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| 19-2793; Rev 0a; 4/03 MAX2045/MAX2046/MAX2047 Evaluation Kits General Description The MAX2045/MAX2046/MAX2047 evaluation kits (EV kits) simplify evaluation of the MAX2045/MAX2046/ MAX2047 vector multipliers. Each kit enables testing of the device's RF performance and requires no additional support circuitry. The EV kit input and output use SMA connectors and baluns (for single-ended-to-differential conversions) to facilitate the connection to RF test equipment. Each EV kit is assembled with either the MAX2045, MAX2046, or MAX2047 and incorporates all matching components optimized for the corresponding band of frequency operation. Features o Easy Evaluation of the MAX2045/MAX2046/ MAX2047 o +4.75V to +5.25V Single-Supply Operation o Include RF Input and Output Matching 2040MHz to 2240MHz (MAX2045) 1740MHz to 2060MHz (MAX2046) 790MHz to 1005MHz (MAX2047) o Configurable for Current-Control Mode and Single-Ended and Differential Voltage-Control Mode o Fully Assembled and Tested Evaluate: MAX2045/MAX2046/MAX2047 Component Suppliers SUPPLIER Murata Toko PHONE 800-831-9172 800-745-8656 FAX 814-238-0490 -- PART MAX2045EVKIT MAX2046EVKIT MAX2047EVKIT Ordering Information TEMP RANGE -40C to +85C -40C to +85C -40C to +85C IC PACKAGE 32 QFN-EP* 32 QFN-EP* 32 QFN-EP* Note: When contacting these suppliers, please indicate that you are using the MAX2045/MAX2046/MAX2047. *EP = Exposed paddle. MAX2045 Component List DESIGNATION C1, C4-C16 QTY 14 DESCRIPTION 22pF 5%, 50V C0G ceramic capacitors (0402) Murata GRP1555C1H220J 220pF 10%, 50V X7R ceramic capacitors (0402) Murata GRP155R71H221K 0.01F 10%, 25V X7R ceramic capacitor (0402) Murata GRP155R71E103K PC board edge-mount SMA RF connectors (flat-tab launch) EFJohnson 142-0741-856 Header, 10 x 2, 0.100in spacing Molex 10-89-1201 DESIGNATION L1 QTY 1 DESCRIPTION 1.5pF 0.1pF, 50V C0G ceramic capacitor (0402) Murata GRP1555C1H1R5B 8.2nH 5% chip inductor (0402) Toko LL1005-FH8N2J 280 1% resistor (0402) Any Not installed 0 resistors (0402) Any 1:1 balun (50:50) Murata LDB15C500A1900 4:1 balun (200:50) Murata LDB15C201A1900 MAX2045ETJ-T (32-pin QFN) L2 R1 R2, R4, R6 R3, R5 T1 T2 U1 1 1 0 2 1 1 1 C2, C3 2 C17 1 J1, J2 2 J3 1 ________________________________________________________________ Maxim Integrated Products 1 For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at 1-888-629-4642, or visit Maxim's website at www.maxim-ic.com. MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 MAX2046 Component List DESIGNATION C1 QTY 1 DESCRIPTION 3.9pF 0.1pF, 50V C0G ceramic capacitor (0402) Murata GRP1555C1H3R9B 220pF 10%, 50V X7R ceramic capacitors (0402) Murata GRP155R71H221K 22pF 5%, 50V C0G ceramic capacitors (0402) Murata GRP1555C1H220J 6.2pF 0.25pF, 50V C0G ceramic capacitor (0402) Murata GRP1555C1H6R2C 0.01F 10%, 25V X7R ceramic capacitor (0402) Murata GRP155R71E103K PC board edge-mount SMA RF connectors (flat-tab launch) EFJohnson 142-0741-856 Header 10 x 2, 0.100in spacing Molex 10-89-1201 1.5pF 0.1pF, 50V C0G ceramic capacitor (0402) Murata GRP1555C1H1R5B 12nH 5% chip inductor (0402) Toko LL1005-FH12NJ 280 1% resistor (0402) Any Not installed 0 resistors (0402) Any 1:1 balun (50:50) Murata LDB15C500A1900 4:1 balun (200:50) Murata LDB15C201A1900 MAX2046ETJ-T (32-pin QFN) MAX2047 Component List DESIGNATION C1-C16 QTY 16 DESCRIPTION 47pF 5%, 50V C0G ceramic capacitors (0402) Murata GRP1555C1H470J 0.01F 