証明を受けておりません。 本製品のご使用に際しては、電波法遵守のため、以下のいずれかの措置を取っていただく必要がありますのでご注意ください。 1. 2. 3. 電波法施行規則第6条第1項第1号に基づく平成18年3月28日総務省告示第173号で定められた電波暗室等の試験設備でご使用いただく。 実験局の免許を取得後ご使用いただく。 技術基準適合証明を取得後ご使用いただく。 なお、本製品は、上記の「ご使用にあたっての注意」を譲渡先、移転先に通知しない限り、譲渡、移転できないものとします。 　　　上記を遵守頂けない場合は、電波法の罰則が適用される可能性があることをご留意ください。 日本テキサス・インスツルメンツ株式会社 東京都新宿区西新宿６丁目２４番１号 西新宿三井ビル http://www.tij.co.jp SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER SPACER EVALUATION BOARD/KIT/MODULE (EVM) WARNINGS, RESTRICTIONS AND DISCLAIMERS For Feasibility Evaluation Only, in Laboratory/Development Environments. Unless otherwise indicated, this EVM is not a finished electrical equipment and not intended for consumer use. It is intended solely for use for preliminary feasibility evaluation in laboratory/development environments by technically qualified electronics experts who are familiar with the dangers and application risks associated with handling electrical mechanical components, systems and subsystems. It should not be used as all or part of a finished end product. Your Sole Responsibility and Risk. You acknowledge, represent and agree that: 1. 2. 3. 4. You have unique knowledge concerning Federal, State and local regulatory requirements (including but not limited to Food and Drug Administration regulations, if applicable) which relate to your products and which relate to your use (and/or that of your employees, affiliates, contractors or designees) of the EVM for evaluation, testing and other purposes. You have full and exclusive responsibility to assure the safety and compliance of your products with all such laws and other applicable regulatory requirements, and also to assure the safety of any activities to be conducted by you and/or your employees, affiliates, contractors or designees, using the EVM. Further, you are responsible to assure that any interfaces (electronic and/or mechanical) between the EVM and any human body are designed with suitable isolation and means to safely limit accessible leakage currents to minimize the risk of electrical shock hazard. You will employ reasonable safeguards to ensure that your use of the EVM will not result in any property damage, injury or death, even if the EVM should fail to perform as described or expected. You will take care of proper disposal and recycling of the EVM’s electronic components and packing materials. Certain Instructions. It is important to operate this EVM within TI’s recommended specifications and environmental considerations per the user guidelines. Exceeding the specified EVM ratings (including but not limited to input and output voltage, current, power, and environmental ranges) may cause property damage, personal injury or death. If there are questions concerning these ratings please contact a TI field representative prior to connecting interface electronics including input power and intended loads. Any loads applied outside of the specified output range may result in unintended and/or inaccurate operation and/or possible permanent damage to the EVM and/or interface electronics. Please consult the EVM User's Guide prior to connecting any load to the EVM output. If there is uncertainty as to the load specification, please contact a TI field representative. During normal operation, some circuit components may have case temperatures greater than 60°C as long as the input and output are maintained at a normal ambient operating temperature. These components include but are not limited to linear regulators, switching transistors, pass transistors, and current sense resistors which can be identified using the EVM schematic located in the EVM User's Guide. When placing measurement probes near these devices during normal operation, please be aware that these devices may be very warm to the touch. As with all electronic evaluation tools, only qualified personnel knowledgeable in electronic measurement and diagnostics normally found in development environments should use these EVMs. Agreement to Defend, Indemnify and Hold Harmless. You agree to defend, indemnify and hold TI, its licensors and their representatives harmless from and against any and all claims, damages, losses, expenses, costs and liabilities (collectively, "Claims") arising out of or in connection with any use of the EVM that is not in accordance with the terms of the agreement. This obligation shall apply whether Claims arise under law of tort or contract or any other legal theory, and even if the EVM fails to perform as described or expected. Safety-Critical or Life-Critical Applications. If you intend to evaluate the components for possible use in safety critical applications (such as life support) where a failure of the TI product would reasonably be expected to cause severe personal injury or death, such as devices which are classified as FDA Class III or similar classification, then you must specifically notify TI of such intent and enter into a separate Assurance and Indemnity Agreement. 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