19-4533; Rev 1; 2/12 MAX7036 Evaluation Kit Evaluates: MAX7036 General Description The MAX7036 evaluation kit (EV kit) provides a proven design to evaluate the MAX7036 ASK receiver in a TQFN package with an exposed pad. The EV kit enables testing of the device’s RF performance and requires no additional support circuitry. The RF input uses an SMA connector for convenient connection to test equipment. The MAX7036 EV kit is available in two versions, 315MHz (MAX7036EVKIT315+) and 433.92MHz (MAX7036EVKIT433+). The passive components are optimized for these frequencies. The EV kit PCBs come with a MAX7036GTP/V+ installed on both EV kit versions. Features SLead(Pb)-Free and RoHS Compliant SProven PCB Layout SProven Components List SAvailable in 315MHz and 433.92MHz Versions SFully Assembled and Tested Ordering Information PART TYPE MAX7036EVKIT-315+ EV Kit MAX7036EVKIT-433+ EV Kit +Denotes lead(Pb)-free and RoHS compliant. Component List DESIGNATION QTY DESCRIPTION C1, C9, C13, C20 4 0.1FF ±10%, 16V X7R ceramic capacitors (0603) Murata GRM188R71C104K C2, C17 0 Not installed, capacitors (0603) DESIGNATION QTY DESCRIPTION 315MHz: 4.7pF ±5%, 50V C0G ceramic capacitor (0603) Murata GRM1885C1H4R7C C19 1 433.92MHz: 10pF ±5%, 50V C0G ceramic capacitors (0603) Murata GRM1885C1H100J C21 1 10pF ±5%, 50V C0G ceramic capacitor (0603) Murata GRM1885C1H100J 1FF ±10%, 6.3V X5R ceramic capacitor (0603) Murata GRM188R60J105K C22 1 10FF ±20%, 6.3V X5R ceramic capacitor (0603) Murata GRM188R60J106M 1 1 180pF ±10%, 50V C0G ceramic capacitor (0603) Murata GRM1885C1H181J C23 220pF ±10%, 50V X7R ceramic capacitor (0603) Murata GRM188R71H221K JU1, JU3 2 2-pin headers JU2, JU4 2 3-pin headers C6 1 22pF ±5%, 50V C0G ceramic capacitor (0603) Murata GRM1885C1H220J C7, C8, C11, C14, C15 100pF ±5%, 50V C0G ceramic capacitors (0603) Murata GRM1885C1H101J L1 5 C10, C12 2 0.01FF ±10%, 25V X7R ceramic capacitors (0603) Murata GRM188R71E103K 1 390pF ±5%, 50V C0G ceramic capacitor (0603) Murata GRM1885C1H391J C3, C16 C4 C5 C18 2 1 315MHz: 4.7pF ±5%, 50V C0G ceramic capacitors (0603) Murata GRM1885C1H4R7C 433.92MHz: 2.7pF ±0.1pF, 50V C0G ceramic capacitor (0603) Murata GRM1885C1H2R7B 315MHz: 100nH ±2% inductor (0603) Murata LQW18ANR10G00 1 433.92MHz: 47nH ±2% inductor (0603) Murata LQW18AN47NG00 315MHz: 27nH ±2% inductor (0603) Murata LQW18AN27NG00 L2 1 433.92MHz: 15nH ±2% inductor (0603) Murata LQW18AN15NG00 __________________________________________________________________ Maxim Integrated Products 1 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. MAX7036 Evaluation Kit Evaluates: MAX7036 Component List (continued) DESIGNATION QTY P1 1 SMA end-launch jack receptacle DESCRIPTION P2 1 SMA female vertical-mount PCB connector R1 1 22kI ±5% resistor (0603) R2 0 Not installed, resistor (0603) TP1–TP4 4 Miniature red test points U1 1 ASK receiver (20 TQFN-EP*) Maxim MAX7036GTP/V+ DESIGNATION QTY DESCRIPTION 315MHz: 9.8375MHz crystal (AT-51CD2) NDK EXS00A-AT00733 Y1 1 — 3 Shunts — 1 PCB: MAX7036 EVALUATION KIT+ 433.92MHz: 13.55375MHz crystal (AT-51CD2) NDK EXS00A-AT00732 *EP = Exposed pad. Component Suppliers SUPPLIER PHONE WEBSITE Murata Electronics North America, Inc. 770-436-1300 www.murata-northamerica.com NDK America (Nihon Dempa Kogyo Co., Ltd.) 815-544-7900 www.ndk.com/en Note: Indicate that you are using the MAX7036 when contacting these component suppliers. Quick Start • MAX7036 EV kit Required Equipment • 3.3V, 20mA DC power supply • RF generator capable of delivering -120dBm to 0dBm output power at the operating frequency, in addition to amplitude modulation (AM) or pulse modulation (e.g., Agilent E4420B or equivalent) • Oscilloscope • Optional ammeter for measuring supply current Procedure The MAX7036 EV kit is fully assembled and tested. Follow the steps below to verify board operation. Caution: Do not turn on the DC power supply or RF signal generator until all connections are completed. 1) Verify that the jumpers are in their default position, as shown in Table 1. 2) Connect a 3.3V DC power supply (through an ammeter, if desired) to the VDD and GND pads on the EV kit. Do not turn on the supply. 3) Connect the RF signal generator to the P2 SMA connector. Do not turn on the generator output. Set the generator for an output carrier frequency of 315MHz (or 433.92MHz) at a power level of -100dBm. Set the modulation of the generator to provide 100% AM (or pulse modulation), with a 4kHz square wave. 4) Connect the oscilloscope to test point TP2 (DATAOUT). 5) Turn on the DC power supply. The supply current should be between 5mA and 6mA. 6) Activate the RF generator’s output without modulation. Set the RF generator to -100dBm. Enable AM squarewave (or pulse) modulation on the RF generator and set the scope’s coupling to DC. The scope now displays a 4kHz square wave at TP2. Additional Evaluation 1) With the modulation still set to AM (or pulse), observe the effect of reducing the RF generator’s amplitude at TP2 (DATAOUT). The error rate in this sliced digital signal increases with reduced RF signal level. The sensitivity is usually defined as the point at which the error in interpreting the data increases beyond a set limit, as defined by a bit-error rate (BER) test. Note: The sensitivity values shown in the MAX7036 IC data sheet assume that pulse modulation is being used. Depending on the model of signal generator, use of 100% AM might not produce identical results to pulse modulation. 2)Connect the oscilloscope to test point TP1, set the scope’s coupling to AC, and adjust the voltage sensitivity. The scope now displays a lowpass-filtered square wave (filtered analog baseband data). 3) Set the scope’s coupling to DC, adjust the voltage sensitivity, and turn off the modulation from the RF generator. The scope should display a DC voltage that varies from approximately 1.35V to 2.2V as the __________________________________________________________________ Maxim Integrated Products 2 MAX7036 Evaluation Kit Evaluates: MAX7036 Table 1. Jumper Table (JU1–JU4) JUMPER SHUNT POSITION JU1 Open Closed* JU2 JU3 JU4 DESCRIPTION Disconnects AVDD and DVDD from VDD. Apply up to 5V on the VDD pad. An internal regulator provides power to AVDD and DVDD. Connects AVDD and DVDD to VDD. When connected, do not exceed 3.3V on the VDD pad. 1-2* Connects ENABLE to VDD (normal operation) 2-3 Connects ENABLE to GND (shutdown) Open* Always keep open. Provides a test point for the IF signal. 1-2 Connects PDOUT to DSN node for faster data detection (if populated) 2-3* Connects PDOUT to GND through R2 and C17 (if populated) *Default position. RF generator amplitude is changed from -115dBm to 0dBm. Note: At an input amplitude of approximately -60dBm, this DC voltage drops suddenly to about 1.76V and then rises again with increasing input amplitude. This is normal; the AGC is turning on the LNA gain-reduction resistor. 4)Capacitors C5 and C18 are used to set the corner frequency of the 2nd-order lowpass Sallen-Key data filter. The current values were selected for bit rates up to 4kbps Manchester. Adjusting these values accommodates different data rates (refer to the MAX7036 IC data sheet for more details). Layout Issues A properly designed PCB is essential for any RF/microwave circuit. Keep high-frequency input and output lines as short as possible to minimize losses and radiation. At high frequencies, trace lengths that are on the order of λ/10 or longer can act as antennas. Both parasitic inductance and capacitance are influential on circuit layouts and are best avoided by using short trace lengths. Generally, a 10-mil wide PCB trace, 0.0625in above a ground plane, with FR4 dielectric has about 19nH/in of inductance and about 1pF/in of capacitance. In the LNA/mixer circuit, where the inductor is on the order of 20nH and a capacitor is on the order of 3pF, the proximity of the circuit to the MAX7036 has a strong influence on the effective component values. To reduce the parasitic inductance, use a solid ground or power plane below the signal traces. Also, use low-inductance connections to ground on all GND pins, and place decoupling capacitors close to all VDD connections. Table 2. Test Points TEST POINT DESCRIPTION TP1 Noninverting op-amp input TP2 DATAOUT output TP3 PDOUT output TP4 GND Detailed Description of Hardware The MAX7036 EV kit provides a proven layout for the MAX7036. On-board test points are included to monitor various signals (Table 2). Power Supply The MAX7036 can operate from 3.3V or 5V supplies. For 5V operation, remove the shunt from JU1 before connecting the supply to VDD. AVDD and DVDD operate from an internal linear regulator when VDD = 5V. For 3.3V operation, connect the shunt on JU1. IF Signal Jumper JU3 with one side grounded is provided to monitor the IF signal. A shunt cannot be used at JU3. External Frequency Input For applications where an external frequency is desired over the crystal frequency, it is possible to remove the crystal and apply an external frequency through P1. Capacitor C2 is necessary (use a 0.01µF capacitor). __________________________________________________________________ Maxim Integrated Products 3 MAX7036 Evaluation Kit Evaluates: MAX7036 Figure 1. MAX7036EVKIT315+ EV Kit Schematic __________________________________________________________________ Maxim Integrated Products 4 MAX7036 Evaluation Kit Evaluates: MAX7036 Figure 2. MAX7036EVKIT433+ EV Kit Schematic __________________________________________________________________ Maxim Integrated Products 5 MAX7036 Evaluation Kit Evaluates: MAX7036 Figure 3. MAX7036 EV Kit Component Placement Guide— Component Side Figure 4. MAX7036 EV Kit PCB Layout—Component Side Figure 5. MAX7036 EV Kit PCB Layout—Solder Side __________________________________________________________________ Maxim Integrated Products 6 MAX7036 Evaluation Kit Evaluates: MAX7036 Revision History REVISION NUMBER REVISION DATE 0 4/09 Initial release 1 2/12 Updated IC part number and the Additional Evaluation section DESCRIPTION PAGES CHANGED — 1, 2 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. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 © 2012 Maxim Integrated Products 7 Maxim is a registered trademark of Maxim Integrated Products, Inc.