(80-Channel Column/Common Driver for iddle- or Large-sized Liquid Crystal Panel) Rev 0.2 February 1996 Description The HD66206 is an 80-channel LCD driver, which is used for liquid crystal dot matrix display. This product can drive various types of liquid crystal displays, from small-sized to monochrome VGA-sized displays. Since this product can function as a column and a common driver, an LCD panel can be configured only with this product. Features Logic power supply voltage: 2.7 to 5.5V Display duty: 1/16 (1/5 bias) to 1/240 80 liquid crystal display drive circuits Liquid crystal display drive voltage: 6 to 28V Data transfer speed 8 Hz max (at 5-V operation) 6.5 Hz max (at 3-V operation) Chip enable signal automatic generation Standby function Controllers that can be used with HD64645/HD64646 (LCTC series) HD66841 (LVIC series) Packages TFP-100B No package (bare chip) COS process 146
Ordering information Type name HD66206TE HCD66206 Package TFP-100B Bare chip 147
148 Pin Arrangement HD66206TE (TFP-100B) (Top view) 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 Y53 Y54 Y55 Y56 Y57 Y58 Y59 Y60 Y61 Y62 Y63 Y64 Y65 Y66 Y67 Y68 Y69 Y70 Y71 Y72 Y73 Y74 Y75 Y76 Y77 Y27 Y26 Y25 Y24 Y23 Y22 Y21 Y20 Y19 Y18 Y17 Y16 Y15 Y14 Y13 Y12 Y11 Y10 Y9 Y8 Y7 Y6 Y5 Y4 Y3 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 Y52 Y51 Y50 Y49 Y48 Y47 Y46 Y45 Y44 Y43 Y42 Y41 Y40 Y39 Y38 Y37 Y36 Y35 Y34 Y33 Y32 Y31 Y30 Y29 Y28 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 Y78 Y79 Y80 E V EE GND SHL FCS TEST DISPOFF CAR Y1 Y2 Figure 1 Pin Arrangement (HD66206TE)
Block Diagram Y80Y79Y78Y77Y76 Y1 Liquid crystal display drive circuit 80-bit latch circuit Data conversion circuit 80-bit bi-directional shift register (also used as a latch circuit) Selector FCS E Operating mode switchin circuit Counter CAR TEST Test input SHL Figure 2 Block Diagram 149
Block Functions Liquid crystal display drive circuit Generates one of four levels to to the output pin to drive the liquid crystal display according to the combination of data of the 80-bit latch circuit and the signal. 80-bit latch circuit Latches data of the 80-bit bi-directional shift register (also used as a latch circuit) at the falling edge of, and transmits it to the liquid crystal display drive circuit. 80-bit bi-directional shift register (also used as a latch circuit) When FCS is low, this register functions as an 80-bit shift register. At this time, and are used as data input/output pins. When FCS is high, this register functions as a 20 4-bit unit latch circuit. At this time, data that is input in parallel to data input pin,, and is converted to 4-bit data, and then is latched to this register according to the latch signal generated by the selector. Data conversion circuit When FCS is low, and are used as data input/output pins. When FCS is high,,,, and are input data. Selector Decodes output data from the counter and generates a latch signal. Functions when latching data at serial-latch operation (when FCS is high). At this time, after 80 bits of data Y1 to Y80 are completely latched, the operation of the selector terminates. Even if input data changes, data in the latch circuit is maintained. Operating mode switching circuit Switches common driver operation (when FCS is low) and column driver operation (when FCS is high). 150
Pin Function Table 1 Pin Functions Classification Symbol Pin No. Pin Name Power supply 39 GND 37 GND V EE 34 V EE 30 31 32 33 Input/ Output Function GND: Logic power supply V EE : Power supply for driving the liquid crystal display. Input Power supply voltage for liquid crystal display drive level. See Figure 3. Control signal 36 Clock 1 Input Column driver data latch signal. Data is latched at the falling edge of this signal. Set this signal low in common driver operation. 