19-1262; Rev 0; 3/98 Low-Voltage, Bidirectional RF/Video Switch The MAX4529 is a low-voltage T-switch designed for switching RF and video signals from DC to 300MHz in 50Ω and 75Ω systems. This switch is constructed in a “T” configuration, ensuring excellent high-frequency off isolation of -80dB at 10MHz. The MAX4529 can handle Rail-to-Rail® analog signals in either direction. On-resistance (70Ω max) is flat (0.5Ω max) over the specified signal range, using ±5V supplies. The off leakage current is less than 1nA at +25°C and 20nA at +85°C. This CMOS switch can operate with dual power supplies ranging from ±2.7V to ±6V or a single supply between +2.7V and +12V. All digital inputs have 0.8V/2.4V logic thresholds, ensuring both TTL- and CMOS-logic compatibility when using ±5V or a single +5V supply. ____________________________Features ♦ High 50Ω Off Isolation: -80dB at 10MHz ♦ DC to 300MHz -3dB Signal Bandwidth ♦ 70Ω Signal Paths with ±5V Supplies ♦ 10Ω Signal-Path Flatness with ±5V Supplies ♦ ±2.7V to ±6V Dual Supplies +2.7V to +12V Single Supply ♦ Low Power Consumption: <1µW ♦ Rail-to-Rail Bidirectional Signal Handling ♦ >2kV ESD Protection per Method 3015.7 ♦ TTL/CMOS-Compatible Inputs with Single +5V or ±5V Ordering Information PART ________________________Applications TEMP. RANGE PINPACKAGE SOT TOP MARK MAX4529CPA 0°C to +70°C 8 Plastic DIP — RF Switching MAX4529CSA 0°C to +70°C 8 Narrow SO — Video Signal Routing MAX4529CUA 0°C to +70°C 8 µMAX High-Speed Data Acquisition MAX4529CUT-T 0°C to +70°C 6 SOT23-6 Test Equipment MAX4529C/D 0°C to +70°C Dice* — MAX4529EPA -40°C to +85°C 8 Plastic DIP — MAX4529ESA -40°C to +85°C 8 Narrow SO — MAX4529EUA -40°C to +85°C 8 µMAX MAX4529EUT-T -40°C to +85°C 6 SOT23-6 ATE Equipment Networking — AAAQ — AAAQ *Contact factory for dice specifications. _______________________Pin Configurations/Functional Diagrams/Truth Table MAX4529 N.C. 1 MAX4529 8 V+ NC 2 7 COM GND 3 6 N.C. IN 4 LOGIC SWITCH NC 1 6 COM 0 1 ON OFF V+ 2 5 GND V- 3 4 IN 5 V- SOT23-6 DIP/SO/µMAX N.C. = NOT INTERNALLY CONNECTED Rail-to-Rail is a registered trademark of Nippon Motorola Ltd. ________________________________________________________________ Maxim Integrated Products 1 For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800. For small orders, phone 408-737-7600 ext. 3468. MAX4529 General Description MAX4529 Low-Voltage, Bidirectional RF/Video Switch ABSOLUTE MAXIMUM RATINGS (Voltages referenced to GND) V+ ...........................................................................-0.3V, +13.0V V- ............................................................................-13.0V, +0.3V V+ to V-...................................................................-0.3V, +13.0V All Other Pins (Note 1) ..........................(V- - 0.3V) to (V+ + 0.3V) Continuous Current into Any Terminal..............................±10mA Peak Current into Any Terminal (pulsed at 1ms, 10% duty cycle)..................................±50mA ESD per Method 3015.7 ..................................................>2000V Continuous Power Dissipation (TA = +70°C) 8-Pin Plastic DIP (derate 9.09mW/°C above +70°C) ...727mW 8-Pin SO (derate 5.88mW/°C above +70°C)............... 471mW 8-Pin µMAX (derate 4.1mW/°C above +70°C) ............. 330mW 6-Pin SOT23-6 (derate 7.1mW/°C above +70°C) ........571mW Operating Temperature Ranges MAX4529C_ E .....................................................0°C to +70°C MAX4529E_ E ..................................................-40°C to +85°C Storage Temperature Range .............................-65°C to +150°C Lead Temperature (soldering, 10sec) .............................+300°C Note 1: Voltages on all other pins exceeding V+ or V- are clamped by internal diodes. Limit forward diode current to maximum current rating. 