19-1017; Rev 0; 10/07 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch Features The MAX2029 high-linearity passive upconverter or downconverter mixer is designed to provide +36.5dBm IIP3, 6.7dB NF, and 6.5dB conversion loss for an 815MHz to 1000MHz RF frequency range to support GSM/cellular base-station transmitter or receiver applications. With a 570MHz to 900MHz LO frequency range, this particular mixer is ideal for low-side LO injection architectures. For a pin-to-pin-compatible mixer meant for high-side LO injection, refer to the MAX2031 data sheet. 815MHz to 1000MHz RF Frequency Range 570MHz to 900MHz LO Frequency Range 960MHz to 1180MHz LO Frequency Range (Refer to the MAX2031 Data Sheet) DC to 250MHz IF Frequency Range 6dB/6.5dB (Upconverter/Downconverter) Conversion Loss 36.5dBm/39dBm (Downconverter/Upconverter) Input IP3 +25dBm/+27dBm (Upconverter/Downconverter) Input 1dB Compression Point 6.7dB Noise Figure Integrated LO Buffer Integrated RF and LO Baluns Low -3dBm to +3dBm LO Drive Built-In SPDT LO Switch with 53dB Isolation and 50ns Switching Time Pin Compatible with the MAX2039/MAX2041 1700MHz to 2200MHz Mixers External Current-Setting Resistor Provides Option for Operating Mixer in Reduced-Power/ReducedPerformance Mode Lead-Free Package Available In addition to offering excellent linearity and noise performance, the MAX2029 also yields a high level of component integration. This device includes a double-balanced passive mixer core, a dual-input LO selectable switch, and an LO buffer. On-chip baluns are also integrated to allow for a single-ended RF input for downconversion (or RF output for upconversion), and single-ended LO inputs. The MAX2029 requires a nominal LO drive of 0dBm, and supply current is guaranteed to be below 100mA. The MAX2029 is pin compatible with the MAX2039, MAX2041, MAX2042, MAX2044 series of 1700MHz to 2200MHz, 2000MHz to 3000MHz, and 3200MHz to 3900MHz mixers, making this family of passive upconverters and downconverters ideal for applications where a common printed-circuit board (PCB) layout is used for multiple frequency bands. The MAX2029 is available in a compact 20-pin thin QFN package (5mm x 5mm) with an exposed paddle. Electrical performance is guaranteed over the extended -40C to +85C temperature range. Ordering Information PART TEMP RANGE PIN-PACKAGE -40C to +85C 20 Thin QFN-EP* T2055-3 (5mm x 5mm) MAX2029ETP+/+T -40C to +85C 20 Thin QFN-EP* T2055-3 (5mm x 5mm) MAX2029ETP/-T Applications T = Tape and reel. *EP = Exposed paddle. +Denotes lead-free package. VCC RF GND GND TOP VIEW IF- Pin Configuration/ Functional Diagram IF+ Predistortion Receivers Microwave and Fixed Broadband Wireless Access Wireless Local Loop Private Mobile Radios Military Systems Microwave Links Digital and SpreadSpectrum Communication Systems GND Cellular Band WCDMA and cdma2000 (R) Base Stations GSM 850/GSM 900 2G and 2.5G EDGE Base Stations TDMA and Integrated Digital Enhanced Network (iDEN(R)) Base Stations PHS/PAS Base Stations WiMAX Base Stations and Customer Premise Equipment PKG CODE 20 19 18 17 16 1 MAX2029 2 15 LO2 14 VCC TAP 3 13 GND GND 4 12 GND 11 LO1 E.P. 6 7 8 9 10 LOBIAS VCC LOSEL GND cdma2000 is a registered trademark of Telecommunications Industry Association. iDEN is a registered trademark of Motorola, Inc. 5 VCC GND ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim's website at www.maxim-ic.com. 1 MAX2029 General Description MAX2029 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch ABSOLUTE MAXIMUM RATINGS VCC to GND ...........................................................-0.3V to +5.5V RF (RF is DC shorted to GND through a balun)..................50mA LO1, LO2 to GND ..................................................-0.3V to +0.3V IF+, IF- to GND ...........................................-0.3V to (VCC + 0.3V) TAP to GND ...........................................................-0.3V to +1.4V LOSEL to GND ...........................................-0.3V to (VCC + 0.3V) LOBIAS to GND..........................................-0.3V to (VCC + 0.3V) RF, LO1, LO2 Input Power* ............................................+20dBm Continuous Power Dissipation (TC = +85C) (Note A) 20-Pin Thin QFN-EP................................................................5W JA (Note B)....................................................................