10%, 25V X7R ceramic capacitor (0402) Murata GRP155R71E103K PC board edge-mount SMA RF connectors (flat-tab launch) EFJohnson 142-0741-856 Header 10 x 2, 0.100in spacing Molex 10-89-1201 15nH 5% chip inductor (0402) Toko LL1005-FH15NJ 39nH 5% chip inductor (0402) Toko LL1005-FH39NJ 280 1% resistor (0402) Any Not installed 0 resistors (0402) Any 1:1 balun (50:50) Murata LDB20C500A900 4:1 balun (200:50) Murata LDB20C201A900 MAX2047ETJ-T (32-pin QFN) C2, C3 2 C17 1 C4-C13, C15, C16 12 J1, J2 2 C14 1 J3 L1 1 1 1 1 0 2 1 1 1 C17 1 L2 R1 R2, R4, R6 R3, R5 T1 T2 U1 J1, J2 2 J3 1 L1 1 L2 R1 R2, R4, R6 R3, R5 T1 T2 U1 1 1 0 2 1 1 1 Quick Start The MAX2045/MAX2046/MAX2047 EV kits are fully assembled and factory tested. Follow the instructions in the Connections and Setup section for proper device evaluation. The EV kits come configured for single-ended, voltage-control operation. For differential voltage- or current-mode operation, see the Detailed Description section. Test Equipment Required Table 1 lists the required test equipment to verify the MAX2045/MAX2046/MAX2047 operation. It is intended as a guide only, and some substitutions are possible. Connections and Setup This section provides a step-by-step guide to operating the EV kits and testing the devices' functions. Do not turn on DC power or RF signal generators until all connections are made. 2 _______________________________________________________________________________________ MAX2045/MAX2046/MAX2047 Evaluation Kits Table 1. Required Test Equipment EQUIPMENT Power supply Power supplies Current sources (optional) Low-noise RF signal generators Network analyzer Ammeter/voltmeters 50 SMA cables QTY 1 2 2 2 1 2 2 DESCRIPTION Capable of delivering up to 250mA at 4.75V to 5.25V Capable of swinging from 0 to +5.5V Capable of delivering 5mA of current HP 8648B or equivalent HP 8753ES or equivalent -- -- 4) Configure the network analyzer to measure S21. The analyzer should read approximately 6.2dB gain at fIN = 2140MHz (MAX2045), 6.6dB gain at f IN = 1900MHz (MAX2046), and 8.1dB gain at f IN = 915MHz (MAX2047). 5) Changing the current source value changes the magnitude of the gain. To adjust the phase, use separate current sources on the II1 and IQ1 terminals. Evaluate: MAX2045/MAX2046/MAX2047 Detailed Description The EV kits come with all necessary components for easy testing. For each kit, make sure all ground pins on the 20-lead header are connected to ground. The REFOUT voltage can be monitored from pins 17 and 18 on the 20-lead header by installing a 0 resistor for R6. To operate the device in differential voltage-control mode, remove R5 and R3, and install 0 resistors for R2 and R4. Figure 1 shows the connections on the 20pin header corresponding to the voltage- and currentcontrol inputs. Using this configuration, an external DC source can also be applied to VI2 and VQ2 for singleended operation using an external regulated voltage. For current-mode operation, leave the VI and VQ (header pins 1, 2, 5, and 6) open, and remove R3 and R5. Testing the Supply Current 1) If available, set the current limit of the power supply to 250mA. Do not turn on the supply. Connect the DC supply set to 5V, through an ammeter, to the VCC and GND terminals on the EV kit. Use a voltmeter to verify that the voltage is at VCC = 5V. 2) Turn on the DC supply; the supply current should read approximately 160mA. Testing the Gain (Single-Ended Voltage Mode) 1) Connect a DC supply set to +3.2V to the VI1 and VQ1 terminals (Figure 1). 