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. ELECTRICAL CHARACTERISTICS—Dual Supplies (V+ = +4.5V to +5.5V, V- = -4.5V to -5.5V, VINL = 0.8V, VINH = 2.4V, VGND = 0V, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL CONDITIONS TA MIN TYP (Note 2) MAX UNITS ANALOG SWITCH Analog Signal Range VCOM, VNC Signal-Path On-Resistance RON Signal-Path On-Resistance Flatness (Note 4) RFLAT(ON) (Note 3) V+ = 5V, V- = -5V, VCOM = ±3V, ICOM = 1mA V+ = 5V; V- = -5V; VCOM = 3V, 0V, -3V; ICOM = 1mA C, E V- +25°C 45 C, E V 70 Ω 100 +25°C 5 INC(OFF) V+ = 5.5V, V- = -5.5V, ± VCOM = ±4.5V, VNC = 4.5V +25°C -1 C, E -20 COM Off Leakage Current (Notes 5, 6) ICOM(OFF) V+ = 5.5V, V- = -5.5V, ± VCOM = ±4.5V, VNC = 4.5V +25°C -1 C, E -20 COM On Leakage Current (Notes 5, 6) ICOM(ON) V+ = 5.5V, V- = -5.5V, VCOM = ±4.5V +25°C -2 C, E -40 NC Off Leakage Current (Notes 5, 6) V+ 0.02 10 1 20 0.02 1 20 0.02 2 40 Ω nA nA nA LOGIC INPUT IN Input Logic Threshold High VINH C, E IN Input Logic Threshold Low VINL C, E 0.8 1.5 IN Input Current Logic High or Low IINH, IINL C, E -1 0.03 2 VIN = 0.8V or 2.4V 1.5 _______________________________________________________________________________________ 2.4 V V 1 µA Low-Voltage, Bidirectional RF/Video Switch (V+ = +4.5V to +5.5V, V- = -4.5V to -5.5V, VINL = 0.8V, VINH = 2.4V, VGND = 0V, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL CONDITIONS TA MIN TYP (Note 2) MAX 45 75 UNITS SWITCH DYNAMIC CHARACTERISTICS Turn-On Time tON VCOM = ±3V, V+ = 5V, V- = -5V, Figure 2 +25°C Turn-Off Time tOFF VCOM = ±3V, V+ = 5V, V- = -5V, Figure 2 +25°C Q CL = 1.0nF, VNC = 0V, RS = 0Ω, Figure 3 +25°C 5 Charge Injection (Note 3) NC Off Capacitance C, E 100 37 C, E 75 100 10 ns ns pC CNC(OFF) VNC = GND, f = 1MHz, Figure 5 +25°C 6 pF COM_ Off Capacitance CCOM(OFF) VCOM = 0V, f = 1MHz, Figure 5 +25°C 6 pF COM_ On Capacitance CCOM(ON) VCOM = VNC = 0V, f = 1MHz, Figure 5 +25°C 11.5 pF Off Isolation (Note 7) VISO RL = 50Ω, VCOM = 1VRMS, f = 10MHz, Figure 4 +25°C -80 dB -3dB Bandwidth BW RL = 50Ω, Figure 4 +25°C 300 MHz VIN = 5Vp-p, f < 20kHz, 600Ω in and out +25°C 0.004 % Distortion THD+N POWER SUPPLY Power-Supply Range V+, V- V+ Supply Current I+ V+ = 5.5V, VIN = 0V or V+, V- = -5.5V V - Supply Current I- V+ = 5.5V, VIN = 0V or V+, V- = -5.5V C, E ±2.7 +25°C -1 C, E -10 +25°C -1 C, E -10 ±6 0.05 1 10 0.05 1 10 V µA µA _______________________________________________________________________________________ 3 MAX4529 ELECTRICAL CHARACTERISTICS—Dual Supplies (continued) MAX4529 Low-Voltage, Bidirectional RF/Video Switch ELECTRICAL CHARACTERISTICS—Single +5V Supply (V+ = +4.5V to +5.5V, V- = 0V, VINL = 0.8V, VINH = 2.4V, VGND = 0V, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL CONDITIONS TA MIN TYP (Note 2) MAX V+ V 70 120 Ω UNITS ANALOG SWITCH Analog Signal Range (Note 3) +25°C V+ = 5V, VCOM = 3V, ICOM = 1mA +25°C INC(OFF) V+ = 5.5V, VCOM = 1V, VNC = 4.5V +25°C -1 C, E -20 COM Off Leakage Current (Notes 5, 6, 8) ICOM(OFF) V+ = 5.5V, VCOM = 1V, VNC = 4.5V +25°C -1 C, E -20 COM On Leakage Current (Notes 5, 6, 8) ICOM(ON) V+ = 5.5V; VCOM = 1V, 4.5V +25°C -2 C, E -40 Signal-Path On-Resistance NC Off Leakage Current (Notes 5, 6, 8) VCOM, VNC RON 0 C, E 150 0.02 1 20 0.02 1 20 0.02 2 40 nA nA nA LOGIC INPUT IN Input Logic Threshold High VINH C, E IN Input Logic Threshold Low VINL C, E 0.8 1.5 IN Input Current Logic High or Low IINH, IINL C, E -1 0.03 VIN = 0.8V or 2.4V 1.5 2.4 V V 1 µA SWITCH DYNAMIC CHARACTERISTICS Turn-On Time (Note 3) tON VCOM = 3V, V+ = 5V, Figure 2 +25°C Turn-Off Time (Note 3) tOFF VCOM = 3V, V+ = 5V, Figure 2 +25°C Charge Injection (Note 3) Off-Isolation (Note 7) Q VISO 65 C, E 100 120 43 C, E 90 110 CL = 1.0nF, VNC = 2.5V, RS = 0Ω, Figure 3 +25°C 1.5 RL = 50Ω, VCOM = 1VRMS, f = 10MHz, Figure 4 +25°C -75 10 ns ns pC dB POWER SUPPLY Power-Supply Range V+ Supply Current 4 V+ I+ V- = 0V V+ = 5.5V, VIN = 0V or V+ C, E 2.7 +25°C -1 C, E -10 12.0 0.05 _______________________________________________________________________________________ 1 10 V µA Low-Voltage, Bidirectional RF/Video Switch (V+ = +2.7V to +3.6V, V- = 0V, VINL = 0.4V, VINH = 2.4V, VGND = 0V, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL CONDITIONS MIN TA TYP (Note 2) MAX V+ V 175 400 Ω UNITS ANALOG SWITCH Analog Signal Range VCOM, VNC (Note 3) +25°C RON V+ = 2.7V, VCOM = 1.5V, ICOM = 0.1mA +25°C IN Input Logic Threshold High VINH (Note 3) C, E IN Input Logic Threshold Low VINL (Note 3) C, E 0.4 VIN = 0.4V or 2.4V (Note 3) C, E -1 Signal-Path On-Resistance 0 C, E 500 LOGIC INPUT IN Input Current Logic High or Low IINH, IINL 1.0 2.4 V 1.0 V 1 µA SWITCH DYNAMIC CHARACTERISTICS Turn-On Time tON VCOM = 1.5V, V+ = 2.7V, Figure 2 (Note 3) +25°C Turn-Off Time tOFF VCOM = 1.5V, V+ = 2.7V, Figure 2 (Note 3) +25°C I+ V+ = 3.6V, VIN = 0V or V+ 150 300 C, E ns 400 70 150 C, E ns 200 POWER SUPPLY V+ Supply Current +25°C -1 C, E -10 0.05 1 µA 10 Note 2: The algebraic convention is used in this data sheet; the most negative value is shown in the minimum column. Note 3: Guaranteed by design. Note 4: Resistance flatness is defined as the difference between the maximum and the minimum value of on-resistance as measured over the specified analog signal range. Note 5: Leakage parameters are 100% tested at the maximum rated hot temperature and guaranteed by correlation at +25°C. Note 6: Guaranteed by design, not subject to production testing in SOT package. Note 7: Off isolation = 20log10 (VCOM / VNC), VCOM = output, VNC = input to off switch. Note 8: Leakage testing for single-supply operation is guaranteed by testing with dual supplies. __________________________________________Typical Operating Characteristics (V+ = +5V, V- = -5V, GND = 0V, TA = +25°C, packages are surface mount, unless otherwise noted.) ON-RESISTANCE vs. VCOM (SINGLE SUPPLY) ON-RESISTANCE (Ω) 100 V+ = 2.7V V+ = 3.3V 100 V+ = 5.0V V+ = 7.5V V+ = 3.3V V- = -3.3V V+ = 10.0V 10 -4 -3 -2 -1 0 1 VCOM (V) 2 3 4 5 +85°C 50 +70°C 0°C 30 -40°C 20 -55°C V+ = 5V V- = -5V 0 0 1 2 3 4 5 6 VCOM (V) 7 8 9 10 +25°C 40 10 10 -5 +125°C 60 V+ = 2.0V V+ = 2.7V V- = -2.7V V+ = 5.0V V- = -5.0V 70 MAX4529-03 V- = 0V V+ = 1.2V ON-RESISTANCE (Ω) ON-RESISTANCE (Ω) V+ = 1.2V V- = -1.2V V+ = 2.0V V- = -2.0V 1000 MAX4529-01 1000 ON-RESISTANCE vs. VCOM AND TEMPERATURE (DUAL SUPPLIES) MAX4529-02 ON-RESISTANCE vs. VCOM (DUAL SUPPLIES) -5 -4 -3 -2 -1 0 1 2 3 4 5 VCOM (V) _______________________________________________________________________________________ 5 MAX4529 ELECTRICAL CHARACTERISTICS—Single +3V Supply ____________________________Typical Operating Characteristics (continued) (V+ = +5V, V- = -5V, GND = 0V, TA = +25°C, packages are surface mount, unless otherwise noted.) SUPPLY, COM, AND NC LEAKAGE CURRENTS vs. TEMPERATURE 100,000 30 +25°C 0°C 1000 1 V+ = 3V V- = 0V 3 0.01 0 -55 -35 -15 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5 25 45 65 85 105 125 -5 -4 -3 -2 -1 0 1 2 3 VCOM (V) TEMPERATURE (°C) VCOM (V) ON-TIME vs. TEMPERATURE OFF-TIME vs. TEMPERATURE LOGIC-LEVEL THRESHOLD vs. SUPPLY VOLTAGE 70 120 80 V+ = 5V V- = 0V 50 tOFF (ns) V+ = 5V V- = 0V 100 V+ = 3V V- = 0V 60 LOGIC-LEVEL THRESHOLD (V) V+ = 3V V- = 0V 40 V+ = 5V V- = -5V 30 60 20 40 V+ = 5V V- = -5V 20 3.0 0 -55 -35 -15 5 25 45 65 5 25 45 65 1 2 3 4 5 20 10 0 -10 OFF ISOLATION -120 10 FREQUENCY (MHz) 100 -20 -30 -40 -50 -60 1000 MAX4529-11 -40 -50 -60 -70 10 THD (%) -20 -30 50 40 30 ON PHASE 6 V+ (V) 100 60 ON PHASE (DEGREES) LOSS (dB) ON LOSS 1 1.0 TOTAL HARMONIC DISTORTION vs. FREQUENCY MAX4529-10 0.1 1.5 0 85 105 125 FREQUENCY RESPONSE -80 -90 -100 -110 2.0 TEMPERATURE (°C) TEMPERATURE (°C) 0 -10 2.5 0 -55 -35 -15 85 105 125 5 0.5 10 0 4 MAX4529-09 80 MAX4529-07 180 MAX4529-08 0 IOFF 0.1 V+ = 5V V- = -5V 0 6 V+ = 5V V- = 0V 6 10 -55°C 10 140 ION 100 V+ = 5V V- = -5V 9 -40°C 20 160 12 I+, IQ (pC) +70°C 40 V+ = 5V V- = -5V 10,000 +85°C CHARGE INJECTION vs. VCOM 15 MAX4529-05 +125°C 50 1,000,000 CURRENT (pA) ON-RESISTANCE (Ω) 60 MAX4529-04 70 MAX4529-06 ON-RESISTANCE vs. VCOM AND TEMPERATURE (SINGLE SUPPLY) tON (ns) MAX4529 Low-Voltage, Bidirectional RF/Video Switch 1 0.1 10 100 1k 10k FREQUENCY (Hz) _______________________________________________________________________________________ 30k 7 8 9 10 11 12 Low-Voltage, Bidirectional RF/Video Switch PIN NAME FUNCTION* SOT23-6 DIP/SO/µMAX — 1, 6 N.C. Not Internally Connected 1 2 NC Analog Switch Normally Closed** Terminal 2 8 V+ Positive Supply-Voltage Input (analog and digital). The voltage difference between V+ and V- should never exceed 12V. 3 5 V- -5V Supply Input. Connect to GND for single-supply operation. 4 4 IN Logic-Level Control Input. Logic-level voltages should never exceed V+ or V-. 5 3 GND RF and Logic Ground. Connect to ground plane. 6 7 COM Analog Switch Common** Terminal. Analog signal voltages should never exceed V+ or V-. * All pins except N.C. have ESD diodes to V- and V+. ** NC and COM pins are identical and interchangeable. Either may be considered as an input or output; signals pass equally well in either direction. Theory of Operation Logic-Level Translators The MAX4529 is constructed as a high-frequency “T” switch, as shown in Figure 1. The logic-level input, IN, is translated by amplifier A1 into a V+ to V- logic signal that drives inverter A2. Amplifier A2 drives the gates of N-channel MOSFETs N1 and N2 from V+ to V-, turning them fully on or off. The same signal drives inverter A3 (which drives the P-channel MOSFETs P1 and P2) from V+ to V-, turning them fully on or off, and drives the Nchannel MOSFET N3 off and on. The logic-level threshold is determined by V+ and GND. The voltage on GND is usually at ground potential, but it may be set to any voltage between (V+ - 2V) and V-. When the voltage between V+ and GND is less than 2V, the level translators become very slow and unreliable. Normally, GND should be connected to the ground plane. Switch On Condition When the switch is on, MOSFETs N1, N2, P1, and P2 are on and MOSFET N3 is off. The signal path is COM to NC, and because both N-channel and P-channel MOSFETs act as pure resistances, it is symmetrical (i.e., signals may pass in either direction). The off MOSFET, N3, has no DC conduction, but has a small amount of capacitance to GND. The four on MOSFETs also have capacitance to ground that, together with the series resistance, forms a lowpass filter. All of these capaci- NORMALLY CLOSED SWITCH CONSTRUCTION N1 COM D IN COM - NC 0 1 ON OFF N2 S D P1 S NC S P2 D S D V+ A1 A2 A3 D N3 IN S GND V+ VESD DIODES ON GND, IN, COM, AND NC V- Figure 1. T-Switch Construction tances are distributed evenly along the series resistance, so they act as a transmission line rather than a simple R-C filter. This helps to explain the exceptional 300MHz bandwidth when the switches are on. Typical attenuation in 50Ω systems is -2dB and is reasonably flat up to 100MHz. Higher-impedance circuits show even lower attenuation (and vice versa), but slightly lower bandwidth due to the increased effect of the internal and external capacitance and the switch’s internal resistance. _______________________________________________________________________________________ 7 MAX4529 Pin Description MAX4529 Low-Voltage, Bidirectional RF/Video Switch The MAX4529 is a optimized for ±5V operation. Using