+38C/W JC .................................................................................+13C/W Operating Temperature Range (Note C) ....TC = -40C to +85C Maximum Junction Temperature .....................................+150C Storage Temperature Range .............................-65C to +150C Lead Temperature (soldering, 10s) .................................+300C Note A: Based on junction temperature TJ = TC + (JC x VCC x ICC). This formula can be used when the temperature of the exposed paddle is known while the device is soldered down to a PCB. See the Applications Information section for details. The junction temperature must not exceed +150C. Note B: Junction temperature TJ = TA + (JA x VCC x ICC). This formula can be used when the ambient temperature of the EV kit PCB is known. The junction temperature must not exceed +150C. See the Applications Information section for details. Note C: TC is the temperature on the exposed paddle of the package. TA is the ambient temperature of the device and PCB. *Maximum reliable continuous input power applied to the RF, LO, and IF ports of this device is +15dBm from a 50 source. Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. DC ELECTRICAL CHARACTERISTICS (Typical Application Circuit, VCC = +4.75V to +5.25V, no RF signals applied, TC = -40C to +85C. IF+ and IF- are DC grounded through an IF balun. Typical values are at VCC = +5V, TC = +25C, unless otherwise noted.) PARAMETER SYMBOL Supply Voltage VCC Supply Current ICC LOSEL Input Logic-Low VIL LOSEL Input Logic-High Input Current CONDITIONS VIH MIN TYP MAX UNITS 4.75 5.00 5.25 V 85 100 mA 0.8 V 2 IIH, IIL V 0.01 A AC ELECTRICAL CHARACTERISTICS (Typical Application Circuit, C5 = 3.3pF, L1 and C4 not used, VCC = +4.75V to +5.25V, RF and LO ports are driven from 50 sources, PLO = -3dBm to +3dBm, PRF = 0dBm, fRF = 815MHz to 1000MHz, fLO = 570MHz to 900MHz, fIF = 90MHz, fLO < fRF, TC = -40C to +85C, unless otherwise noted. Typical values are at VCC = +5V, PLO = 0dBm, fRF = 920MHz, fLO = 830MHz, fIF = 90MHz, TC = +25C, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN MAX UNITS 1000 MHz 570 900 MHz DC 250 MHz (Note 2) -3 +3 dBm LO2 selected, PLO = +3dBm, TC = +25C, fRF = 920MHz to 960MHz, fLO = 830MHz to 870MHz 48 RF Frequency Range fRF (Note 2) 815 LO Frequency Range fLO (Note 2) IF Frequency Range fIF External IF transformer dependence (Note 2) LO Drive LO1-to-LO2 Isolation (Note 3) PLO LO1 selected, PLO = +3dBm, TC = +25C, fRF = 920MHz to 960MHz, fLO = 830MHz to 870MHz Maximum LO Leakage at RF Port PLO = +3dBm Maximum LO Leakage at IF Port PLO = +3dBm, fRF = 920MHz to 960MHz, fLO = 830MHz to 870MHz (Note 3) 2 TYP 53 dB 50 56 -17 -29.5 _______________________________________________________________________________________ dBm -23 dBm High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch (Typical Application Circuit, C5 = 3.3pF, L1 and C4 not used, VCC = +4.75V to +5.25V, RF and LO ports are driven from 50 sources, PLO = -3dBm to +3dBm, PRF = 0dBm, fRF = 815MHz to 1000MHz, fLO = 570MHz to 900MHz, fIF = 90MHz, fLO < fRF, TC = -40C to +85C, unless otherwise noted. Typical values are at VCC = +5V, PLO = 0dBm, fRF = 920MHz, fLO = 830MHz, fIF = 90MHz, TC = +25C, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS LO Switching Time 50% of LOSEL to IF, settled within 2 degrees Minimum RF-to-IF Isolation fRF = 920MHz to 960MHz, fLO = 830MHz to 870MHz (Note 3) MIN 38 RF Port Return Loss LO Port Return Loss IF Port Return Loss TYP MAX UNITS 50 ns 47 dB 18 dB LO1/LO2 port selected, LO2/LO1, RF, and IF terminated into 50 19 LO1/LO2 port unselected, LO2/LO1, RF, and IF terminated into 50 31 LO driven at 0dBm, RF terminated into 50 23 dB dB AC ELECTRICAL CHARACTERISTICS (DOWNCONVERTER OPERATION) (Typical Application Circuit, C5 = 3.3pF, L1 and C4 not used, VCC = +4.75V to +5.25V, RF and LO ports are driven from 50 sources, PLO = -3dBm to +3dBm, PRF = 0dBm, fRF = 815MHz to 1000MHz, fLO = 570MHz to 900MHz, fIF = 90MHz, fLO < fRF, TC = -40C to +85C, unless otherwise noted. Typical values are at VCC = +5V, PLO = 0dBm, fRF = 920MHz, fLO = 830MHz, fIF = 90MHz, TC = +25C, unless otherwise noted.) (Note 1) PARAMETER Conversion Loss SYMBOL CONDITIONS MIN GC Input Compression Point -0.28 TC = +25C to +85C 0.35 (Note 4) Input Third-Order Intercept Point IIP3 fRF1 = 920MHz, fRF2 = 921MHz, PRF = 0dBm/tone, PLO = 0dBm, TC = +25C (Note 3) Input IP3 Variation Over Temperature IIP3 Output Third-Order Intercept Point OIP3 Spurious Response at IF (Note 3) 2x2 3x3 Noise Figure NF Noise Figure Under Blocking (Note 5) 33 dB 27 dBm 36.5 dBm TC = +25C to -40C -0.6 TC = +25C to +85C 0.4 fRF1 = 920MHz, fRF2 = 921MHz, PRF = 0dBm/tone, PLO = 0dBm, TC = +25C (Note 3) 2RF - 2LO, PRF = -10dBm, fRF = 920MHz to 960MHz (fLO = 830MHz to 870MHz), TC = +25C dB 0.4 TC = +25C to -40C P1dB UNITS dB 0.2 fRF = 920MHz to 960MHz Conversion Loss Variation Over Temperature MAX 6.5 Flatness over any one of three frequency bands (fIF = 90MHz): fRF = 827MHz to 849MHz fRF = 869MHz to 894MHz fRF = 880MHz to 915MHz Conversion Loss Flatness (Note 3) TYP 26 30 62 72 3RF - 3LO, PRF = -10dBm 96 Single sideband 6.7 PBLOCKER = +8dBm 15 PBLOCKER = +12dBm 19 dB dBm dBc dB dB _______________________________________________________________________________________ 3 MAX2029 AC ELECTRICAL CHARACTERISTICS (continued) MAX2029 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch AC ELECTRICAL CHARACTERISTICS (UPCONVERTER OPERATION) (Typical Application Circuit, L1 = 4.7nH, C4 = 4.7pF, C5 not used, VCC = +4.75V to +5.25V, RF and LO ports are driven from 50 sources, PLO = -3dBm to +3dBm, PIF = 0dBm, fRF = 815MHz to 1000MHz, fLO = 570MHz to 900MHz, fIF = 90MHz, fLO < fRF, TC = -40C to +85C, unless otherwise noted. Typical values are at VCC = +5V, PLO = 0dBm, fRF = 920MHz, fLO = 830MHz, fIF = 90MHz, TC = +25C, unless otherwise noted.) (Note 1) PARAMETER Conversion Loss SYMBOL CONDITIONS MIN GC TYP MAX UNITS 6 dB Flatness over any one of four frequency bands (fIF = 90MHz): fRF = 827MHz to 849MHz fRF = 869MHz to 894MHz fRF = 880MHz to 915MHz fRF = 920MHz to 960MHz 0.3 dB TC = +25C to -40C -0.4 TC = +25C to +85C 0.3 P1dB (Note 4) 25 dBm Input Third-Order Intercept Point IIP3 fIF1 = 90MHz, fIF2 = 91MHz (results in fRF1 = 920MHz, fRF2 = 921MHz), PIF = 0dBm/tone, PLO = 0dBm, TC = +25C (Note 3) 39 dBm Input IP3 Variation Over Temperature IIP3 Conversion Loss Flatness Conversion Loss Variation Over Temperature Input Compression Point 34 TC = +25C to -40C -0.6 TC = +25C to +85C -0.6 dB dB LO 2IF Spur 71 dBc LO 3IF Spur 86 dBc -167 dBm/Hz Output Noise Floor Note 1: Note 2: Note 3: Note 4: Note 5: 4 POUT = 0dBm (Note 5) All limits include external component losses. Output measurements are taken at IF or RF port of the Typical Application Circuit. Operation outside this range is possible, but with degraded performance of some parameters. Guaranteed by design. Compression point characterized. It is advisable not to continuously operate the mixer RF/IF inputs above +15dBm. Measured with external LO source noise filtered, so its noise floor is -174dBm/Hz at 100MHz offset. This specification reflects the effects of all SNR degradations in the mixer, including the LO noise as defined in Maxim Application Note 2021. _______________________________________________________________________________________ High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch Downconverter Curves TC = -40C TC = +25C 5 7 6 PLO = -3dBm, 0dBm, +3dBm 5 4 900 950 1000 RF FREQUENCY (MHz) 900 950 1000 38 36 TC = -40C 34 PLO = -3dBm, 0dBm, +3dBm 34 950 1000 850 900 950 1000 800 8 7 6 950 1000 NOISE FIGURE vs. RF FREQUENCY PLO = -3dBm 8 7 6 900 10 MAX2029 toc08 9 NOISE FIGURE (dB) TC = +85C 850 RF FREQUENCY (MHz) NOISE FIGURE vs. RF FREQUENCY 10 MAX2029 toc07 TC = +25C VCC = 4.75V 34 RF FREQUENCY (MHz) NOISE FIGURE vs. RF FREQUENCY 9 36 30 800 RF FREQUENCY (MHz) 10 38 32 9 NOISE FIGURE (dB) 900 1000 VCC = 5.25V VCC = 5.0V 40 30 850 950 42 32 30 900 INPUT IP3 vs. RF FREQUENCY 38 36 850 RF FREQUENCY (MHz) MAX2029 toc05 40 32 800 MAX2029 toc03 800 INPUT IP3 vs. RF FREQUENCY INPUT IP3 (dBm) INPUT IP3 (dBm) TC = +85C 850 42 MAX2029 toc04 TC = +25C 40 VCC = 4.75V, 5.0V, 5.25V RF FREQUENCY (MHz) INPUT IP3 vs. RF FREQUENCY 42 6 4 800 INPUT IP3 (dBm) 850 7 5 4 800 NOISE FIGURE (dB) 8 PLO = 0dBm, +3dBm MAX2029 toc09 6 8 MAX2029 toc06 7 CONVERSION LOSS vs. RF FREQUENCY 9 MAX2029 toc02 MAX2029 toc01 TC = +85C CONVERSION LOSS (dB) CONVERSION LOSS (dB) 8 CONVERSION LOSS vs. RF FREQUENCY 9 CONVERSION LOSS (dB) CONVERSION LOSS vs. RF FREQUENCY 9 VCC = 4.75V, 5.0V, 5.25V 8 7 6 TC = -40C 5 5 800 850 900 950 RF FREQUENCY (MHz) 1000 5 800 850 900 950 RF FREQUENCY (MHz) 1000 800 850 900 950 1000 RF FREQUENCY (MHz) _______________________________________________________________________________________ 5 MAX2029 Typical Operating Characteristics (Typical Application Circuit, C5 = 3.3pF, L1 and C4 not used, VCC = +5.0V, PLO = 0dBm, PRF = 0dBm, fLO < fRF, fIF = 90MHz, unless otherwise noted.) Typical Operating Characteristics (continued) (Typical Application Circuit, C5 = 3.3pF, L1 and C4 not used, VCC = +5.0V, PLO = 0dBm, PRF = 0dBm, fLO < fRF, fIF = 90MHz, unless otherwise noted.) Downconverter Curves 55 50 65 60 PLO = +3dBm PLO = 0dBm 55 950 1000 RF FREQUENCY (MHz) 3RF - 3LO RESPONSE vs. RF FREQUENCY VCC = 5.25V 55 900 950 1000 800 850 TC = +85C 80 TC = -40C 900 950 1000 RF FREQUENCY (MHz) 3RF - 3LO RESPONSE vs. RF FREQUENCY 3RF - 3LO RESPONSE (dBc) TC = +25C 70 850 100 MAX2029 toc13 PRF = 0dBm 90 60 RF FREQUENCY (MHz) 100 VCC = 4.75V 65 45 800 PRF = 0dBm 3RF - 3LO RESPONSE vs. RF FREQUENCY 100 PRF = 0dBm 3RF - 3LO RESPONSE (dBc) 900 MAX2029 toc14 850 VCC = 5.0V 50 45 800 3RF - 3LO RESPONSE (dBc) 70 50 45 PRF = 0dBm 90 PLO = -3dBm, 0dBm, +3dBm 80 70 90 VCC = 5.25V MAX2029 toc15 60 PLO = -3dBm 2RF - 2LO RESPONSE (dBc) 65 PRF = 0dBm 70 2RF - 2LO RESPONSE (dBc) TC = -40C, +25C, +85C 2RF - 2LO RESPONSE vs. RF FREQUENCY 75 MAX2029 toc11 PRF = 0dBm 70 2RF - 2LO RESPONSE (dBc) 75 MAX2029 toc10 75 MAX2029 toc12 2RF - 2LO RESPONSE vs. RF FREQUENCY 2RF - 2LO RESPONSE vs. RF FREQUENCY VCC = 5.0V 80 70 VCC = 4.75V 60 850 900 950 1000 60 800 RF FREQUENCY (MHz) 900 950 RF FREQUENCY (MHz) 1000 900 950 1000 INPUT P1dB vs. RF FREQUENCY 31 VCC = 5.0V 29 27 VCC = 5.25V 27 VCC = 4.75V 25 23 850 850 RF FREQUENCY (MHz) 25 TC = +85C 800 800 INPUT P1dB (dBm) INPUT P1dB (dBm) TC = -40C 23 6 PLO = -3dBm, 0dBm, +3dBm 29 25 1000 INPUT P1dB vs. RF FREQUENCY 29 27 950 31 MAX2029 toc16 TC = +25C 900 RF FREQUENCY (MHz) INPUT P1dB vs. RF FREQUENCY 31 850 MAX2029 toc17 800 MAX2029 toc18 60 INPUT P1dB (dBm) MAX2029 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch 23 800 850 900 950 RF FREQUENCY (MHz) 1000 800 850 900 950 RF FREQUENCY (MHz) _______________________________________________________________________________________ 1000 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch Downconverter Curves TC = +85C 50 TC = +25C 40 PLO = -3dBm, 0dBm, +3dBm 600 700 800 900 1000 MAX2029 toc21 MAX2029 toc20 50 40 60 50 VCC = 4.75V, 5.0V, 5.25V 40 500 600 700 800 900 1000 500 600 700 800 900 LO FREQUENCY (MHz) LO FREQUENCY (MHz) LO FREQUENCY (MHz) LO LEAKAGE AT IF PORT vs. LO FREQUENCY LO LEAKAGE AT IF PORT vs. LO FREQUENCY LO LEAKAGE AT IF PORT vs. LO FREQUENCY -30 TC = +85C -40 -50 PLO = 0dBm, +3dBm -30 PLO = -3dBm -40 -50 -20 LO LEAKAGE AT IF PORT (dBm) TC = -40C -20 MAX2029 toc23 MAX2029 toc22 -20 LO LEAKAGE AT IF PORT (dBm) 500 LO LEAKAGE AT IF PORT (dBm) 60 LO SWITCH ISOLATION vs. LO FREQUENCY 70 1000 MAX2029 toc24 TC = -40C LO SWITCH ISOLATION (dB) MAX2029 toc19 LO SWITCH ISOLATION (dB) 60 LO SWITCH ISOLATION vs. LO FREQUENCY 70 LO SWITCH ISOLATION (dB) LO SWITCH ISOLATION vs. LO FREQUENCY 70 VCC = 4.75V, 5.0V, 5.25V -30 -40 -50 TC = +25C -60 -60 760 810 910 -60 710 760 810 860 910 760 810 860 LO FREQUENCY (MHz) LO FREQUENCY (MHz) LO LEAKAGE AT RF PORT vs. LO FREQUENCY LO LEAKAGE AT RF PORT vs. LO FREQUENCY LO LEAKAGE AT RF PORT vs. LO FREQUENCY -30 TC = +85C -35 -40 -25 -30 -35 PLO = -3dBm, 0dBm, +3dBm -40 -45 700 800 LO FREQUENCY (MHz) 900 1000 -20 -25 -30 -35 VCC = 4.75V, 5.0V, 5.25V -40 -45 600 MAX2029 toc27 -20 910 -15 LO LEAKAGE AT RF PORT (dBm) -25 MAX2029 toc26 TC = -40C -15 LO LEAKAGE AT RF PORT (dBm) TC = +25C -20 500 710 LO FREQUENCY (MHz) -15 LO LEAKAGE AT RF PORT (dBm) 860 MAX2029 toc25 710 -45 500 600 700 800 LO FREQUENCY (MHz) 900 1000 500 600 700 800 900 1000 LO FREQUENCY (MHz) _______________________________________________________________________________________ 7 MAX2029 Typical Operating Characteristics (continued) (Typical Application Circuit, C5 = 3.3pF, L1 and C4 not used, VCC = +5.0V, PLO = 0dBm, PRF = 0dBm, fLO < fRF, fIF = 90MHz, unless otherwise noted.) Typical Operating Characteristics (continued) (Typical Application Circuit, C5 = 3.3pF, L1 and C4 not used, VCC = +5.0V, PLO = 0dBm, PRF = 0dBm, fLO < fRF, fIF = 90MHz, unless otherwise noted.) Downconverter Curves 45 TC = -40C 55 TC = +25C 40 35 55 RF-TO-IF ISOLATION (dB) 50 RF-TO-IF ISOLATION vs. RF FREQUENCY 60 MAX2029 toc29 MAX2029 toc28 TC = +85C RF-TO-IF ISOLATION (dB) 50 45 PLO = -3dBm, 0dBm, +3dBm 40 35 30 30 850 900 950 1000 45 VCC = 4.75V, 5.0V, 5.25V 40 30 800 850 900 950 1000 800 850 900 950 RF FREQUENCY (MHz) RF FREQUENCY (MHz) RF FREQUENCY (MHz) RF PORT RETURN LOSS vs. RF FREQUENCY IF PORT RETURN LOSS vs. IF FREQUENCY LO SELECTED RETURN LOSS vs. LO FREQUENCY IF PORT RETURN LOSS (dB) 5 5 10 15 20 PLO = -3dBm, 0dBm, +3dBm 25 0 10 VCC = 4.75V, 5.0V, 5.25V 15 20 25 30 35 1000 MAX2029 toc33 0 MAX2029 toc31 0 LO SELECTED RETURN LOSS (dB) 800 50 35 MAX2029 toc32 RF-TO-IF ISOLATION (dB) 55 RF-TO-IF ISOLATION vs. RF FREQUENCY 60 MAX2029 toc30 RF-TO-IF ISOLATION vs. RF FREQUENCY 60 RF PORT RETURN LOSS (dB) 5 10 PLO = +3dBm PLO = 0dBm 15 20 25 30 PLO = -3dBm 35 INCLUDES IF TRANSFORMER 30 40 820 870 920 970 1020 40 0 100 RF FREQUENCY (MHz) 200 300 400 600 5 700 800 LO FREQUENCY (MHz) SUPPLY CURRENT vs. TEMPERATURE (TC) 100 MAX2029 toc34 0 VCC = 5.25V SUPPLY CURRENT (mA) 10 15 PLO = -3dBm, 0dBm, +3dBm 25 30 90 80 VCC = 5.0V VCC = 4.75V 70 35 40 60 500 600 700 800 LO FREQUENCY (MHz) 8 500 IF FREQUENCY (MHz) LO UNSELECTED RETURN LOSS vs. LO FREQUENCY 20 500 MAX2029 toc35 770 LO UNSELECTED RETURN LOSS (dB) MAX2029 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch 900 1000 -40 -15 10 35 60 TEMPERATURE (C) _______________________________________________________________________________________ 85 900 1000 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch Upconverter Curves 6 5 TC = -40C 8 4 9 7 6 5 8 CONVERSION LOSS (dB) TC = +85C 7 CONVERSION LOSS vs. RF FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) MAX2029 toc02 TC = +25C CONVERSION LOSS (dB) PLO = -3dBm, 0dBm, +3dBm 4 3 3 820 870 920 970 1020 7 6 5 VCC = 4.75V, 5.0V, 5.25V 4 3 820 870 920 970 1020 820 970 1020 INPUT IP3 vs. RF FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) INPUT IP3 vs. RF FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) 50 50 50 45 VCC = 5.25V 45 35 40 35 30 25 870 920 35 VCC = 4.75V 30 25 820 VCC = 5.0V 40 PLO = -3dBm, 0dBm, +3dBm TC = +85C 30 INPUT IP3 (dBm) INPUT IP3 (dBm) TC = +25C 40 970 1020 MAX2029 toc06 INPUT IP3 vs. RF FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) MAX2029 toc04 RF FREQUENCY (MHz) 45 25 820 870 920 970 1020 820 870 920 970 1020 RF FREQUENCY (MHz) LO + 2IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO + 2IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO + 2IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) 90 90 90 LO + 2IF REJECTION (dBc) TC = -40C 80 TC = +85C 70 60 TC = +25C PIF = 0dBm PLO = -3dBm 80 70 60 PLO = +3dBm 50 780 830 880 LO FREQUENCY (MHz) 930 80 VCC = 5.25V VCC = 4.75V 70 VCC = 5.0V 60 PLO = 0dBm 50 730 PIF = 0dBm LO + 2IF REJECTION (dBc) PIF = 0dBm MAX2029 toc09 RF FREQUENCY (MHz) MAX2029 toc07 RF FREQUENCY (MHz) MAX2029 toc08 INPUT IP3 (dBm) 920 RF FREQUENCY (MHz) TC = -40C LO + 2IF REJECTION (dBc) 870 RF FREQUENCY (MHz) MAX2029 toc05 CONVERSION LOSS (dB) 8 9 MAX2029 toc01 9 CONVERSION LOSS vs. RF FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) MAX2029 toc03 CONVERSION LOSS vs. RF FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) 50 730 780 830 880 LO FREQUENCY (MHz) 930 730 780 830 880 930 LO FREQUENCY (MHz) _______________________________________________________________________________________ 9 MAX2029 Typical Operating Characteristics (Typical Application Circuit, L1 = 4.7nH, C4 = 4.7pF, C5 not used, VCC = +5.0V, PLO = 0dBm, PIF = 0dBm, fRF = fLO + fIF, fIF = 90MHz, unless otherwise noted.) Typical Operating Characteristics (continued) (Typical Application Circuit, L1 = 4.7nH, C4 = 4.7pF, C5 not used, VCC = +5.0V, PLO = 0dBm, PIF = 0dBm, fRF = fLO + fIF, fIF = 90MHz, unless otherwise noted.) Upconverter Curves 90 90 90 80 TC = +25C 70 TC = +85C 60 50 780 830 880 PLO = 0dBm 70 60 930 80 VCC = 4.75V VCC = 5.0V 70 60 VCC = 5.25V 50 730 780 830 880 930 730 780 830 880 930 LO FREQUENCY (MHz) LO FREQUENCY (MHz) LO + 3IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO + 3IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO + 3IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) TC = -40C 80 TC = +25C 70 60 100 MAX2029 toc14 PIF = 0dBm PIF = 0dBm LO + 3IF REJECTION (dBc) LO + 3IF REJECTION (dBc) TC = +85C 90 100 MAX2029 toc13 PIF = 0dBm 90 80 PLO = -3dBm, 0dBm, +3dBm 70 60 730 780 830 880 930 MAX2029 toc15 LO FREQUENCY (MHz) 100 90 80 VCC = 4.75V, 5.0V, 5.25V 70 60 730 780 830 880 930 730 