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SP3222E

SP3222E

  • 厂商:

    SIPEX(迈凌)

  • 封装:

  • 描述:

    SP3222E - True 3.0V to 5.5V RS-232 Transceivers - Sipex Corporation

  • 数据手册
  • 价格&库存
SP3222E 数据手册
® SP3222E/3232E True +3.0V to +5.5V RS-232 Transceivers FEATURES ■ Meets true EIA/TIA-232-F Standards from a +3.0V to +5.5V power supply ■ Minimum 120Kbps Data Rate Under Full Load ■ 1µA Low-Power Shutdown with Receivers Active (SP3222E) ■ Interoperable with RS-232 down to +2.7V power source ■ Enhanced ESD Specifications: ±15kV Human Body Model ±15kV IEC1000-4-2 Air Discharge ±8kV IEC1000-4-2 Contact Discharge EN 1 18 SHDN 17 VCC 16 GND 15 SP3222E 14 T1OUT R1IN C1+ 2 V+ C1C2+ C2VT2OUT R2IN 3 4 5 6 7 8 9 13 R1OUT 12 T1IN 11 T2IN 10 R2OUT DIP/SO Now Available in Lead Free Packaging Note: See page 6 for other pinouts DESCRIPTION The SP3222E/3232E series is an RS-232 transceiver solution intended for portable or handheld applications such as notebook or palmtop computers. The SP3222E/3232E series has a high-efficiency, charge-pump power supply that requires only 0.1µF capacitors in 3.3V operation. This charge pump allows the SP3222E/3232E series to deliver true RS-232 performance from a single power supply ranging from +3.3V to +5.0V. The SP3222E/3232E are 2-driver/2-receiver devices. This series is ideal for portable or hand-held applications such as notebook or palmtop computers. The ESD tolerance of the SP3222E/3232E devices are over ±15kV for both Human Body Model and IEC1000-4-2 Air discharge test methods. The SP3222E device has a low-power shutdown mode where the devices' driver outputs and charge pumps are disabled. During shutdown, the supply current falls to less than 1µA. SELECTION TABLE MODEL SP3222 SP3232 Power Supplies +3.0V to +5.5V +3.0V to +5.5V RS-232 Drivers 2 2 RS-232 Receivers 2 2 External Components 4 4 Shutdown Yes No TTL 3-State Yes No No. of Pins 18, 20 16 Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 1 ABSOLUTE MAXIMUM RATINGS These are stress ratings only and functional operation of the device at these ratings or any other above those indicated in the operation sections of the specifications below is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect reliability and cause permanent damage to the device. VCC................................................................-0.3V to +6.0V V+ (NOTE 1)................................................-0.3V to +7.0V V- (NOTE 1)................................................+0.3V to -7.0V V+ + |V-| (NOTE 1)....................................................+13V ICC (DC VCC or GND current).................................±100mA Input Voltages TxIN, EN ................................................... -0.3V to +6.0V RxIN .......................................................................... ±15V Output Voltages TxOUT ...................................................................... ±15V RxOUT ........................................... -0.3V to (VCC + 0.3V) Short-Circuit Duration TxOUT ............................................................ Continuous Storage Temperature .............................. -65°C to +150°C Power Dissipation Per Package 20-pin SSOP (derate 9.25mW/oC above +70oC) ..... 750mW 18-pin PDIP (derate 15.2mW/oC above +70oC) .... 1220mW 18-pin SOIC (derate 15.7mW/oC above +70oC) ... 1260mW 20-pin TSSOP (derate 11.1mW/oC above +70oC) .. 890mW 16-pin SSOP (derate 9.69mW/oC above +70oC) ..... 775mW 16-pin PDIP (derate 14.3mW/oC above +70oC) .... 1150mW 16-pin Wide SOIC (derate 11.2mW/oC above +70oC) 900mW 16-pin TSSOP (derate 10.5mW/oC above +70oC) .. 850mW 16-pin nSOIC (derate 13.57mW/°C above +70°C) .. 1086mW NOTE 1: V+ and V- can have maximum magnitudes of 7V, but their absolute difference cannot exceed 13V. ELECTRICAL CHARACTERISTICS Unless otherwise noted, the following specifications apply for VCC = +3.0V to +5.0V with TAMB = TMIN to TMAX PARAMETER DC CHARACTERISTICS Supply Current Shutdown Supply Current 0.3 1.0 1.0 10 mA µA no load, TAMB = +25oC, VCC = 3.3V SHDN = GND, TAMB = +25oC, VCC = +3.3V MIN. TYP. MAX. UNITS CONDITIONS LOGIC INPUTS AND RECEIVER OUTPUTS Input Logic Threshold LOW Input Logic Threshold HIGH Input Leakage Current Output Leakage Current Output Voltage LOW Output Voltage HIGH DRIVER OUTPUTS Output Voltage Swing ± 5.0 ± 5. 4 V 3kΩ load to ground at all driver outputs, TAMB = +25oC VCC = V+ = V- = 0V, TOUT = +2V VOUT = 0V VOUT = +15V VOUT = +12V,VCC= 0V to 5.5V,drivers disabled VCC-0.6 VCC-0.1 2.0 2.4 ± 0.01 ± 0.05 ± 1. 0 ± 10 0.4 0.8 V V µA µA V V TxIN, EN, SHDN, Note 2 VCC = 3.3V, Note 2 VCC = 5.0V, Note 2 TxIN, EN, SHDN, TAMB = +25oC receivers disabled IOUT = 1.6mA IOUT = -1.0mA Output Resistance Output Short-Circuit Current Output Leakage Current 300 ± 35 ± 70 ± 60 ± 100 ± 25 Ω mA mA µA Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 2 ELECTRICAL CHARACTERISTICS Unless otherwise noted, the following specifications apply for VCC = +3.0V to +5.0V with TAMB = TMIN to TMAX. Typical Values apply at VCC = +3.3V or +5.0V and TAMB = 25oC. PARAMETER RECEIVER INPUTS Input Voltage Range Input Threshold LOW Input Threshold HIGH Input Hysteresis Input Resistance TIMING CHARACTERISTICS Maximum Data Rate Driver Propagation Delay Receiver Propagation Delay Receiver Output Enable Time Receiver Output Disable Time Driver Skew Receiver Skew Transition-Region Slew Rate 120 235 1.0 1.0 0.3 0.3 200 200 100 200 500 1000 30 kbps µs µs µs ns ns ns ns V/µs | tPHL - tPLH |, TAMB = 25oC | tPHL - tPLH | VCC = 3.3V, RL = 3KΩ, TAMB = 25oC, measurements taken from -3.0V to +3.0V or +3.0V to -3.0V RL=3kΩ, CL=1000pF, one driver switching tPHL, RL = 3KΩ, CL = 1000pF tPLH, RL = 3KΩ, CL = 1000pF tPHL, RxIN to RxOUT, CL=150pF tPLH, RxIN to RxOUT, CL=150pF 3 -15 0.6 0.8 1.2 1.5 1. 5 1.8 0.3 5 7 2.4 2.4 +15 V V V V kΩ VCC=3.3V VCC=5.0V VCC=3.3V VCC=5.0V MIN. TYP. MAX. UNITS CONDITIONS NOTE 2: Driver input hysteresis is typically 250mV. Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 3 TYPICAL PERFORMANCE CHARACTERISTICS Unless otherwise noted, the following performance characteristics apply for VCC = +3.3V, 120kbps data rates, all drivers loaded with 3kΩ, 0.1µF charge pump capacitors, and TAMB = +25°C. 6 14 12 10 Slew Rate [V/µs] Transmitter Output Voltage [V] 4 2 0 0 -2 -4 500 1000 1500 2000 Vout+ Vout- 8 6 4 2 +Slew -Slew -6 Load Capacitance [pF] 0 0 500 1000 1500 Load Capacitance [pF] 2000 2330 Figure 1. Transmitter Output Voltage VS. Load Capacitance for the SP3222 and the SP3232 Figure 2. Slew Rate VS. Load Capacitance for the SP3222 and the SP3232 50 45 40 35 Supply Current [mA] 118KHz 60KHz 10KHz 30 25 20 15 10 5 0 0 500 1000 1500 2000 2330 Load Capacitance [pF] Figure 3. Supply Current VS. Load Capacitance when Transmitting Data for the SP3222 and the SP3232 Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 4 PIN NUMBER NAME FUNCTION SP3222E DIP/SO EN C1+ V+ C1C2+ C2VT1OUT T2OUT R1IN R2IN R1OUT R2OUT T1IN T2IN GND VCC SHDN N.C. Receiver Enable. Apply logic LOW for normal operation. Apply logic HIGH to disable the receiver outputs (high-Z state). Positive terminal of the voltage doubler charge-pump capacitor. +5.5V generated by the charge pump. Negative terminal of the voltage doubler charge-pump capacitor. Positive terminal of the inverting charge-pump capacitor. Negative terminal of the inverting charge-pump capacitor. -5.5V generated by the charge pump. RS-232 driver output. RS-232 driver output. RS-232 receiver input. RS-232 receiver input. TTL/CMOS reciever output. TTL/CMOS reciever output. TTL/CMOS driver input. TTL/CMOS driver input. Ground. +3.0V to +5.5V supply voltage Shutdown Control Input. Drive HIGH for normal device operation. Drive LOW to shutdown the drivers (high-Z output) and the onboard power supply. No Connect. 1 2 3 4 5 6 7 15 8 14 9 13 10 12 11 16 17 18 SSOP/TSSOP 1 2 3 4 5 6 7 17 8 16 9 15 10 13 12 18 19 20 11, 14 SP3232E 1 2 3 4 5 6 14 7 13 8 12 9 11 10 15 16 - Table 1. Device Pin Description Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 5 EN 1 20 SHDN 19 VCC 18 GND 17 SP3222E 16 T1OUT R1IN EN 1 18 SHDN 17 VCC 16 GND 15 SP3222E 14 T1OUT R1IN C1+ 2 V+ C1C2+ C2VT2OUT R2IN 3 4 5 6 7 8 9 C1+ 2 V+ C1C2+ C2VT2OUT R2IN 3 4 5 6 7 8 9 15 R1OUT 14 N.C. 13 R1OUT 12 T1IN 11 T2IN 10 R2OUT 13 T1IN 12 T2IN 11 N.C. R2OUT 10 DIP/SO SSOP/TSSOP Figure 4. Pinout Configurations for the SP3222E C1+ 1 V+ 2 C1C2+ C2VT2OUT R2IN 3 4 5 6 7 8 SP3232E 16 VCC 15 GND 14 T1OUT 13 R1IN 12 R1OUT 11 T1IN 10 9 T2IN R2OUT Figure 5. Pinout Configuration for the SP3232E Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 6 VCC + 19 VCC V+ 3 *C3 + 0.1µF + VCC 17 VCC V+ 3 *C3 + 0.1µF C5 0.1µF 2 C1+ 0.1µF 4 C15 C2+ C5 0.1µF 2 C1+ 0.1µF 4 C15 C2+ C1 + C1 + C2 + 0.1µF 6 C213 T1IN 12 T2IN SP3222E SSOP TSSOP V- 7 C4 + 0.1µF C2 + 0.1µF SP3222E DIP/SO V- 7 C4 + 0.1µF 6 C212 T1IN 11 T2IN T1OUT T2OUT 15 8 T1OUT T2OUT 17 8 RS-232 OUTPUTS LOGIC INPUTS LOGIC INPUTS RS-232 OUTPUTS 15 R1OUT LOGIC OUTPUTS 5kΩ 10 R2OUT 5kΩ 1 EN GND 18 R1IN 16 RS-232 INPUTS LOGIC OUTPUTS 13 R1OUT 5kΩ 10 R2OUT 5kΩ 1 EN GND R1IN 14 RS-232 INPUTS R2IN 9 R2IN 9 SHDN 20 SHDN 18 *can be returned to either VCC or GND 16 *can be returned to either VCC or GND Figure 6. SP3222E Typical Operating Circuits VCC + 16 VCC V+ C5 0.1µF 1 C1+ 0.1µF 3 C14 C2+ 2 *C3 + 0.1µF C1 + SP3232E C2 + V- 6 C4 + 0.1µF 0.1µF 5 C211 T1IN 10 T2IN T1OUT T2OUT 14 7 LOGIC INPUTS RS-232 OUTPUTS 12 R1OUT LOGIC OUTPUTS 5kΩ 9 R2OUT 5kΩ R1IN 13 RS-232 INPUTS R2IN 8 GND 15 *can be returned to either VCC or GND Figure 7. SP3232E Typical Operating Circuit Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 7 DESCRIPTION The SP3222E/3232E transceivers meet the EIA/ TIA-232 and V.28/V.24 communication protocols and can be implemented in battery-powered, portable, or hand-held applications such as notebook or palmtop computers. The SP3222E/ 3232E devices all feature Sipex's proprietary on-board charge pump circuitry that generates 2 x VCC for RS-232 voltage levels from a single +3.0V to +5.5V power supply. This series is ideal for +3.3V-only systems, mixed +3.3V to +5.5V systems, or +5.0V-only systems that require true RS-232 performance. The SP3222E/ 3232E series have drivers that operate at a typical data rate of 235Kbps fully loaded. The SP3222E and SP3232E are 2-driver/2-receiver devices ideal for portable or hand-held applications. The SP3222E features a 1µA shutdown mode that reduces power consumption and extends battery life in portable systems. Its receivers remain active in shutdown mode, allowing external devices such as modems to be monitored using only 1µA supply current. THEORY OF OPERATION The SP3222E/3232E series are made up of three basic circuit blocks: 1. Drivers, 2. Receivers, and 3. the Sipex proprietary charge pump. Drivers The drivers are inverting level transmitters that convert TTL or CMOS logic levels to ±5.0V EIA/TIA-232 levels inverted relative to the input logic levels. Typically, the RS-232 output voltage swing is ±5.5V with no load and at least ±5V minimum fully loaded. The driver outputs are protected against infinite short-circuits to ground without degradation in reliability. Driver outputs will meet EIA/TIA-562 levels of ±3.7V with supply voltages as low as 2.7V. The drivers typically can operate at a data rate of 235Kbps. The drivers can guarantee a data rate of 120Kbps fully loaded with 3KΩ in parallel with 1000pF, ensuring compatibility with PC-to-PC communication software. Date: 02/24/05 The slew rate of the driver output is internally limited to a maximum of 30V/µs in order to meet the EIA standards (EIA RS-232D 2.1.7, Paragraph 5). The transition of the loaded output from HIGH to LOW also meets the monotonicity requirements of the standard. The SP3222E/3232E drivers can maintain high data rates up to 235Kbps fully loaded. Figure 8 shows a loopback test circuit used to test the RS-232 drivers. Figure 9 shows the test results of the loopback circuit with all drivers active at 120Kbps with RS-232 loads in parallel with 1000pF capacitors. Figure 10 shows the test results where one driver was active at 235Kbps and all drivers loaded with an RS-232 receiver in parallel with a 1000pF capacitor. A solid RS-232 data transmission rate of 120Kbps provides compatibility with many designs in personal computer peripherals and LAN applications. The SP3222E driver's output stages are turned off (tri-state) when the device is in shutdown mode. When the power is off, the SP3222E device permits the outputs to be driven up to ±12V. The driver's inputs do not have pull-up resistors. Designers should connect unused inputs to VCC or GND. In the shutdown mode, the supply current falls to less than 1µA, where SHDN = LOW. When the SP3222E device is shut down, the device's driver outputs are disabled (tri-stated) and the charge pumps are turned off with V+ pulled down to VCC and V- pulled to GND. The time required to exit shutdown is typically 100µs. Connect SHDN to VCC if the shutdown mode is not used. SHDN has no effect on RxOUT or RxOUTB. As they become active, the two driver outputs go to opposite RS-232 levels where one driver input is HIGH and the other LOW. Note that the drivers are enabled only when the magnitude of V- exceeds approximately 3V. SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 8 VCC + C5 0.1µF C1+ 0.1µF C1C2+ 0.1µF C2- VCC V+ C3 + 0.1µF C1 + C2 + SP3222E SP3232E VC4 + 0.1µF LOGIC INPUTS LOGIC OUTPUTS TxIN TxOUT RxOUT 5kΩ EN GND RxIN *SHDN VCC 1000pF * SP3222 only Figure 8. SP3222E/3232E Driver Loopback Test Circuit [ T ] [ T ] T1 IN 1 T T1 IN 1 T T1 OUT 2 T T R1 OUT 3 Ch1 5.00V Ch3 5.00V Ch2 5.00V M 5.00µs Ch1 0V T1 OUT 2 T T R1 OUT 3 Ch1 5.00V Ch3 5.00V Ch2 5.00V M 2.50µs Ch1 0V Figure 9. Driver Loopback Test Results at 120kbps Figure 10. Driver Loopback Test Results at 235kbps Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 9 Receivers The receivers convert EIA/TIA-232 levels to TTL or CMOS logic output levels. All receivers have an inverting tri-state output. These receiver outputs (RxOUT) are tri-stated when the enable control EN = HIGH. In the shutdown mode, the receivers can be active or inactive. EN has no effect on TxOUT. The truth table logic of the SP3222E/3232E driver and receiver outputs can be found in Table 2. Since receiver input is usually from a transmission line where long cable lengths and system interference can degrade the signal, the inputs have a typical hysteresis margin of 300mV. This ensures that the receiver is virtually immune to noisy transmission lines. Should an input be left unconnected, a 5kΩ pulldown resistor to ground will commit the output of the receiver to a HIGH state. Charge Pump The charge pump is a Sipex–patented design (5,306,954) and uses a unique approach compared to older less–efficient designs. The charge pump still requires four external capacitors, but uses a four–phase voltage shifting technique to attain symmetrical 5.5V power supplies. The internal power supply consists of a regulated dual charge pump that provides output voltages 5.5V regardless of the input voltage (VCC) over the +3.0V to +5.5V range. In most circumstances, decoupling the power supply can be achieved adequately using a 0.1µF bypass capacitor at C5 (refer to Figures 6 and 7). In applications that are sensitive to power-supply noise, decouple VCC to ground with a capacitor of the same value as charge-pump capacitor C1. Physically connect bypass capacitors as close to the IC as possible. The charge pumps operate in a discontinuous mode using an internal oscillator. If the output voltages are less than a magnitude of 5.5V, the charge pumps are enabled. If the output voltage exceed a magnitude of 5.5V, the charge pumps are disabled. This oscillator controls the four phases of the voltage shifting. A description of each phase follows. Phase 1 — VSS charge storage — During this phase of the clock cycle, the positive side of capacitors C1 and C2 are initially charged to VCC. Cl+ is then switched to GND and the charge in C1– is transferred to C2–. Since C2+ is connected to VCC, the voltage potential across capacitor C2 is now 2 times VCC. Phase 2 — VSS transfer — Phase two of the clock connects the negative terminal of C2 to the VSS storage capacitor and the positive terminal of C2 to GND. This transfers a negative generated voltage to C3. This generated voltage is regulated to a minimum voltage of -5.5V. Simultaneous with the transfer of the voltage to C3, the positive side of capacitor C1 is switched to VCC and the negative side is connected to GND. Phase 3 — VDD charge storage — The third phase of the clock is identical to the first phase — the charge transferred in C1 produces –VCC in the negative terminal of C1, which is applied to the negative side of capacitor C2. Since C2+ is at VCC, the voltage potential across C2 is 2 times VCC. SHDN 0 0 1 1 EN 0 1 0 1 TxOUT Tri-state Tri-state Active Active RxOUT Active Tri-state Active Tri-state Table 2. Truth Table Logic for Shutdown and Enable Control Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 10 Phase 4 — VDD transfer — The fourth phase of the clock connects the negative terminal of C2 to GND, and transfers this positive generated voltage across C2 to C4, the VDD storage capacitor. This voltage is regulated to +5.5V. At this voltage, the internal oscillator is disabled. Simultaneous with the transfer of the voltage to C4, the positive side of capacitor C1 is switched to VCC and the negative side is connected to GND, allowing the charge pump cycle to begin again. The charge pump cycle will continue as long as the operational conditions for the internal oscillator are present. Since both V+ and V– are separately generated from VCC; in a no–load condition V+ and V– will be symmetrical. Older charge pump approaches that generate V– from V+ will show a decrease in the magnitude of V– compared to V+ due to the inherent inefficiencies in the design. The clock rate for the charge pump typically operates at 250kHz. The external capacitors can be as low as 0.1µF with a 16V breakdown voltage rating. ESD Tolerance The S P3222E/3232E s eries incorporates ruggedized ESD cells on all driver output and receiver input pins. The ESD structure is improved over our previous family for more rugged applications and environments sensitive to electro-static discharges and associated transients. The improved ESD tolerance is at least ±15kV without damage nor latch-up. There are different methods of ESD testing applied: a) MIL-STD-883, Method 3015.7 b) IEC1000-4-2 Air-Discharge c) IEC1000-4-2 Direct Contact The Human Body Model has been the generally accepted ESD testing method for semiconductors. This method is also specified in MIL-STD883, Method 3015.7 for ESD testing. The premise of this ESD test is to simulate the human body’s Date: 02/24/05 potential to store electro-static energy and discharge it to an integrated circuit. The simulation is performed by using a test model as shown in Figure 17. This method will test the IC’s capability to withstand an ESD transient during normal handling such as in manufacturing areas where the ICs tend to be handled frequently. The IEC-1000-4-2, formerly IEC801-2, is generally used for testing ESD on equipment and systems. For system manufacturers, they must guarantee a certain amount of ESD protection since the system itself is exposed to the outside environment and human presence. The premise with IEC1000-4-2 is that the system is required to withstand an amount of static electricity when ESD is applied to points and surfaces of the equipment that are accessible to personnel during normal usage. The transceiver IC receives most of the ESD current when the ESD source is applied to the connector pins. The test circuit for IEC1000-4-2 is shown on Figure 18. There are two methods within IEC1000-4-2, the Air Discharge method and the Contact Discharge method. With the Air Discharge Method, an ESD voltage is applied to the equipment under test (EUT) through air. This simulates an electrically charged person ready to connect a cable onto the rear of the system only to find an unpleasant zap just before the person touches the back panel. The high energy potential on the person discharges through an arcing path to the rear panel of the system before he or she even touches the system. This energy, whether discharged directly or through air, is predominantly a function of the discharge current rather than the discharge voltage. Variables with an air discharge such as approach speed of the object carrying the ESD potential to the system and humidity will tend to change the discharge current. For example, the rise time of the discharge current varies with the approach speed. SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 11 VCC = +5V +5V C1 + – C4 + – + C2 + – – VDD Storage Capacitor VSS Storage Capacitor –5V –5V C3 Figure 12. Charge Pump — Phase 1 VCC = +5V C4 + – + C1 + – C2 + – – VDD Storage Capacitor VSS Storage Capacitor –10V C3 Figure 13. Charge Pump — Phase 2 [ +6V a) C2+ T ] GND 1 GND 2 b) C2- T -6V T Ch1 2.00V Ch2 2.00V M 1.00µs Ch1 5.48V Figure 14. Charge Pump Waveforms VCC = +5V +5V C1 + – C4 + – + C2 + – – VDD Storage Capacitor VSS Storage Capacitor –5V –5V C3 Figure 15. Charge Pump — Phase 3 VCC = +5V +10V C1 + – C4 + – + C2 + – – VDD Storage Capacitor VSS Storage Capacitor C3 Figure 16. Charge Pump — Phase 4 Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 12 RC RC SW1 SW1 DC Power Source RS RS SW2 SW2 CS CS Device Under Test Figure 17. ESD Test Circuit for Human Body Model The Contact Discharge Method applies the ESD current directly to the EUT. This method was devised to reduce the unpredictability of the ESD arc. The discharge current rise time is constant since the energy is directly transferred without the air-gap arc. In situations such as hand held systems, the ESD charge can be directly discharged to the equipment from a person already holding the equipment. The current is transferred on to the keypad or the serial port of the equipment directly and then travels through the PCB and finally to the IC. The circuit models in Figures 17 and 18 represent the typical ESD testing circuits used for all three methods. The CS is initially charged with the DC power supply when the first switch (SW1) is on. Now that the capacitor is charged, the second switch (SW2) is on while SW1 switches off. The voltage stored in the capacitor is then applied through RS, the current limiting resistor, onto the device under test (DUT). In ESD tests, the SW2 switch is pulsed so that the device under test receives a duration of voltage. Contact-Discharge Module RC C SW1 DC Power Source RS S RV SW2 CS S Device Under Test RS and RV add up to 330Ω for IEC1000-4-2. Figure 18. ESD Test Circuit for IEC1000-4-2 Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 13 For the Human Body Model, the current limiting resistor (RS) and the source capacitor (CS) are 1.5kΩ an 100pF, respectively. For IEC-1000-4-2, the current limiting resistor (RS) and the source capacitor (CS) are 330Ω an 150pF, respectively. The higher CS value and lower RS value in the IEC1000-4-2 model are more stringent than the Human Body Model. The larger storage capacitor injects a higher voltage to the test point when SW2 is switched on. The lower current limiting resistor increases the current charge onto the test point. 30A 15A 0A t=0ns t=30ns I➙ t➙ Figure 19. ESD Test Waveform for IEC1000-4-2 Device Pin Tested Driver Outputs Receiver Inputs Human Body Model ±15kV ±15kV Air Discharge ±15kV ±15kV IEC1000-4-2 Direct Contact ±8kV ±8kV Level 4 4 Table 3. Transceiver ESD Tolerance Levels Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 14 PACKAGE: PLASTIC SHRINK SMALL OUTLINE (SSOP) E H D A Ø e B A1 L DIMENSIONS (Inches) Minimum/Maximum (mm) A A1 B D E e H L Ø 16–PIN 0.068/0.078 (1.73/1.99) 0.002/0.008 (0.05/0.21) 0.010/0.015 (0.25/0.38) 0.239/0.249 (6.07/6.33) 0.205/0.212 (5.20/5.38) 0.0256 BSC (0.65 BSC) 0.301/0.311 (7.65/7.90) 0.022/0.037 (0.55/0.95) 0°/8° (0°/8°) 20–PIN 0.068/0.078 (1.73/1.99) 0.002/0.008 (0.05/0.21) 0.010/0.015 (0.25/0.38) 0.278/0.289 (7.07/7.33) 0.205/0.212 (5.20/5.38) 0.0256 BSC (0.65 BSC) 0.301/0.311 (7.65/7.90) 0.022/0.037 (0.55/0.95) 0°/8° (0°/8°) Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 15 PACKAGE: PLASTIC DUAL–IN–LINE (NARROW) E1 E D1 = 0.005" min. (0.127 min.) D A1 = 0.015" min. (0.381min.) A = 0.210" max. (5.334 max). A2 C Ø eA = 0.300 BSC (7.620 BSC) L e = 0.100 BSC (2.540 BSC) B1 B ALTERNATE END PINS (BOTH ENDS) DIMENSIONS (Inches) Minimum/Maximum (mm) A2 B B1 C D E E1 L Ø 16–PIN 0.115/0.195 (2.921/4.953) 0.014/0.022 (0.356/0.559) 0.045/0.070 (1.143/1.778) 0.008/0.014 (0.203/0.356) 18–PIN 0.115/0.195 (2.921/4.953) 0.014/0.022 (0.356/0.559) 0.045/0.070 (1.143/1.778) 0.008/0.014 (0.203/0.356) 0.780/0.800 0.880/0.920 (19.812/20.320) (22.352/23.368) 0.300/0.325 (7.620/8.255) 0.240/0.280 (6.096/7.112) 0.115/0.150 (2.921/3.810) 0°/ 15° (0°/15°) 0.300/0.325 (7.620/8.255) 0.240/0.280 (6.096/7.112) 0.115/0.150 (2.921/3.810) 0°/ 15° (0°/15°) Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 16 PACKAGE: PLASTIC SMALL OUTLINE (SOIC) (WIDE) E H D A Ø e B A1 L DIMENSIONS (Inches) Minimum/Maximum (mm) A A1 B D E e H L Ø 16–PIN 0.090/0.104 (2.29/2.649) 0.004/0.012 (0.102/0.300) 0.013/0.020 (0.330/0.508) 0.398/0.413 (10.10/10.49) 0.291/0.299 (7.402/7.600) 0.050 BSC (1.270 BSC) 0.394/0.419 (10.00/10.64) 0.016/0.050 (0.406/1.270) 0°/8° (0°/8°) 18–PIN 0.090/0.104 (2.29/2.649)) 0.004/0.012 (0.102/0.300) 0.013/0.020 (0.330/0.508) 0.447/0.463 (11.35/11.74) 0.291/0.299 (7.402/7.600) 0.050 BSC (1.270 BSC) 0.394/0.419 (10.00/10.64) 0.016/0.050 (0.406/1.270) 0°/8° (0°/8°) Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 17 PACKAGE: PLASTIC SMALL OUTLINE (SOIC) (NARROW) E H h x 45° D A Ø e B A1 L DIMENSIONS (Inches) Minimum/Maximum (mm) A A1 B D E e H h L Ø 16–PIN 0.053/0.069 (1.346/1.748) 0.004/0.010 (0.102/0.249) 0.013/0.020 (0.330/0.508) 0.386/0.394 (9.802/10.000) 0.150/0.157 (3.802/3.988) 0.050 BSC (1.270 BSC) 0.228/0.244 (5.801/6.198) 0.010/0.020 (0.254/0.498) 0.016/0.050 (0.406/1.270) 0°/8° (0°/8°) Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 18 DIMENSIONS in inches (mm) Minimum/Maximum Symbol D e 16 Lead 20 Lead 0.193/0.201 0.252/0.260 (4.90/5.10) (6.40/6.60) 0.026 BSC (0.65 BSC) 0.026 BSC (0.65 BSC) PACKAGE: PLASTIC THIN SMALL OUTLINE (TSSOP) e 0.126 BSC (3.2 BSC) 0.252 BSC (6.4 BSC) 1.0 OIA 0.169 (4.30) 0.177 (4.50) 0.039 (1.0) 0’-8’ 12’REF e/2 0.039 (1.0) 0.043 (1.10) Max D 0.033 (0.85) 0.037 (0.95) 0.007 (0.19) 0.012 (0.30) 0.002 (0.05) 0.006 (0.15) (θ2) 0.008 (0.20) 0.004 (0.09) Min 0.004 (0.09) Min Gage Plane 0.010 (0.25) (θ3) 1.0 REF 0.020 (0.50) 0.026 (0.75) (θ1) Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 19 ORDERING INFORMATION Model Temperature Range Package Type SP3222ECA ............................................. 0˚C to +70˚C .......................................... 20-Pin SSOP SP3222ECA/TR ....................................... 0˚C to +70˚C .......................................... 20-Pin SSOP SP3222ECP ............................................. 0˚C to +70˚C ............................................ 18-Pin PDIP SP3222ECT ............................................. 0˚C to +70˚C ........................................ 18-Pin WSOIC SP3222ECT/TR ....................................... 0˚C to +70˚C ........................................ 18-Pin WSOIC SP3222ECY ............................................. 0˚C to +70˚C ........................................ 20-Pin TSSOP SP3222ECY/TR ....................................... 0˚C to +70˚C ........................................ 20-Pin TSSOP SP3222EEA ............................................ -40˚C to +85˚C ........................................ 20-Pin SSOP SP3222EEA/TR ...................................... -40˚C to +85˚C ........................................ 20-Pin SSOP SP3222EEP ............................................ -40˚C to +85˚C .......................................... 18-Pin PDIP SP3222EET ............................................ -40˚C to +85˚C ...................................... 18-Pin WSOIC SP3222EET/TR ...................................... -40˚C to +85˚C ...................................... 18-Pin WSOIC SP3222EEY ............................................ -40˚C to +85˚C ...................................... 20-Pin TSSOP SP3222EEY/TR ...................................... -40˚C to +85˚C ...................................... 20-Pin TSSOP SP3232ECA ............................................. 0˚C to +70˚C .......................................... 16-Pin SSOP SP3232ECA/TR ....................................... 0˚C to +70˚C .......................................... 16-Pin SSOP SP3232ECP ............................................. 0˚C to +70˚C ............................................ 16-Pin PDIP SP3232ECT ............................................. 0˚C to +70˚C ........................................ 16-Pin WSOIC SP3232ECT/TR ....................................... 0˚C to +70˚C ........................................ 16-Pin WSOIC SP3232ECN ............................................. 0˚C to +70˚C ......................................... 16-Pin nSOIC SP3232ECN/TR ....................................... 0˚C to +70˚C ......................................... 16-Pin nSOIC SP3232ECY ............................................. 0˚C to +70˚C ........................................ 16-Pin TSSOP SP3232ECY/TR ....................................... 0˚C to +70˚C ........................................ 16-Pin TSSOP SP3232EEA ............................................ -40˚C to +85˚C ........................................ 16-Pin SSOP SP3232EEA/TR ...................................... -40˚C to +85˚C ........................................ 16-Pin SSOP SP3232EEP ............................................ -40˚C to +85˚C .......................................... 16-Pin PDIP SP3232EET ............................................ -40˚C to +85˚C ...................................... 16-Pin WSOIC SP3232EET/TR ...................................... -40˚C to +85˚C ...................................... 16-Pin WSOIC SP3232EEN ............................................ -40˚C to +85˚C ....................................... 16-Pin nSOIC SP3232EEN/TR ...................................... -40˚C to +85˚C ....................................... 16-Pin nSOIC SP3232EEY ............................................ -40˚C to +85˚C ...................................... 16-Pin TSSOP SP3232EEY/TR ...................................... -40˚C to +85˚C ...................................... 16-Pin TSSOP Available in lead free packaging. To order add “-L” suffix to part number. Example: SP3232EEN/TR = standard; SP3232EEN-L/TR = lead free /TR = Tape and Reel Pack quantity is 1,500 for SSOP, TSSOP or WSOIC and 2,500 for NSOIC. CLICK HERE TO ORDER SAMPLES Corporation ANALOG EXCELLENCE Sipex Corporation Headquarters and Sales Office 233 South Hillview Drive Milpitas, CA 95035 TEL: (408) 934-7500 FAX: (408) 935-7600 Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the application or use of any product or circuit described hereing; neither does it convey any license under its patent rights nor the rights of others. Date: 02/24/05 SP3222E, SP3232E True +3.0 to +5.0V RS-232 Transceivers © Copyright 2005 Sipex Corporation 20
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SP3222EEA-L/TR
  •  国内价格
  • 1+7.714
  • 30+7.424
  • 100+6.844
  • 500+6.264
  • 1000+5.974

库存:140