lower supply voltages or a single supply increases switching time, on-resistance (and therefore on-state attenuation), and nonlinearity. Switch Off Condition When the switch is off, MOSFETs N1, N2, P1, and P2 are off and MOSFET N3 is on. The signal path is through the off-capacitances of the series MOSFETs, but it is shunted to ground by N3. This forms a highpass filter whose exact characteristics depend on the source and load impedances. In 50Ω systems, and below 10MHz, the attenuation can exceed 80dB. This value decreases with increasing frequency and increasing circuit impedances. External capacitance and board layout have a major role in determining overall performance. Applications Information Power-Supply Considerations Overview The MAX4529’s construction is typical of most CMOS analog switches. It has three supply pins: V+, V-, and GND. V+ and V- are used to drive the internal CMOS switches and set the limits of the analog voltage on any switch. Reverse ESD protection diodes are internally connected between each analog signal pin and both V+ and V-. If the voltage on any pin exceeds V+ or V-, one of these diodes will conduct. During normal operation these reverse-biased ESD diodes leak, forming the only current drawn from V-. Virtually all the analog leakage current is through the ESD diodes. Although the ESD diodes on a given signal pin are identical, and therefore fairly well balanced, they are reverse biased differently. Each is biased by either V+ or V- and the analog signal. This means their leakages vary as the signal varies. The difference in the two diode leakages from the signal path to the V+ and V- pins constitutes the analog signal-path leakage current. All analog leakage current flows to the supply terminals, not to the other switch terminal. This explains how both sides of a given switch can show leakage currents of either the same or opposite polarity. When the switch is on, there is no connection between the analog signal paths and GND. The analog signal paths consist of an N-channel and P-channel MOSFET with their sources and drains paralleled and their gates driven out of phase with V+ and V- by the logic-level translators. V+ and GND power the internal logic and logic-level translators, and set the input logic thresholds. The logic-level translators convert the logic levels to 8 switched V+ and V- signals to drive the gates of the analog switches. This drive signal is the only connection between the logic supplies and the analog supplies. All pins have ESD protection to V+ and to V-. Increasing V- has no effect on the logic-level thresholds, but it does increase the drive to the P-channel switches, reducing their on-resistance. V- also sets the negative limit of the analog signal voltage. The logic-level thresholds are CMOS and TTL compatible when V+ is +5V. As V+ is raised, the threshold increases slightly; when V+ reaches +12V, the level threshold is about 3.1V, which is above the TTL output high-level minimum of 2.8V, but still compatible with CMOS outputs. Bipolar-Supply Operation The MAX4529 operates with bipolar supplies between ±2.7V and ±6V. The V+ and V- supplies need not be symmetrical, but their sum cannot exceed the absolute maximum rating of 13.0V. Do not connect the MAX4529 V+ pin to +3V and connect the logic-level input pins to TTL logic-level signals. TTL logic-level outputs can exceed the absolute maximum ratings, causing damage to the part and/or external circuits. CAUTION: The absolute maximum V+ to V- differential voltage is 13.0V. Typical “±6-Volt” or “12-Volt” supplies with ±10% tolerances can be as high as 13.2V. This voltage can damage the MAX4529. Even ±5% tolerance supplies may have overshoot or noise spikes that exceed 13.0V. Single-Supply Operation The MAX4529 operates from a single supply between +2.7V and +12V when V- is connected to GND. All of the bipolar precautions must be observed. Note, however, that these parts are optimized for ±5V operation, and most AC and DC characteristics are degraded significantly when departing from ±5V. As the overall supply voltage (V+ to V-) is lowered, switching speed, on-resistance, off isolation, and distortion are degraded (see Typical Operating Characteristics). Single-supply operation also limits signal levels and interferes with grounded signals. When V- = 0V, AC signals are limited to -0.3V. Voltages below -0.3V can be clipped by the internal ESD-protection diodes, and the parts can be damaged if excessive current flows. _______________________________________________________________________________________ Low-Voltage, Bidirectional RF/Video Switch Power Off When power to the MAX4529 is off (i.e., V+ = 0V and V= 0V), the Absolute Maximum Ratings still apply. This means that neither logic-level inputs on IN nor signals on COM or NC can exceed ±0.3V. Voltages beyond ±0.3V cause the internal ESD-protection diodes to conduct, and the parts can be damaged if excessive current flows. Grounding DC Ground Considerations Satisfactory high-frequency operation requires that careful consideration be given to grounding. For most applications, a ground plane is strongly recommended, and GND should be connected to it with solid copper. In systems that have separate digital and analog (signal) grounds, connect these switch GND pins to analog ground. Preserving a good signal ground is much more important than preserving a digital ground. Ground current is only a few nanoamps. The logic-level input, IN, has voltage thresholds determined by V+ and GND. (V- does not influence the logic-level threshold.) With +5V and 0V applied to V+ and GND, the threshold is about 1.6V, ensuring compatibility with TTL- and CMOS-logic drivers. The GND pin can be connected to separate voltage potentials if the logic-level input is not a normal logic signal. (The GND voltage cannot exceed (V+ - 2V) or V-.) Elevating GND reduces off isolation. Note, however, that IN can be driven more negative than GND, as far as V-. GND does not have to be removed from 0V when IN is driven from bipolar sources, but the voltage on IN should never exceed V-. GND should be separated from 0V only if the logic-level threshold has to be changed. If the GND pin is not connected to 0V, it should be bypassed to the ground plane with a surface-mount 10nF capacitor to maintain good RF grounding. DC current in the IN and GND pins is less than 1nA, but increases with switching frequency. AC Ground and Bypassing A ground plane is mandatory for satisfactory highfrequency operation. (Prototyping using hand wiring or wire-wrap boards is strongly discouraged.) Connect any 0V GND pins to the ground plane with solid copper. (The GND pin extends the high-frequency ground through the package wire-frame, into the silicon itself, thus improving isolation.) The ground plane should be solid metal underneath the device, without interruptions. There should be no traces under the device itself. For DIP packages, this applies to both sides of a twosided board. Failure to observe this will have a minimal effect on the “on” characteristics of the switch at high frequencies, but it will degrade the off isolation and crosstalk. V+ and V- pins should be bypassed to the ground plane with surface-mount 10nF capacitors. For DIP packages, they should be mounted as close as possible to the pins on the same side of the board as the device. Do not use feedthroughs or vias for bypass capacitors. For surface-mount packages, the pins are so close to each other that the bypass capacitors should be mounted on the opposite side of the board from the device. In this case, use short feedthroughs or vias, directly under the V+ and V- pins. Any GND pin not connected to 0V should be similarly bypassed. If Vis 0V, connect it directly to the ground plane with solid copper. Keep all leads short. Signal Routing Keep all signal leads as short as possible. Separate all signal leads from each other and other traces with the ground plane on both sides of the board. Where possible, use coaxial cable instead of printed circuit board traces. Board Layout IC sockets degrade high-frequency performance and should not be used if signal bandwidth exceeds 5MHz. Surface-mount parts, having shorter internal lead frames, provide the best high-frequency performance. Keep all bypass capacitors close to the device, and separate all signal leads with ground planes. Such grounds tend to be wedge-shaped as they get closer to the device. Use vias to connect the ground planes on each side of the board, and place the vias in the apex of the wedge-shaped grounds that separate signal leads. Logic-level signal lead placement is not critical. _______________________________________________________________________________________ 9 MAX4529 Single-Supply Operation Above 5V The MAX4529 is designed for operation from single +5V or dual ±5V supplies. As V+ is increased above 5V, the logic-level threshold voltage increases and the supply current increases. In addition, if the logic levels are not driven rail-to-rail, the analog signal pins, COM and NC, can conduct a significant DC current (up to 1mA) to the supply pins. This current can add an unwanted DC bias to the signal. Therefore, when operating V+ above 5V, always drive the IN pin rail-to-rail. MAX4529 Low-Voltage, Bidirectional RF/Video Switch ______________________________________________Test Circuits/Timing Diagrams +5V 10nF V+ V+ NC VIN 3V 50% 50% 0V MAX4529 VIN 90% VOUT IN COM GND VOUT 90% 0V VRL = 50Ω 50Ω tOFF tON 10nF -5V V- IS CONNECTED TO GND (OV) FOR SINGLE-SUPPLY OPERATION. Figure 2. Switching Time 10nF +5V V+ V+ NC VNC = 0V VIN 0V MAX4529 VIN IN COM GND V- VOUT ∆VOUT VOUT CL = 1000pF 50Ω 10nF -5V V- IS CONNECTED TO GND (0V) FOR SINGLE-SUPPLY OPERATION. ∆VOUT IS THE MEASURED VOLTAGE DUE TO CHARGE TRANSFER ERROR Q WHEN THE CHANNEL TURNS OFF. Q = ∆VOUT x CL Figure 3. Charge Injection 10 ______________________________________________________________________________________ Low-Voltage, Bidirectional RF/Video Switch +5V 10nF V OFF ISOLATION = 20log OUT VIN NETWORK ANALYZER 0V OR V+ V+ IN NC 50Ω VIN V ON LOSS = 20log OUT VIN 50Ω MAX4529 COM GND VOUT V- MEAS REF 50Ω 50Ω 10nF -5V MEASUREMENTS ARE STANDARDIZED AGAINST SHORT AT IC TERMINALS. OFF ISOLATION IS MEASURED BETWEEN COM_ AND "OFF" NC TERMINAL. ON LOSS IS MEASURED BETWEEN COM_ AND "ON" NC TERMINAL. SIGNAL DIRECTION THROUGH SWITCH IS REVERSED; WORST VALUES ARE RECORDED. V- IS CONNECTED TO GND (0V) FOR SINGLE-SUPPLY OPERATION. Figure 4. On Loss and Off Isolation ___________________Chip Topography V+ 10nF +5V NC 0V OR V+ COM V+ IN NC MAX4529 COM GND V- 1MHz CAPACITANCE ANALYZER 0.054" (1.372mm) N.C. N.C. 10nF -5V GND Figure 5. NC and COM Capacitance V- IN 0.038" (0.965mm) TRANSISTOR COUNT: 78 SUBSTRATE INTERNALLY CONNECTED TO VN.C. = NO CONNECTION ______________________________________________________________________________________ 11 MAX4529 _________________________________Test Circuits/Timing Diagrams (continued) ________________________________________________________Package Information 6LSOT.EPS MAX4529 Low-Voltage, Bidirectional RF/Video Switch 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. 12 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 © 1998 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.