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MIC5400 Micrel MIC5400 Dual, 8-Output, 14-Bit LED Video Display Driver General Description The MIC5400 consists of 2 banks of 8 LED driver outputs, each output capable of sinking up to 30mA. Each bank is intended to drive 8 LED pixels of the same color. Most applications will use the MIC5400 to drive pixel clusters of 4 LEDs (RRGB.) Typically two red LEDs are used for every one green and blue to compensate for red LED brightness. A single external resistor sets maximum drive current. Use of an external resistor allows different color LED banks to be biased to the same intensity. Brightness control is digitally programmed through the serial interface. Coarse Brightness Control is determined by two 4-bit DACs, one for each driver bank, limiting the full-scale output to a fraction of the maximum value. Additionally, each output has Fine Brightness Control using 10-bit resolution PWM. Groups of drivers can be cascaded in Daisy Chain fashion. Open circuit output faults are detected and can be read back from the internal Status register. Features * 2 banks of 8 outputs * Output characteristics: * Current sink: 30mA - Programmable brightness control * Coarse: 4-bit resolution DAC * Fine: 10-bit resolution PWM - Resistor sets maximum LED current to compensate variation in LEDs - Current limit on each output * Full protection: - Over-temperature shutdown - Watchdog disables output under fault condition - Power-on reset (all LEDs Off) - Soft-start on power up and watchdog recovery - Output open fault detection with status register readback * Output transitions are staggered to minimize supply transients Applications * Outdoor video screen * Large LED display Ordering Information Part Number MIC5400BWM MIC5400YWM Junction Temp. Range -40C to +85C -40C to +85C Package 28-Pin Wide SOIC 28-Pin Wide SOIC Typical Application RSC BCP69 MIC5400 VDDA RSET Output A SHFTCLK SHIFTIN SHIFTOUT LOAD BD_A Logic Control and SRegister Output B VDD 0.01F VDD VDDB BD_B RSC 2.2F 3301/2 BCP69 3301/2 2.2F Micrel, Inc. * 1849 Fortune Drive * San Jose, CA 95131 * USA * tel + 1 (408) 944-0800 * fax + 1 (408) 944-0970 * http://www.micrel.com January 2005 1 MIC5400 MIC5400 Micrel Pin Configuration A4 1 A3 2 A2 3 A1 4 LOAD 5 SHFTCLK 6 VDD 7 GND 8 SHIFTIN 9 SHIFTOUT 10 B1 11 B2 12 B3 13 B4 14 28 A5 27 A6 26 A7 25 A8 24 VDDA 23 BD_A 22 GND 21 IREF 20 BD_B 19 VDDB 18 B8 17 B7 16 B6 15 B5 28-Lead SOIC Pin Description Pin Number Pin 1,2,3,4 5 Pin Name Name A4,A3,A2,A1 LOAD Pin Function Function Current Sink pins to be connected to LED cathodes If this pin is Low, the device acts as a shift register. When this pin is High, only the first falling edge of the clock transfers data from the Shift-Register to the Parallel Register. The next rising edge transfers data from the Status Register to the Shift Register Shift-register Clock Input Positive Supply Voltage Ground Shift-register Data Input Shift-register Data Output Current Sink pins to be connected to LED cathodes Current Sink pins to be connected to LED cathodes Analog Power source pins which provide current sense points for Channel A and Channel B PNP emitter currents, independently. Base Drive Outputs for external PNP transistors. Feedback Loop compensation requires one external capacitor at each PNP transistor collector. Reference current output. Must be connected to an external resistor to set the maximum current for the current sink outputs. Base Drive Outputs for external PNP transistors. Feedback Loop compensation requires one external capacitor at each PNP transistor collector. Analog Power source pins which provide current sense points for Channel A and Channel B PNP emitter currents, independently. Current Sink pins to be connected to LED cathodes 6 7 8,22 9 10 11,12,13,14 15,16,17,18 19 20 21 23 24 25,26,27,28 SHFTCLK VDD GND SHIFTIN SHIFTOUT B1,B2,B3,B4 B5,B6,B7,B8 VDDB BD_B REF BD_A VDDA A8,A7,A6,A5 MIC5400 2 January 2005 MIC5400 Micrel Absolute Maximum Ratings (Note 1) Supply Voltage .............................................................. +7V Input Voltage ....................................... -0.3V to VCC + 0.3V Base Drive Voltage ....................................................... +7V Output Sink Current (per output) ................................ 