47 Clock 2 Input In column driver operation, used as a display data latch signal. In common driver operation, used as a line selection data shift signal. In both operations, this signal is valid at its falling edge. 35 Input AC conversion signal for liquid crystal display drive output. SHL 38 Shift left Input Control signal for inverting data output destination. 1. In column driver operation See Figure 4. 2. In common driver operation SR1, SR2, SR3,..., SR80 correspond to Y1, Y2, Y3,..., Y80 outputs. When SHL is low, data is input to pin and output from pin. and are set low. When SHL is high, the relationships between and are reverse. See Table 2. ( 29 Enable Input When FCS is high, data latch starts by setting the ( signal low. When FCS is low, set the ( signal high. The relationships between the ( signal, the FCS signal, data latch operation, and driver function are as show in Table 3 151
Table 1 Pin Function (cont) Classification Symbol Pin No. Pin Name Input/ Output Function Control signal &$5 48 Carry Output When FCS is high, a chip enable signal is transferred to the next IC from this pin. Connect this pin to ( of the next IC. When FCS is low, open this pin. Liquid crystal display drive output ',632)) 42 Display off Input When this signal is low, liquid crystal display drive output is set at level and liquid crystal display is turned off. At this time, internal display data is not affected. When this signal is high, the operation returns to the normal status. D1L 46 45 44 43 Data0 (L) Data1 (R) Data2 Data3 FCS 40 Function select Input/ output Input Input In column driver operation, input display data to,,, and pins. In common driver operation, when SHL is high, and pins are display data output and input pins, respectively, and vice versa when SHL is low. At this time, set and low. When display data is high, liquid crystal display drive output is selection level and the display is on, and when display data is low, they are non-selection level and off, respectively. Control signal to select each operating mode. When the FCS pin is high, the operating mode is column driver, and when it is low, the operation mode is common driver. TEST 41 TEST Input Test pin. Set this pin low. Y1 to Y80 49 to 100 1 to 28 Y1 to Y80 Output Liquid crystal display drive output. One of four levels to is output according to the combination of the signal and display data. See Figures 5 and 6. 152
and : Selection level and : Non-selection level Figure 3 Liquid Crystal Display Drive Level SHL Input data and latch address Y1 Y2 Y3 Y4 Y5 Y6 Y7 Y8 Y73 Y74 Y75 Y76 Y77 Y78 Y79 Y80 High Last 2nd 1st Low Y1 Y2 Y3 Y4 Y5 1st Y6 Y7 Y8 2nd Y73 Y74 Y75 Y76 Y77 Y78 Y79 Y80 Last Figure 4 Column Driver Operating ode Table 2 Common Driver Operation SHL Shift Register Shift Direction Common Signal Scan Direction Low SR SR... SR Y1 Y80 1 2 80 High SR SR... SR 80 79 1 Y80 Y1 Table 3 Relationship between FCS, (, Data Latch Operation, and Driver Function FCS ( Data Latch Operation Driver Function High Low Enabled Column driver High Disabled Low High Common driver 153
Output level to be selected 1 0 Data 1 0 1 0 Output level Figure 5 Liquid Crystal Display Drive Output in Column Driver Operation Output level to be selected 1 0 Data 1 0 1 0 Output level Figure 6 Liquid Crystal Display Drive Output in Common Driver Operation 154
HD66206 Application Examples Figure 7 shows an example when configuring the 640 240-dot LCD panel using the HD66206. com1 com2 com3 GND V EE E SHL 80 DISPOFF HD66206 (1) LCD panel 640 240 1/240 duty Y80, Y79, Y2, Y1 CAR FCS TEST Open GND V EE E SHL 80 DISPOFF HD66206 (3) seg638 seg639 seg640 seg1 seg2 seg3 com239 com240 Y80, Y79,, Y2, Y1 CAR FCS TEST Open Open 80 80 80 GND(0V) (+3V) SHL Y80, Y79,, Y2, Y1 SHL Y80, Y79,, Y2, Y1 SHL Y80, Y79,, Y2, Y1 Open HD66206 (8) CAR HD66206 (1) R1 CAR HD66206 (2),,, DISPOFF FCS TEST R1 Controller FL DISPOFF,,,. CAR R2,,, DISPOFF FCS TEST E GND V EE R1 R1 FCS TEST,,, DISPOFF E GND V EE E GND V EE + + + + V EE (-25V) Notes: 1. The resisances of R1 and R2 depend on the type of LCD panel used. For example, for an LCD panel with a 1/15 bias, R1 and R2 must be 3 kω and 33 kω, respectively. That is, R1/(4 R1 + R2) should be 1/15. 2. To stabilize the power supply, place two 0.1-µF capacitors near each LCD driver: one between and GND, and the other between and V EE. 3. In this example, the Y1 pin is located to the right as viewed from the front of the panel. Figure 7 Application Example 155