2) Using a calibrated network analyzer, connect port 1 to the RF_IN terminal (SMA J1) and port 2 to the RF_OUT terminal (SMA J2). 3) Configure the network analyzer to measure S21. The analyzer should read approximately 7dB gain at fIN = 2140MHz (MAX2045), 7.4dB gain at f IN = 1900MHz (MAX2046), and 8.4dB gain at f IN = 915MHz (MAX2047). 4) Changing the DC supply on the VI1 and VQ1 terminals changes the magnitude of the gain. To adjust the phase, use separate DC supplies on the VI1 and VQ1 terminals. Testing the Gain (Current Mode) 1) Configure the evaluation kits for current mode (see the Detailed Description section). 2) Connect a current source set to 4mA to the II1 and IQ1 terminals. Leave II2, IQ2, and all voltage-control pins open (Figure 1). 3) Using a calibrated network analyzer, connect port 1 to the RF_IN terminal (SMA J1) and port 2 to the RF_OUT terminal (SMA J2). Bias Resistor The bias resistor value (280) was optimized during characterization at the factory. This value should not be adjusted. If the 280 (1%) resistor is not readily available, substitute a standard 280 (5%) resistor. On-Chip Reference Voltage An on-chip, 2.5V reference voltage is provided for single-ended control mode. REFOUT is connected, through R3 and R5, to VI2 and VQ2 to provide a stable reference voltage. The equivalent output resistance of the REFOUT pin is approximately 80. REFOUT is capable of sourcing 1mA of current with <10mV drop in voltage. Capacitors Ceramic capacitors C16 and C17 provide bypass on the supply. Place C16 as close to the part as possible for high-frequency bypassing. C4-C11 are bypass capacitors for the control inputs. C1 and C14 are DCblocking capacitors for the on-board baluns. DC-blocking capacitors prevent DC current from flowing into the transformers and can be used as part of the matching circuit. Capacitors C13 and C15 are used to provide an RF ground for transformer T2. Capacitor C12 is used to bypass the 2.5V reference in case the reference is used. As the differential RF outputs are relatively high _______________________________________________________________________________________ 3 MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 impedance, they are more susceptible to component parasitics. It is often good practice to relieve the ground plane directly underneath large components to reduce associated shunt-C parasitics. er and of the same length to ensure signal balance. The PC board layout should provide a large ground pad under the device for proper RF grounding and thermal performance. This pad should be connected to the ground plane of the board by using multiple vias. To minimize inductance, route the ground pins of the device to the large ground pad. Solder the exposed pad on the bottom of the device package to the PC board exposed pad (refer to the MAX2045/MAX2046/ MAX2047 data sheet). The MAX2045/MAX2046/MAX2047 EV kits can be used as a reference for board layout. Gerber files are available upon request at www.maxim-ic.com. Layout The EV kit's PC board can serve as a guide for laying out a board using the MAX2045/MAX2046/MAX2047. Keep RF signal lines as short as possible to minimize losses and radiation. Always use controlled-impedance lines on all high-frequency inputs and outputs and use low-inductance connections to ground on all GND pins. At all differential ports, keep the differential