35mA Lead Temperature (soldering, 5 sec) ........................ 260C Junction Temperature (TJ)(max) ............................... 125C Operating Ratings (Note 2) Supply Voltage (VCC) ................................ +4.75V to +5.5V Junction Temperature (TJ) ....................... -40C to +125C Package Thermal Resistance SOIC (JC) .......................................................... 28C/W SOIC (JA) ......................................................... 100C/W DC Electrical Characteristics VDD = 4.75V to 5.5 V, TA = 25C, bold values indicate -40C TA +85C. RBIAS = 500. Applies to all channels unless noted. Symbol IOUT IOUT IOUT(OFF) IDD IB VREF VIH VIL VOH VOL TSHUTDOWN Parameter Output Sink Current Output Current Matching Output Off Leakage Supply Current PNP Base Drive Current Reference Output Voltage Logic 1 Input Threshold Logic 0 Input Threshold Logic 1 Output Level Logic 0 Output Level Thermal Shutdown Temperature ILOAD = 1mA ILOAD = 1mA 165 2.4 0.4 VOUT = 5V VDD = 5.5V VBD = 4V IREF = -4mA -1 0 7 1.9 2.2 0.8 Condition Min 26 Typ Max 35 7 1 2 50 2.1 Units mA % A mA mA V V V V V C AC Electrical Characteristics VDD = 4.75V to 5.5V, TA = 25C, bold values indicate -40C TA +85C. RBIAS = 500. Applies to all channels unless noted Symbol Parameter Conditions Min Typ Max Units fSHIFT tSET-DATA tHOLD-DATA tSET-LOAD tHOLD-LOAD IOUT(tr) IOUT(ttf) tD-SHIFT tr,f-OUT tWD-TIMEOUT tr,f[in] Note 1. Note 2. Note 3. Note 4. Note 5. Shift Frequency Set Up Time for Data In Hold Time for Data In Set Up Time for Load Hold Time for Load Rise Time IOUT Fall Time IOUT Clock to Shift Out Delay Shift Out Rise and Fall Time Watch Dog Timeout Delay Logic Input Rise and Fall Times Exceeding the absolute maximum rating may damage the device. The device is not guaranteed to function outside its operating rating. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5k in series with 100pF. Test circuit shown in Figure 1. Guaranteed by design; not production tested. 15 Note 5 Note 5 Note 5 Note 5 Note 4, 5 Note 4, 5 Rise and Fall, 50% CLOAD = 30pF, Note 5 10% to 90%; CLOAD =30pF, Note 5 No Shiftclock 25 7 13 20 13 125 50 23 10 200 10 MHz ns ns ns ns ns ns ns ns s ns January 2005 3 MIC5400 MIC5400 Micrel Test Circuit VDD = 5V Controller Device Under Test OUTN 75 VOUT to FET Probe (C < 1.5pF) Figure 1. AC Output Test Circuit Timing Diagrams SHFTCLK LOAD Control Register Contents DN-1 DN Shift Register Contents Shifting DN DN SN Shifting Status Register Contents SN SN SN SN+1 Figure 2. MIC5400 Timing Diagram Linearity Typical Global Full Scale Linearity (any output) 45 40 35 IOUT ( mA ) Linear Operating Region (Recommended) 30 25 20 15 10 TJ = 25 Non-Linear Operation 5 1.5 2 2.5 3 3.5 4 4.5 5 5.5 IREF (mA) Figure 3. Typical Global Full Scale Linearity MIC5400 4 January 2005 MIC5400 Micrel Functional Diagram PWM Select (3 Bits) PWM Select Select 1 of 8 in Bank A/B PWM 1 PWM 2 PWM 3 PWM 4 PWM 5 Out 1A Out 2A Out 3A Out 4A Out 5A Out 6A Out 7A Out 8A PWM Data A (10 Bits) PWM Data B (10 Bits) Watchdog Enable (1 Bits) Data and Control Register (36 bits) DAC A (4 Bits) DAC B (4 Bits) Divisor (4 Bits) IREF A 2X4-bit Brightness DAC PWM 6 PWM 7 PWM 8 IREF B Status A (8 Bits) Status B (8 Bits) PWM 1 Watchdog Status (1 Bits) Out 1B Out 2B Out 3B Out 4B Out 5B Out 6B Out 7B Out 8B Status Register (36 bits) Thermal Status (1 Bits) Mask Rev. (3 Bits) Fixed Pattern (15 Bits) PWM 2 PWM 3 PWM 4 PWM 5 PWM 6 PWM 7 SHIFTIN 36 Bit Shift Register SHIFTOUT PWM 8 SHFTCLK LOAD MIC5400 Functional Diagram January 2005 5 MIC5400 MIC5400 Micrel Address 3 Bits Q1 to Q3 [Q1 = LSB] Data A 10 bits Q4 to Q13 Data B 10 Bits Q14 to Q23 Watchdog 1 Bit Q24 Divisor 4 Bits Q25 to Q28 DAC B 4 Bits Q29 to Q32 DAC B 4 Bits Q33 to Q36 Bit 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 Description Address bit 1 Address Bit 2 Address Bit 3 Data A Bit 1 Data A Bit 2 Data A Bit 3 Data A Bit 4 Data A Bit 5 Data A Bit 6 Data A Bit 7 Data A Bit 8 Data A Bit 9 Data A Bit 10 Data B Bit 1 Data B Bit 2 Data B Bit 3 Data B Bit 4 Data B Bit 5 Data B Bit 6 Data B Bit 7 Data B Bit 8 Data B Bit 9 Data B Bit 10 Watchdog Bit [Disable = 1] Divisor Bit 1 Divisor Bit 2 Divisor Bit 3 Divisor Bit 4 DAC A Bit 1 DAC A Bit 2 DAC A Bit 3 DAC A Bit 4 DAC B Bit 1 DAC B Bit 2 DAC B Bit 3 DAC B Bit 4 Table 1. Shift Register Data Format MIC5400 6 January 2005 MIC5400 Micrel Status A [1 = Open Circuit] Status B [1 = Open Circuit] Watchdog [1 = Timeout] Thermal [1 = Overtemp] Mask Revision 3 Bits D19 to D21 Alternating Bits 15 Fixed Bits D22 to D36 8 Bits D1-D8 8 Bits D9-D16 Bit 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 1 Bit D17 1 Bit D18 Description Status A - Bit 1 (Output Open Circuit = 0) Status A - Bit 2 (Output Open Circuit = 0) Status A - Bit 3 (Output Open Circuit = 0) Status A - Bit 4 (Output Open Circuit = 0) Status A - Bit 5 (Output Open Circuit = 0) Status A - Bit 6 (Output Open Circuit = 0) Status A - Bit 7 (Output Open Circuit = 0) Status A - Bit 8 (Output Open Circuit = 0) Status B - Bit 1 (Output Open Circuit = 0) Status B - Bit 2 (Output Open Circuit = 0) Status B - Bit 3 (Output Open Circuit = 0) Status B - Bit 4 (Output Open Circuit = 0) Status B - Bit 5 (Output Open Circuit = 0) Status B - Bit 6 (Output Open Circuit = 0) Status B - Bit 7 (Output Open Circuit = 0) Status B - Bit 8 (Output Open Circuit = 0) Watchdog Status [0 = Normal, 1 = Time Out] Thermal Status [0 = Normal, 1 = Overtemp] Mask Revision Bit 1 Mask Revision Bit 2 Mask Revision Bit 3 0 [Fixed Pattern Filler Bits] 1 0 1 0 1 0 1 0 1 0 1 0 1 0 Table 2. Status Word Format January 2005 7 MIC5400 MIC5400 Applications Information Output Current Drive The MIC5400 includes several ways to program LED output current. These output current controls are superimposed and have an additive effect on LED output current as follows: Global Full Scale Current Limit: This function sets the Global Full Scale (GFS) current at each of the outputs. The GFS value current is about 8.1 times ISET. ISET is the current through the single resistor, RBIAS, connected from VREF to Ground. VREF is regulated to 2V (nominal) so: Micrel As a result of the 25 microsecond minimum watchdog timeout delay, the lower limit of clock frequency is 40kHz. The thermal shutdown typically activates if the die temperature exceeds 165C. Thermal shutdown shuts off all outputs and sets the Thermal status bit to logic 1 if overtemperature is detected. Thermal status is read back from status word bit D18. External PNP Transistors The external PNPs have a dual role. As part of a voltage regulator loop they aid in limiting package power dissipation. Sensing current in the PNP emitters also allows setting an overall limit to the current available to one bank of 8 LEDs. Power dissipation: The regulator loop controls the voltage at the LED drive output to limit power dissipation. The outputs are typically controlled to 1.1V. A 2.2 F capactor is required at the collector of each PNP for frequency compensation. PNP Current Limit The current limit of the external PNP can be set by conncting a sense resistor RCS from VDD to VDDA and VDDB respectively. The current limit is: 48mV ILIM = R SC If current limit is not used, short VDDA and VDDB to VDD. Daisy Chains Parts may be cascaded in groups of arbitrary size. The SHIFTOUT pin of one part is connected to the SHIFTIN pin of the following part. Data bit 36 is the first bit data to be shifted in. Status bit 36 is the first status bit to be shifted out. (See Table 1 and Table 2) When loading the 36-bit data words, the user must keep track of the number of SHIFTCLOCK cycles to determine when data is aligned for transfer to the control and PWM registers. For example, if one daisy chains 10 parts, 360 SHIFTCLK cycles are required to clock in all the data words. LOAD and the Data/Control and Status Registers: When LOAD is low, the MIC5400 acts as a 36-bit shift register. When LOAD goes high, the part no longer shifts data. Data is transferred from the Shift Register to the parallel control registers on the first falling edge of SHIFTCLK after LOAD goes high. While LOAD remains high, the next rising edge of SHIFTCLOCK transfers data from the status registers to the shift register. The first status bit to appear on SHIFTOUT is Status Filler Bit 36 (Logic 0). See Table 2 for description and Figure 2 for timing. Status A or Status B = 0 if the output is open circuit, i.e., open LED. After LOAD returns low, normal shift register operation resumes and status data is shifted out as new data words are shifted in on the rising edge of SHIFTCLK. ISET = VREF ( 2V ) [8.1] x [2V] = and GFS= RBIAS RBIAS RBIAS For RBIAS = 500, GFS = 32.4mA The recommended value for ISET is 4mA or less for linear operation. See Figure 3. Brightness Control Brightness contol is provided by two, 4-bit DACs, one DAC for each of the two output banks of 8 outputs. The output current is varied between 0*GFS and (15/16) *GFS in 15 equal steps based on the 4 Bit DAC code from the shift register Data Word; Bits Q29 -Q32 control Output Bank A and Bits QA3336 control Output Bank B. (See Table 1: Data Word Format). Watchdog Status is read back from Status Word Bit Q17. Thermal Status is read from Status Word Bit Q18. Output Intensity Each LED Output intensity is further controlled by a Pulse Width Modulator providing 10-bit resolution intensity variation. One LED output per bank can be set up for each Data Word. A 3-bit address selects 1 of the 8 PWMs for each of the two output banks. Programming bits Q1-Q3 determine the PWM address, bits Q4-Q13 control the PWMs driving Bank A, bits Q14-Q23 control the PWMs driving Bank B. The PWM is created by comparing the count of a 10-bit counter with the 10-bit programming word. If the count output is greater than the programming word, the output is "OFF". The PWM frequency is also programmable, in ratio to the frequency of the shift register clock. The ratio value is set by the Divisor, loaded into bits Q25-Q28 of the Data Word. See Table 3. Watchdog and Thermal Shutdown The MIC5400 incorporates both a watchdog and thermal shutdown. The watchdog shuts off all outputs and sets watchdog status bit to logic 1 if the shift clock is absent for more than 200 microseconds. Watchdog status remains logic 0 for shift clocks more frequent than 25 microseconds. The watchdog is enabled by data word bit Q24. Watchdog status is read back from status word bit D17. Divisor Code 0 1 2 3 4 5 6 7 8 9 ABCDE F Divide by R 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Table 3. PWM Clock Ratio to Shift Clock [PWM Clock Freq. = (Shift Clock Freq)/R] MIC5400 8 January 2005 MIC5400 Micrel (1V/div) TIME (2.5ns/div) (1V/div) (2V/div) TIME (2.5ns/div) Output Current Sink Rise Time Clock to Shiftout Delay Time (1V/div) TIME (2.5ns/div) Output Current Sink Fall Time January 2005 9 MIC5400 MIC5400 Micrel Package Information Rev. 02 28-Pin Wide SOIC MICREL, INC. 1849 FORTUNE DRIVE SAN JOSE, CA 95131 USA TEL + 1 (408) 944-0800 FAX + 1 (408) 944-0970 WEB http://www.micrel.com The information furnished by Micrel in this datasheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser's use or sale of Micrel Products for use in life support appliances, devices or systems is at Purchaser's own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. (c) 2005 Micrel, Incorporated. MIC5400 10 January 2005 |
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