780 830 880 930 LO FREQUENCY (MHz) LO FREQUENCY (MHz) LO - 3IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO - 3IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO - 3IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO - 3IF REJECTION (dBc) 90 80 100 TC = -40C TC = +85C 70 60 PIF = 0dBm 90 80 PLO = -3dBm, 0dBm, +3dBm 70 60 730 780 830 880 LO FREQUENCY (MHz) 930 100 PIF = 0dBm VCC = 5.25V LO - 3IF REJECTION (dBc) PIF = 0dBm TC = +25C MAX2029 toc16 100 MAX2029 toc18 LO FREQUENCY (MHz) MAX2029 toc17 LO + 3IF REJECTION (dBc) PLO = -3dBm 50 730 10 PLO = +3dBm 80 PIF = 0dBm LO - 2IF REJECTION (dBc) LO - 2IF REJECTION (dBc) LO - 2IF REJECTION (dBc) TC = -40C PIF = 0dBm MAX2029 toc12 LO - 2IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) MAX2029 toc11 LO - 2IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) MAX2029 toc10 LO - 2IF REJECTION vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) PIF = 0dBm LO - 3IF REJECTION (dBc) MAX2029 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch 90 VCC = 5.0V 80 VCC = 4.75V 70 60 730 780 830 880 LO FREQUENCY (MHz) 930 730 780 830 880 LO FREQUENCY (MHz) ______________________________________________________________________________________ 930 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch Upconverter Curves TC = +25C -30 TC = -40C -40 -20 -30 PLO = -3dBm, 0dBm, +3dBm -40 LO LEAKAGE AT RF PORT vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) -10 MAX2029 toc21 MAX2029 toc20 -10 LO LEAKAGE AT RF PORT (dBm) -20 MAX2029 toc19 LO LEAKAGE AT RF PORT (dBm) -10 LO LEAKAGE AT RF PORT vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) LO LEAKAGE AT RF PORT (dBm) LO LEAKAGE AT RF PORT vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) -20 VCC = 4.75V, 5.0V, 5.25V -30 -40 TC = +85C -50 -50 730 780 830 880 -50 730 780 830 880 930 730 780 830 880 930 LO FREQUENCY (MHz) LO FREQUENCY (MHz) LO FREQUENCY (MHz) IF LEAKAGE AT RF vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) IF LEAKAGE AT RF vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) IF LEAKAGE AT RF vs. LO FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) TC = +25C -80 IF LEAKAGE AT RF (dBm) TC = -40C -70 -70 PLO = 0dBm, +3dBm -80 -90 -90 -60 -70 VCC = 4.75V, 5.0V -80 -90 PLO = -3dBm TC = +85C -100 VCC = 5.25V -100 780 830 880 930 -100 730 LO FREQUENCY (MHz) 780 830 880 930 LO FREQUENCY (MHz) 730 780 830 880 930 LO FREQUENCY (MHz) RF PORT RETURN LOSS vs. RF FREQUENCY (L-C BPF TUNED FOR 940MHz RF FREQUENCY) MAX2029 toc25 0 5 RF PORT RETURN LOSS (dB) 730 MAX2029 toc24 -60 IF LEAKAGE AT RF (dBm) -60 -50 MAX2029 toc23 -50 MAX2029 toc22 -50 IF LEAKAGE AT RF (dBm) 930 L1 AND C4 BPF INSTALLED 10 15 20 25 L1 AND C4 BPF REMOVED 30 35 THE L-C BPF ENHANCES PERFORMANCE IN THE UPCONVERTER MODE BUT LIMITS RF BANDWIDTH 40 820 870 920 970 1020 RF FREQUENCY (MHz) ______________________________________________________________________________________ 11 MAX2029 Typical Operating Characteristics (continued) (Typical Application Circuit, L1 = 4.7nH, C4 = 4.7pF, C5 not used, VCC = +5.0V, PLO = 0dBm, PIF = 0dBm, fRF = fLO + fIF, fIF = 90MHz, unless otherwise noted.) MAX2029 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch Pin Description PIN NAME FUNCTION 1, 6, 8, 14 VCC 2 RF 3 TAP Center Tap of the Internal RF Balun. Connect to ground. 4, 5, 10, 12, 13, 16, 17, 20 GND Ground. Connect to PCB ground plane for proper operation and improved pin-to-pin isolation. Power-Supply Connection. Bypass each VCC pin to GND with capacitors as shown in the Typical Application Circuit. Single-Ended 50 RF Input/Output. This port is internally matched and DC shorted to GND through a balun. 7 LOBIAS Bias Resistor for Internal LO Buffer. Connect a 523 1% resistor from LOBIAS to the power supply. 9 LOSEL 11 LO1 Local Oscillator Select. Logic-control input for selecting LO1 or LO2. Local Oscillator Input 1. Drive LOSEL low to select LO1. 15 LO2 Local Oscillator Input 2. Drive LOSEL high to select LO2. 