lines togethJ1 RF_IN C1 L1 T1 C2 C3 RFIN2 RFIN1 GND GND GND GND GND GND 26 25 31 30 29 28 J3 1 2 R2 OPEN 3 C5 C4 VI2 2 CONTROL AMPLIFIER I 90 PHASE SHIFTER VI1 1 24 32 27 GND GND 23 RBIAS GND 21 U1 VQ1 R4 OPEN C6 VQ2 C7 II1 C8 5 4 3 22 MAX2045 MAX2046 MAX2047 CONTROL AMPLIFIER Q VECTOR MULTIPLIER R1 280 GND 20 GND II2 C9 IQ1 C10 IQ2 C11 6 2.5V REFERENCE OUTPUT STAGE 19 VCC VCC C16 17 VCC C17 7 18 8 10 11 12 13 14 VREF R5 R6 OPEN 0 R3 0 C12 VCC RF_OUT REFOUT RFOUT1 RFOUT2 GND GND 15 GND 5V 19 20 J2 C14 L2 C15 C13 GND GND T2 Figure 1. MAX2045/MAX2046/MAX2047 EV Kit Schematic 4 _______________________________________________________________________________________ 16 9 NOTE: PLEASE SEE THE PART-SPECIFIC COMPONENT LIST FOR COMPONENT VALUES. MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 1.0" Figure 2. MAX2045 EV Kit Component Placement Guide--Top Silkscreen 1.0" Figure 3. MAX2045 EV Kit Component Placement Guide-- Bottom Silkscreen 1.0" Figure 4. MAX2045 EV Kit PC Board Layout--Primary Component Side 1.0" Figure 5. MAX2045 EV Kit PC Board Layout --Ground Layer (Layer 2) 5 _______________________________________________________________________________________ MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 1.0" Figure 6. MAX2045 EV Kit PC Board Layout--Route Layer (Layer 3) 1.0" Figure 7. MAX2045 EV Kit PC Board Layout--Secondary Side 1.0" Figure 8. MAX2045 EV Kit PC Board Layout--Top Solder Mask 1.0" Figure 9. MAX2045 EV Kit PC Board Layout--Bottom Solder Mask 6 _______________________________________________________________________________________ MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 1.0" Figure 10. MAX2046 EV Kit Component Placement Guide-- Top Silkscreen 1.0" Figure 11. MAX2046 EV Kit Component Placement Guide-- Bottom Silkscreen 1.0" Figure 12. MAX2046 EV Kit PC Board Layout--Primary Component Side 1.0" Figure 13. MAX2046 EV Kit PC Board Layout--Ground Layer (Layer 2) 7 _______________________________________________________________________________________ MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 1.0" Figure 14. MAX2046 EV Kit PC Board Layout--Route Layer (Layer 3) 1.0" Figure 15. MAX2046 EV Kit PC Board Layout--Secondary Side 1.0" Figure 16. MAX2046 EV Kit PC Board Layout--Top Solder Mask 8 1.0" Figure 17. MAX2046 EV Kit PC Board Layout--Bottom Solder Mask _______________________________________________________________________________________ MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 1.0" Figure 18. MAX2047 EV Kit Component Placement Guide-- Top Silkscreen 1.0" Figure 19. MAX2047 EV Kit Component Placement Guide-- Bottom Silkscreen 1.0" Figure 20. MAX2047 EV Kit PC Board Layout--Primary Component Side 1.0" Figure 21. MAX2047 EV Kit PC Board Layout--Ground Layer (Layer 2) 9 _______________________________________________________________________________________ MAX2045/MAX2046/MAX2047 Evaluation Kits Evaluate: MAX2045/MAX2046/MAX2047 1.0" Figure 22. MAX2047 EV Kit PC Board Layout--Route Layer (Layer 3) 1.0" Figure 23. MAX2047 EV Kit PC Board Layout--Secondary Side 1.0" Figure 24. MAX2047 EV Kit PC Board Layout--Top Solder Mask 1.0" Figure 25. MAX2047 EV Kit PC Board Layout--Bottom Solder Mask Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. 10 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 (c) 2003 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products. |
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