1 2 3 4 19 20 21 22 23 156 157 158 159 160 ---------- ----------------------- seg.4 seg.8 seg.12 seg.16 ---------- seg.76 seg.80 seg.84 seg.88 seg.92 ----------------------- seg.624 seg.628 seg.632 seg.636 seg.640 seg.3 seg.7 seg.11 seg.15 ---------- seg.75 seg.79 seg.83 seg.87 seg.91 ----------------------- seg.623 seg.627 seg.631 seg.635 seg.639 seg.2 seg.6 seg.10 seg.14 ---------- seg.74 seg.78 seg.82 seg.86 seg.90 ----------------------- seg.622 seg.626 seg.630 seg.634 seg.638 seg.1 seg.5 seg.9 seg.13 ---------- seg.73 seg.77 seg.81 seg.85 seg.89 ----------------------- seg.621 seg.625 seg.629 seg.633 seg.637 CAR (the first IC) The next IC is activated. Y1 (the first IC) Y80 (the first IC) SEG.80 SEG.1 Figure 8 Timing Charts for Application Example in Column Driver Operation 1 2 3 4 237 238 239 240 1 2 3 4 237 238 239 240 ------------------- ------------------- FL Y80 (the first IC) Y79 (the first IC) Figure 9 Timing Charts for Application Example in Common Driver Operation 156
Absolute aximum Ratings Item Symbol Ratings Unit Note Power supply Logic circuit 0.3 to +7.0 V 1 voltage Liquid crystal display drive circuit V EE 30.0 to + 0.3 V Input voltage (1) VT1 0.3 to + 0.3 V 1 and 2 Input voltage (2) VT2 V EE 0.3 to + 0.3 V 1 and 3 Operating temperature T opr 20 to +75 C Storage temperature T stg 55 to +125 C Notes: 1. easured relative to GND (0V). 2. Applies to,,, SHL, (,,,,, FCS, TEST, and ',632)) pins. 3. Applies to to pins. 4. If the LSI is used beyond its absolute maximum rating, it may be permanently damaged. It should always be used within the limits of its electrical characteristics in order to prevent malfunction or unreliability. 157
Electrical Characteristics DC Characteristics 1 ( = 5V ± 10%, GND = 0V, = 6 to 28V, and Ta = 20 to 75 C, unless otherwise stated) Item Symbol Applicable Pin in. Typ. ax. Unit Conditions Note Input high level voltage Input low level voltage Output high level voltage Output low level voltage Vi-Yj on resistance VIH,,, SHL, (,,,, VIL, FCS, TEST, and ',632)) 0.7 V 0 0.3 V VOH &$5,, 0.4 V I OH = 0.4 ma VOL &$5,, 0.4 V I OL = 0.4 ma R ON1 Y1 to Y80, to 2.0 kω I ON = 100 µa = 28V 1 and 5 R ON2 4.0 kω 1 and 4 Input leakage current (1) Input leakage current (2) Consumption current (1) Consumption current (2) Consumption current (3) Consumption current (4) Consumption current (5) I IL1,,, SHL, (,,,,, FCS, TEST, and ',632)) 5 5 µa VIN = to GND I IL2 to 25 25 µa VIN = to V EE I GND1 3.0 ma f = 8.0 Hz f = 50 khz f = 2.3 khz 2 and 4 I ST 200 µa = 5V = 28V 2 to 4 I EE1 500 µa Checker data FCS = high 2 and 4 I GN 100 µa f = 50 khz f = 2.3 khz I EE2 500 µa = 5V = 28V FCS = low 2 and 5 2 and 5 158
DC Characteristics 2 ( = 2.7 to 4.5V, GND = 0V, = 6 to 28V, and Ta = 20 to 75 C, unless otherwise stated) Item Symbol Applicable pin in. Typ. ax. Unit Conditions Note Input high level voltage Input low level voltage Output high level voltage Output low level voltage Vi-Yj on resistance Input leakage current (1) Input leakage current (2) Consumption current (1) Consumption current (2) Consumption current (3) Consumption current (4) Consumption current (5) VIH,,, SHL, (,,,, VIL, FCS, TEST, and ',632)) VOH VOL R ON1 &$5,, and &$5,, and Y1 to Y80, and to 0.8 V 0 0.2 V 0.4 V I OH = 0.4 ma 0.4 V I OL = 0.4 ma 2.0 kω I ON = 100 µa = 2 8V 1 and 5 R ON2 4.0 kω 1 and 4 I IL1,,, SHL, (,,,,, FCS, TEST, and ',632)) 5 5 µa VIN = to GND I IL2 to 25 25 µa VIN = to V EE I GND1 1.5 ma f = 6.5 Hz f = 40.6 khz f = 1.8 khz 2 and 4 I ST 100 µa = 3.0V = 28V 2 to 4 I EE1 500 µa Checker data FCS = high 2 and 4 I GN 50 µa f = 40.6 khz f = 1.8 khz I EE2 500 µa = 3.0V = 28V FCS = low 2 and 5 2 and 5 Notes: 1. Indicates the resistance between one pin from Y1 to Y80 and another pin from the V pins to, when a load current is applied to the Y pin; defined under the following conditions: In column driver operation and = 2/10 ( ) and = V EE + 2/10 ( ) In common driver operation and = 2/10 ( ) and = V EE + 2/10 ( ) and should be near the VCC level, and and should be near the V EE level. All these voltage pairs should be separated by less than V, which is the range within which R ON, the LCD drive circuits output impedance, is stable. Note that V depends on power supply voltage. See Figure 10. 159
2. Input and output currents are excluded. When a COS input is floating, excess current flows from the power supply through to the input circuit. To avoid this, VIH and VIL must be held to and GND, respectively. 3. GND current at standby (( input = high) 4. Applies to column driver operation. 5. Applies to common driver operation. V 2.4 V (V)5.6 V 6 28 V EE V EE (V) Figure 10 Relationship between Driver Output Waveform and Level Voltages 160
Pin Configuration Each pin configuration is shown below. Applicable pin:,, SHL, E, FCS, and TEST POS Applicable pin: and NOS Input enable GND Figure 11 Input Pin Configuration Applicable pin: and POS POS Output data NOS NOS Output enable POS Output data GND POS NOS Output enable NOS Input enable GND Figure 12 Input/Output Pin Configuration Applicable pin: CAR POS Applicable pin: Y1 Y80 POS GND NOS Yn V EE V EE POS NOS NOS Figure 13 Output Pin Configuration 161
AC Characteristics 1 (In Column Driver Operation) ( = 5V ± 10%, GND = 0V, = 6 to 28V, and Ta = 20 to +75 C, unless otherwise stated) Item Symbol Applicable Pins in. ax. Unit Note Clock cycle time t CYC 125 ns Clock high level width t CWH and 40 ns Clock low level width t CWL 40 ns Clock setup time t SCL and 80 ns Clock hold time t HCL and 80 ns Clock rise time t r and 1 ns 1 Clock fall time t f and 1 ns 1 Data setup time t DS,,,, and 20 ns Data hold time t DH,,,, and 20 ns Enable setup time t ESU ( and 20 ns Carry output delay time t CAR &$5 and 70 ns 2 phase difference t C and 300 ns cycle time t t CYC 50 ns 162
AC Characteristics 2 (In Column Driver Operation) ( = 2.7 to 4.5V, GND = 0V, = 6 to 28V, and Ta = 20 to +75 C, unless otherwise stated) Item Symbol Applicable pins in. ax. Unit Note Clock cycle time t CYC 152 ns Clock high level width t CWH and 65 ns Clock low level width t CWL 65 ns Clock setup time t SCL and 80 ns Clock hold time t HCL and 120 ns Clock rise time t r and 1 ns 1 Clock fall time t f and 1 ns 1 Data setup time t DS,,,, and 50 ns Data hold time t DH,,,, and 50 ns Enable setup time t ESU ( and 30 ns Carry output delay time t CAR &$5 and 100 ns 2 phase difference t C and 300 ns cycle time t t CYC 50 ns Notes: 1. Clock rise time (t r ) and clock fall time (t f ) must satisfy the following conditions: t r and t f < (t CYC t CWH t CWL )/2 t r and t f 50 2. Defined by connecting the load circuit shown in Figure 14. Test point 30 pf Figure 14 Load Circuit 163
AC Characteristics 3 (In Common Driver Operation) ( = 2.7 to 5.5V, GND = 0V, = 6 to 28V, and Ta = 20 to +75 C, unless otherwise stated) Item Symbol Applicable Pins in. ax. Unit Note Clock cycle time t CYC 10 µs Clock high level width t CWH 80 ns Clock low level width t CWL 1.0 µs Clock rise time t r 30 ns Clock fall time t f 30 ns Data setup time t DS,, and 100 ns Data hold time t DH,, and 100 ns Data output delay time t DD,, and 7.0 µs 1 Note: Defined by connecting the load circuit shown in Figure 15. Test point 30 pf Figure 15 Load Circuit 164
t r t CWH t f t CWL t CYC VIL VIH t DS t DH,,, and VIH VIL t CWH t VIH VIL t SCL thcl VIL t CAR VIH Last data t CAR CAR VOH VOL E t C VIL t ESU VIH VIL Figure 16 Common Driver Operation Timing 165
t f t CWL t r t CWH t CYC VIH VIL t DS t DH Data in (, ) VIH VIL t DD Data out (, ) VOH VOL Figure 17 Common Driver Operation Timing 166