18, 19 IF-, IF+ EP GND Differential IF Input/Outputs Exposed Ground Paddle. Solder the exposed paddle to the ground plane using multiple vias. Detailed Description The MAX2029 can operate either as a downconverter or an upconverter mixer. As a downconverter, the MAX2029 yields a 6.5dB conversion loss, a 6.7dB noise figure, and a +36.5dBm third-order input intercept point (IIP3). The integrated baluns and matching circuitry allow for 50 single-ended interfaces to the RF port and the two LO ports. The RF port can be used as an input for downconversion or an output for upconversion. A single-pole, double-throw (SPDT) switch provides 50ns switching time between the two LO inputs with 53dB of LO-to-LO isolation. Furthermore, the integrated LO buffer provides a high drive level to the mixer core, reducing the LO drive required at the MAX2029's inputs to a -3dBm to +3dBm range. The IF port incorporates a differential output for downconversion, which is ideal for providing enhanced IIP2 performance. For upconversion, the IF port is a differential input. Specifications are guaranteed over broad frequency ranges to allow for use in cellular band WCDMA, cdmaOneTM, cdma2000, and GSM 850/GSM 900 2.5G EDGE base stations. The MAX2029 is specified to operate over an 815MHz to 1000MHz RF frequency range, a 570MHz to 900MHz LO frequency range, and a DC to 250MHz IF frequency range. Operation beyond these ranges is possible; see the Typical Operating Characteristics for additional details. The MAX2029 is optimized for low-side LO injection architectures. However, the device can operate in high-side LO injection applications with an extended LO range, but performance degrades as fLO increases. See the Typical Operating Characteristics for measurements taken with fLO up to 1000MHz. For a pin-compatible device that has been optimized for high-side LO injection, refer to the MAX2031 data sheet. RF Port and Balun For using the MAX2029 as a downconverter, the RF input is internally matched to 50, requiring no external matching components. A DC-blocking capacitor is required because the input is internally DC shorted to ground through the on-chip balun. The RF return loss is typically better than 15dB over the entire 815MHz to 1000MHz RF frequency range. For upconverter operation, the RF port is a single-ended output similarly matched to 50. LO Inputs, Buffer, and Balun The MAX2029 is optimized for low-side LO injection architectures with a 570MHz to 900MHz LO frequency range. For a device with a 960MHz to 1180MHz LO frequency range, refer to the MAX2031 data sheet. As an added feature, the MAX2029 includes an internal LO SPDT switch that can be used for frequency-hopping applications. The switch selects one of the two singleended LO ports, allowing the external oscillator to settle on a particular frequency before it is switched in. LO switching time is typically less than 50ns, which is more than adequate for nearly all GSM applications. If frequency hopping is not employed, set the switch to either of the LO inputs. The switch is controlled by a digital input (LOSEL): logic-high selects LO2, logic-low selects LO1. To avoid damage to the part, voltage MUST be applied to VCC before digital logic is applied to LOSEL (see the Absolute Maximum Ratings). LO1 cdmaOne is a trademark of CDMA Development Group. 12 ______________________________________________________________________________________ High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch A two-stage internal LO buffer allows a wide inputpower range for the LO drive. All guaranteed specifications are for a -3dBm to +3dBm LO signal power. The on-chip low-loss balun, along with an LO buffer, drives the double-balanced mixer. All interfacing and matching components from the LO inputs to the IF outputs are integrated on-chip. High-Linearity Mixer The core of the MAX2029 is a double-balanced, highperformance passive mixer. Exceptional linearity is provided by the large LO swing from the on-chip LO buffer. Differential IF The MAX2029 mixer has a DC to 250MHz IF frequency range. Note that these differential ports are ideal for providing enhanced IIP2 performance. Single-ended IF applications require a 1:1 balun to transform the 50 differential IF impedance to 50 single-ended. Including the balun, the IF return loss is better than 15dB. The differential IF is used as an input port for upconverter operation. The user can use a differential IF amplifier following the mixer, but a DC block is required on both IF pins. Applications Information Input and Output Matching The RF and LO inputs are internally matched to 50. No matching components are required. As a downconverter, the return loss at the RF port is typically better than 15dB over the entire input range (815MHz to 1000MHz), and return loss at the LO ports are typically 15dB (570MHz to 850MHz). RF and LO inputs require only DC-blocking capacitors for interfacing. An optional L-C bandpass filter (BPF) can be installed at the RF port to improve upconverter performance. See the Typical Application Circuit and Typical Operating Characteristics for upconverter operation with an L-C BPF tuned for 920MHz RF frequency. Performance can be optimized at other frequencies by choosing different values for L1 and C4. Removing L1 and C4 altogether results in a broader match, but performance degrades. Contact factory for details. The IF output impedance is 50 (differential). For evaluation, an external low-loss 1:1 (impedance ratio) balun transforms this impedance to a 50 single-ended output (see the Typical Application Circuit). Bias Resistor Bias current for the LO buffer is optimized by fine tuning resistor R1. If reduced current is required at the expense of performance, contact the factory for details. If the 1% bias resistor values are not readily available, substitute standard 5% values. Layout Considerations A properly designed PCB is an essential part of any RF/microwave circuit. Keep RF signal lines as short as possible to reduce losses, radiation, and inductance. For the best performance, route the ground-pin traces directly to the exposed pad under the package. The PCB exposed pad MUST be connected to the ground plane of the PCB. It is suggested that multiple vias be used to connect this pad to the lower-level ground planes. This method provides a good RF/thermal conduction path for the device. Solder the exposed pad on the bottom of the device package to the PCB. The MAX2029 evaluation kit can be used as a reference for board layout. Gerber files are available upon request at www.maxim-ic.com. Power-Supply Bypassing Proper voltage-supply bypassing is essential for highfrequency circuit stability. Bypass each VCC pin with the capacitors shown in the Typical Application Circuit. See Table 1. Table 1. Typical Application Circuit Component List COMPONENT VALUE C1, C2, C7, C8, C10, C11, C12 82pF Microwave capacitors (0603) C3, C6, C9 10nF Microwave capacitors (0603) C4* 4.7pF Microwave capacitor (0603) C5** 3.3pF Microwave capacitor (0603) L1* 4.7nH Inductor (0603) R1 523 T1 1:1 U1 DESCRIPTION 1% resistor (0603) IF balun M/A-COM: MABAES0029 MAX2029 Maxim IC *C4 and L1 installed only when mixer is used as an upconverter. **C5 installed only when mixer is used as a downconverter. Exposed Pad RF/Thermal Considerations The exposed paddle (EP) of the MAX2029's 20-pin thin QFN-EP package provides a low-thermal-resistance path to the die. It is important that the PCB on which the MAX2029 is mounted be designed to conduct heat from the EP. In addition, provide the EP with a lowinductance path to electrical ground. The EP MUST be soldered to a ground plane on the PCB, either directly or through an array of plated via holes. ______________________________________________________________________________________ 13 MAX2029 and LO2 inputs are internally matched to 50, requiring an 82pF DC-blocking capacitor at each input. High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch MAX2029 Typical Application Circuit T1 1 4 3 5 IF 19 17 GND IF18 16 C2 C12 VCC C1 RF RF C4 L1 IF+ GND 20 C3 GND C5 VCC TAP GND GND 15 1 MAX2029 2 14 3 13 4 12 E.P. 11 5 LO2 LO2 VCC VCC C11 GND GND LO1 LO1 C10 GND 10 LOSEL 9 VCC 8 LOBIAS 7 VCC 6 R1 VCC LOSEL C6 C7 C8 VCC NOTE: L1 AND C4 USED ONLY FOR UPCONVERTER OPERATION. C5 USED ONLY FOR DOWNCONVERTER OPERATION. C9 Chip Information PROCESS: SiGe BiCMOS 14 ______________________________________________________________________________________ High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch QFN THIN.EPS ______________________________________________________________________________________ 15 MAX2029 Package Information (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to www.maxim-ic.com/packages.) MAX2029 High-Linearity, 815MHz to 1000MHz Upconversion/ Downconversion Mixer with LO Buffer/Switch Package Information (continued) (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to www.maxim-ic.com/packages.) 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. 16 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 (c) 2007 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc.