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| TK15328 Audio Analog Switch FEATURES s s s s s s Wide Operating Voltage Range (2 to 7 V) Low Distortion (typ. 0.003%) Wide Dynamic Range (typ. 6 VP-P) Low Output Impedance (typ. 20 ) Low Switching Noise (typ. 3 mV) Output Parallel Connection Possible APPLICATIONS s Audio Systems s Radio Cassettes DESCRIPTION The TK15328M is an Analog Switch IC that was developed for audio frequency. Function is to select one output from two inputs, and has floating position too. The channel can be changed by two control levels and in a device that includes two circuits. The TK15328M has a dual power supply and the input bias is direct coupling at GND level. Because the distortion is very low, the TK15328M fits various signals switching. It is best suited for Hi-Fi devices. Operating voltage is wide, the circuit plan is simple. The TK15328M is available in a small plastic surface mount package (SSOP-12). TK15326 VCC Bch OUT 1ch-in Ach 1KEY GND VEE 11 Bch 10 OUT 9 8 7 Ach 2 KEY NC 2ch-in BLOCK DIAGRAM VCC Ach + - 1 ch out 1ch-in 2 ch out 1KEY Bch + - ORDERING INFORMATION Ach + - Logic 2KEY TK15328M Tape/Reel Code 2ch-in Bch + - GND VEE TAPE/REEL CODE TL: Tape Left June 1999 TOKO, Inc. Page 1 TK15328 ABSOLUTE MAXIMUM RATINGS Supply Voltage ...................................................... 7.5 V Power Dissipation (Note 5) ................................ 350 mW Storage Temperature Range ................... -55 to +150 C Operating Temperature Range ...................-20 to +75 C CONTROL SECTION Input Voltage ................................... -0.3 V to VCC + 0.3 V ANALOG SWITCH SECTION Signal Input Voltage ........................ VEE - 0.3 to VCC + 0.3 Signal Output Current ............................................. 3 mA Operating Voltage Range ............................... 2 to 7 V Maximum Input Frequency .................................. 100 kHz TK15328M ELECTRICAL CHARACTERISTICS Test conditions: VCC = 4 V, TA = 25 C, unless otherwise specified. SYMBOL ICC PARAMETER Supply Current TEST CONDITIONS MIN TYP 3.2 MAX 5.2 UNITS mA KEY CONTROL SECTION VIL VIH ZIN Input Voltage Low Level Input Voltage High Level Input Impedance Note 1 -0.3 1.8 50 +0.8 VCC + 0.3 V V k ANALOG SWITCH SECTION THD NL ISO SE P DYN GVA Vcent Vcent IIN ZOUT Total Harmonic Distortion Residual Noise Isolation Separation Maximum Input Signal Level Voltage Gain Input-Output Terminal Voltage Output Terminal Voltage Difference Input Bias Current Output Impedance VIN = 1 Vrms, f = 1 kHz Note 2 VIN = 1 Vrms, F = 10 kHz, Note 3 VIN = 1 Vrms, f = 10 kHz, Note 3 f = 1 kHz, THD = 0.1% f = ~20 kHz GND Bias Between same channel Note 4 DC Impedance - 0.2 2.0 0 0 3 0.5 20 VCC 0.003 0.006 10 -75 -80 % Vrms dB dB Vrms dB +0.2 13 V mV A Note 1: The KEY input equivalent circuit is shown in Figure A. When the control pin is open, it is outputted low level. The TK15328 is controlled by two values, and the function table is described in the block diagram. Note 2: The specification means a value as measurement-input terminal connects to ground through a capacitor. Note 3: ISO is a cross talk between A channel and B channel, SEP is a cross talk between 1 channel and 2 channel. The specification means a value as measurement-input terminal connects to ground through 10 k resistor and capacitor. Note 4: Input equivalent circuit is shown in Figure B. The standard application of TK15328M is the direct connecting with the GND bias. When connecting a capacitor, then to supply a bias voltage from GND to input be any resistor is necessary. Note 5: Power dissipation is 350 mW when mounted as recommended. Derate at 3.0 mW/C for operation above 25C. Input Key Logic Input VEE Figure A Figure B Page 2 June 1999 TOKO, Inc. TK15328 TEST CIRCUITS AND METHODS SW6 VCC SW3 50 k SW7 SW9 SW8 SW4 50 k 33 F + SW2 1 kHz 1 Vrms or 2 Vrms 10 kHz 1 Vrms + 10 F SW5 + 10 F SW1 L H SW1 L H ~ ~ 10 k V ~ V _ THD + 33 F VEE 1: 2: 3: 4: The above condition represents 1ch. The above conditions distortion rate of 1-Ach and dynamic range measurement. SW5 is for residual noise measurement. SW8 is for cross talk (ISO or SEP) measurement. SUPPLY CURRENT (FIGURE 1) This current is a consumption current with a nonloading condition. 1) Bias supply to Pins 2,4,9,11. (This condition is the same with other measurements, omitted from the next for simplicity) 2) Contact Pin 5 to VCC, Pin 8 is low level or open. 2) Measure the inflow current to Pin 1 from VCC. This current is the supply current. CONTROL LOW/HIGH LEVEL (FIGURE 2) This level is to measure the threshold level. 1) Input, the VCC to Pin 1 and input VEE to Pin 12. (This condition is the same with other measurements, omitted from the next for simplicity) 2) Input to Pin 4 with sine wave (f = 1 kHz, VIN = 1 Vrms). 3) Connect an oscilloscope to Pin 3. 4) Pin 8 is low level or the open, and elevate Pin 5 voltage gradually from 0 V until the sine wave appears at the oscilloscope. This voltage is the threshold level when the wave appears. VCC + VCC A 50 K 50 K 50 K 50 K + ~ VEE Cont. + VEE Figure 1 June 1999 TOKO, Inc. Figure 2 Page 3 TK15328 TEST CIRCUITS AND METHODS (CONT.) CONTROL INPUT IMPEDANCE (FIGURE 3) This is the input resistance of the control terminal. 1) Measure the inflow current from VCC to Pin 5. 2) Calculate: IMP = VCC / Inflow Current This resistance is the input impedance. VCC + + VCC + VEE Figure 4 + + VEE Figure 3 VOLTAGE GAIN (FIGURE 5) This is the output level against input level. 1) Connect VCC to Pin 5, Pin 8 is in the open condition, or low level. 2) Connect AC volt meters to Pin 4 and Pin 3. (Using the same type meter is best) 3) Input a sine wave (f = max. 20 kHz, 1 Vrms) to Pin 4. 4) Measure the level of Pin 4 and name this V1. 5) Measure the level of Pin 3 and name this V2. 6) Calculate Gain = 20 Log (( |V2 - V1| )/V1) V1 TOTAL HARMONIC DISTORTION (FIGURE 4) Use the lower distortion oscillator for this measurement because distortion of the TK15328 is very low. 1) Connect VCC to Pin 5, Pin 8 is in the open condition, or low level. 2) Connect a distortion analyzer to Pin 3. 3) Input the sine wave (1 kHz, 1 Vrms) to Pin 4. 4) Measure the distortion of Pin 3. This value is the distortion of 1-Ach. 5) Next reverse condition at Pin 5 and Pin 8. 6) Input the same sine wave to Pin 2. 7) Measure in the same way. This value is the distortion of 1-Bch. Page 4 June 1999 TOKO, Inc. TK15328 TEST CIRCUITS AND METHODS (CONT.) VCC VCC + + + + + + VEE + VEE Figure 5 Figure 6 MAXIMUM INPUT LEVEL (FIGURE 6) This measurement measures at output side. 1) Connect VCC to Pin 5, Pin 8 is in the open condition, or low level. 2) Connect a distortion analyzer and an AC volt meter to Pin 3. 3) Input a sine wave (1 kHz) to Pin 4 and elevate the voltage gradually until the distortion gets to 0.1%. 4) When the distortion amounts to 0.1%, stop elevating and measure the AC level of Pin 3. This value is the maximum input level of 1-Ach. 5) Next, reverse conditions at Pin 5 and Pin 8. 6) Input the same sine wave to Pin 2. 7) Measure in the same way. This value is the maximum input level of 1-Bch. RESIDUAL NOISE (FIGURE 7) This value is not S/N ratio. This is a noise which occurs from the device itself. 1) Connect VCC to Pin 5, Pin 8 is the open condition, or low level. 2) Connect an AC volt meter to Pin 3. 3) Connect a capacitor from Pin 4 to GND. 4) Measure AC voltage of Pin 3. This value is the noise of 1-Ach. If the influence of noise from outside exists, use optional filters. 5) Next, reverse conditions at Pin 5 and Pin 8. 6) Connect to GND through a capacitor from Pin 2. 7) Measure in the same way. This value is the noise level of 1-Bch. June 1999 TOKO, Inc. Page 5 TK15328 TEST CIRCUITS AND METHODS (CONT.) VCC VCC + 10 K + + + + + VEE + VEE Figure 7 Figure 8 ISOLATION (FIGURE 8) This is the cross talk between Ach and Bch. 1) Connect VCC to Pin 8, Pin 5 is in the open condition, or low level. 2) Connect AC volt meters to Pin 4 and Pin 3. 3) Connect a capacitor and a resistance to GND from Pin 2. 4) Input a sine wave (10 kHz, 1 Vrms) to Pin 4. 5) Measure the level of Pin 4 and name this V4. 6) Measure the level of Pin 3 and name this V3. 7) Calculate: ISO = 20 Log (V3 / V4) This value is the isolation to Bch from Ach. 8) Next, reverse conditions at Pin 5 and Pin 8. 9) Change line of Pin 2 and Pin 4. 10) Input the same sine wave to Pin 2. 11) Measure and calculate in the same way. This value is the isolation to Ach from Bch. SEPARATION (FIGURE 9) This is the cross talk between 1ch and 2ch. 1) Connect either Pin 5 or Pin 8 to VCC; one pin is in the open condition, or low level. 2) Connect AC volt meters to Pin 4 (or Pin 2) and Pin 10. 3) Connect Pin 9 and Pin 11 to GND through capacitors and a resistance. 4) Input a sine wave (10 kHz, 1 Vrms) to Pin 2 and Pin 4. 5) Measure the level of Pin 4 and name this V5. 6) Measure the level of Pin 10 and name this V6. 7) Calculate: SEP = 20 Log (V6 / V5) This value is the separation to 2ch from 1ch. Page 6 June 1999 TOKO, Inc. TK15328 TEST CIRCUITS AND METHODS (CONT.) VCC VCC + I/O TERMINAL VOLTAGE (FIGURE 10) This is the DC voltage of input and output. Because the input and the output are nearly equal, only the output is measured. 1) Connect VCC to Pin 5, Pin 8 is in the open condition, or low level. 2) Connect a DC volt meter to Pin 3 and measure. This value is the terminal voltage of 1-Ach. 3) Next, reverse conditions at Pin 5 and Pin 8. 4) Measure in the same way. This value is the terminal voltage of 1-Bch. June 1999 TOKO, Inc. + + + + 10 K + + VEE + VEE Figure 9 Figure 10 OUTPUT TERMINAL DIFFERENCE This is the DC output voltage difference between Ach and Bch. This is calculated by using values measured at the I/O Terminal Voltage. Vcent = | (1 - Ach value) - (1 - Bch value) | This value is the voltage difference of 1ch. Page 7 TK15328 TYPICAL PERFORMANCE CHARACTERISTICS VCC = 8 V, TA = 25 C, unless otherwise specified. TOTAL HARMONIC DISTORTION vs. FREQUENCY 0.1 SUPPLY CURRENT VS. SUPPLY VOLTAGE 5 4 ICC (mA) 3 2 1 0 0 0.001 0.1 TOTAL HARMONIC DISTORTION vs. LOAD RESISTANCE 0.1 THD (%) THD (%) 0.01 0.01 1 2 3 4 5 6 7 8 1 f (kHz) 10 100 0.001 0.1 1 RL (k) 10 100 VCC (V) DYNAMIC RANGE vs. SUPPLY VOLTAGE 5 2 LEVEL (Vrms) DYNAMIC RANGE vs. LOAD RESISTANCE -60 -70 LEVEL (dB) ISOLATION vs. FREQUENCY 4 LEVEL (Vrms) 3 2 1 0 0 -80 -90 -100 1 1 2 3 4 5 VCC (V) 6 7 8 0 0.1 1 RL (k) 10 100 -110 0.1 1 f (kHz) 10 100 SEPARATION vs. FREQUENCY -60 -70 1.5 CONTROL THRESHOLD VS. TEMPERATURE VOLTAGE GAIN VS. TEMPERATURE +.1 LEVEL (dB) LEVEL (V) -80 -90 -100 -110 0.1 1 GVA (dB) -20 0 20 40 60 80 0 0.5 -.1 0 1 f (kHz) 10 100 -20 0 20 40 60 80 TA (C) TA (C) Page 8 June 1999 TOKO, Inc. TK15328 TYPICAL PERFORMANCE CHARACTERISTICS (CONT.) VCC = 8 V, TA = 25 C, unless otherwise specified. OUTPUT DIFFERENCE VS. TEMPERATURE 1.2 6 LEVEL (Vrms) LEVEL (mV) 3 CURRENT (A) 1.0 .8 .6 .4 .2 0 -20 0 20 40 60 80 TA (C) 0 -20 0 20 40 60 80 TA (C) 0 -20 0 20 40 60 80 TA (C) RESIDUAL NOISE VS. TEMPERATURE INPUT BIAS CURRENT VS. TEMPERATURE 4 2 2 1 TERMINAL VOLTAGE AND CIRCUIT Condition: VCC = +4 V, VEE = -4 V. PIN NO. 1 2 4 9 11 ASSIGNMENT VCC IN A, IN B Input: Open Input: 0 V 3 10 OUT 100 DC VOLTAGE +4 V CIRCUIT/FUNCTION +Supply Voltage Pin Floating 0V Signal Input Pin Input: Open Input: 0 V -3.3 V 0V Signal Output Pin 5 8 KEY 0V 50 K Control Pin 6 7 12 GND NC VEE 0V Floating -4 V Ground Pin No Contact Pin -Supply Voltage Pin June 1999 TOKO, Inc. Page 9 TK15328 APPLICATION INFORMATION VCC VEE 33 F + 2Ain KEY INPUT CIRCUIT Figure 11 is an equivalence circuit of key inputs. 1ch and 2ch does at the same time action by two control keys. If two keys are low level or high level at the same time then the output is a floating condition. 1Ain 33 F + 10 F + 11 10 9 8 10 F + RL RL Key in to Logic 1Key 1Bin 7 2Key 2 Bin Figure 11 SWITCHING TIME This time is the signal change response time compared to the control key input signal. Figure 12 illustrates the timimg chart. T = 2 s typically. Figure 13 CROSS TALK (ISOLATION AND SEPARATION) Figure 14 is an example of a layout pattern. As the TK15328M is a direct coupling type, the influence by applications is not almost. But, if it is coupled at the capacitor, by high impedance at input, capacitors acccomplishes the antenna action each other. Then in case its parts are bigger, and the space between capacitors is too narrow, cross talk will increase. Therefore, when designing the print circuit pattern, separate the input capacitors as far as possible and use smaller parts. (e.g., surface mount type) 2AIN VCC GND VEE 2BIN Bch (Ach) Key in SW out 50% t Ach (Bch) Figure 12 APPLICATION Figure 13 illustrates an example of a typical application. The standard application is to use direct coupling at GND level at the inputs and outputs of the TK15328M. For characteristics of distortion and dynamic range versus RL, refer to the graphs in the Typical Performance Characteristics. The TK15328M can be used at the capacitor coupling too, but then the bias supply is necessary from the GND level. 1OUT 2OUT 1AIN 1KEY 2KEY 1BIN Figure 14 Page 10 June 1999 TOKO, Inc. TK15328 APPLICATION INFORMATION (CONT.) OUTPUT TERMINAL VOLTAGE DIFFERENCE This parameter is the output voltage difference between Ach and Bch, and appears when the channel changes from Ach to Bch, or changes to the reverse. Generally, this is called Switching Noise or Pop Noise. If this value is big and if this noise is amplified by the final amplifier and is outputted by the speakers, then it appears as a Shock Sound. Output terminal voltage difference of the TK15326M is a value that adds the internal bias difference and the off-set voltage difference. The value of the TK15326M is very small; its maximum value is 3 mV. So almost the output bias difference will be decided by the supply bias difference. Toko can offer the "Muting IC" if users wish to mute Switching Noise. DIRECT TOUCH The signal input terminals: Internal circuits are operated by constant current circuit, even if VCC or GND is contacted, damage does not occur. The signal output terminal: Outflow or inflow current is decided by ability of final transistor, but protection circuit is not attached. If GND or VCC are contacted damage may occur. Pay attention to long time contact. Do not supply over the maximum rating. Referenced to GND, do not provide to all terminals over VCC +0.3 V or -0.3 V. DC SIGNAL INPUT The output of the TK15326M has a saturation voltage (both VCC and VEE sides about 1.0 V); accordingly the use of a DC signal is not recommend (e.g., the pulse signal etc.) NC TERMINAL NC terminals are not wired inside IC by bonding wire. NC terminals are not tested so do not connect at outside. June 1999 TOKO, Inc. Page 11 TK15328 PACKAGE OUTLINE Marking Information 0.4 SSOP-12 TK15328M 328 Marking 12 7 e1 5.4 AAA 4.4 1.2 YYY e 0.8 Recommended Mount Pad 1 Lot. No. 6 1.7 max 1.4 0.5 0 ~ 10 5.0 0 ~ 0.2 +0.15 0.3 -0.05 e 0.8 0.1 6.0 0.10 M + 0.3 Dimensions are shown in millimeters Tolerance: x.x = 0.2 mm (unless otherwise specified) Toko America, Inc. Headquarters 1250 Feehanville Drive, Mount Prospect, Illinois 60056 Tel: (847) 297-0070 Fax: (847) 699-7864 TOKO AMERICA REGIONAL OFFICES Midwest Regional Office Toko America, Inc. 1250 Feehanville Drive Mount Prospect, IL 60056 Tel: (847) 297-0070 Fax: (847) 699-7864 Western Regional Office Toko America, Inc. 2480 North First Street , Suite 260 San Jose, CA 95131 Tel: (408) 432-8281 Fax: (408) 943-9790 Eastern Regional Office Toko America, Inc. 107 Mill Plain Road Danbury, CT 06811 Tel: (203) 748-6871 Fax: (203) 797-1223 Semiconductor Technical Support Toko Design Center 4755 Forge Road Colorado Springs, CO 80907 Tel: (719) 528-2200 Fax: (719) 528-2375 Visit our Internet site at http://www.tokoam.com The information furnished by TOKO, Inc. is believed to be accurate and reliable. However, TOKO reserves the right to make changes or improvements in the design, specification or manufacture of its products without further notice. TOKO does not assume any liability arising from the application or use of any product or circuit described herein, nor for any infringements of patents or other rights of third parties which may result from the use of its products. No license is granted by implication or otherwise under any patent or patent rights of TOKO, Inc. Page 12 (c) 1999 Toko, Inc. All Rights Reserved IC-119-TK119xx 0798O0.0K 0.15 +0.15 -0.15 June 1999 TOKO, Inc. Printed in the USA |
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