INTEGRATED CIRCUITS DATA SHEET For a complete data sheet, please also download: * The IC04 LOCMOS HE4000B Logic Family Specifications HEF, HEC * The IC04 LOCMOS HE4000B Logic Package Outlines/Information HEF, HEC HEF4060B MSI 14-stage ripple-carry binary counter/divider and oscillator Product specification File under Integrated Circuits, IC04 January 1995 Philips Semiconductors Product specification 14-stage ripple-carry binary counter/divider and oscillator HEF4060B MSI be replaced by an external clock signal at input RS. The counter advances on the negative-going transition of RS. A HIGH level on MR resets the counter (O3 to O9 and O11 to O13 = LOW), independent of other input conditions. DESCRIPTION The HEF4060B is a 14-stage ripple-carry binary counter/divider and oscillator with three oscillator terminals (RS, RTC and CTC), ten buffered outputs (O3 to O9 and O11 to O13) and an overriding asynchronous master reset input (MR). The oscillator configuration allows design of either RC or crystal oscillator circuits. The oscillator may Schmitt-trigger action in the clock input makes the circuit highly tolerant to slower clock rise and fall times. Fig.1 Functional diagram. PINNING MR master reset RS clock input/oscillator pin RTC oscillator pin CTC external capacitor connection O3 to O9 O11 to O13 Fig.2 Pinning diagram. counter outputs HEF4060BP(N): 16-lead DIL; plastic (SOT38-1) HEF4060BD(F): 16-lead DIL; ceramic (cerdip) (SOT74) HEF4060BT(D): 16-lead SO; plastic (SOT109-1) ( ): Package Designator North America FAMILY DATA, IDD LIMITS category MSI See Family Specifications January 1995 2 This text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here in _white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader.This text is here inThis text is here in white to force landscape pages to be rotated correctly when browsing through the pdf in the Acrobat reader. white to force landscape pages to be ... Philips Semiconductors 3 14-stage ripple-carry binary counter/divider and oscillator January 1995 Fig.3 Logic diagram. Product specification HEF4060B MSI Philips Semiconductors Product specification 14-stage ripple-carry binary counter/divider and oscillator HEF4060B MSI AC CHARACTERISTICS VSS = 0 V; Tamb = 25 C; CL = 50 pF; input transition times 20 ns VDD V SYMBOL TYPICAL EXTRAPOLATION FORMULA MIN. TYP. MAX. Propagation delays RS O3 HIGH to LOW 5 10 tPHL 15 5 LOW to HIGH 10 tPLH 15 On On + 1 HIGH to LOW 5 Output transition times HIGH to LOW LOW to HIGH width input RS HIGH Minimum MR pulse width; HIGH Recovery time for MR 69 ns + (0,23 ns/pF) CL 50 100 ns 42 ns + (0,16 ns/pF) CL 210 420 ns 183 ns + (0,55 ns/pF) CL 80 160 ns 69 ns + (0,23 ns/pF) CL 50 100 ns 42 ns + (0,16 ns/pF) CL 50 ns ns 6 12 ns 25 50 ns 10 20 ns 6 12 ns 100 200 ns 73 ns + (0,55 ns/pF) CL 40 80 ns 29 ns + (0,23 ns/pF) CL 15 30 60 ns 22 ns + (0,16 ns/pF) CL 5 60 120 ns 10 ns + (1,0 ns/pF) CL 10 tPLH 5 10 tPHL 30 60 ns 9 ns + (0,42 ns/pF) CL 15 20 40 ns 6 ns + (0,28 ns/pF) CL 5 60 120 ns 30 60 ns 9 ns + (0,42 ns/pF) CL 20 40 ns 6 ns + (0,28 ns/pF) CL 10 10 tTHL tTLH 15 Minimum clock pulse 183 ns + (0,55 ns/pF) CL ns 20 15 HIGH to LOW ns 160 25 tPHL 5 MR On 420 80 10 10 15 LOW to HIGH 210 5 10 120 tWRSH 60 ns 50 25 ns 15 30 15 ns 5 50 25 ns 10 tWMRH 30 15 ns 15 20 10 ns 5 160 80 ns 10 tRMR 80 40 ns 15 60 30 ns Maximum clock pulse 5 4 8 MHz frequency input RS 10 10 20 MHz 15 30 MHz 15 January 1995 fmax 4 10 ns + (1,0 ns/pF) CL Philips Semiconductors Product specification 14-stage ripple-carry binary counter/divider and oscillator HEF4060B MSI AC CHARACTERISTICS VSS = 0 V; Tamb = 25 C; input transition times 20 ns VDD V TYPICAL FORMULA FOR P (W)(1) 5 700 fi + foCLVDD2 per package 10 3 300 fi + foCLVDD2 (P) 15 8 900 fi + foCLVDD2 Dynamic power dissipation Total power dissipation 5 700 fosc + foCLVDD2 + 2CtVDD2fosc + when using the 10 3 300 fosc + on-chip oscillator (P) 15 8 900 fosc + foCLVDD2 foCLVDD2 + + 2CtVDD2fosc 2CtVDD2fosc Notes 1. where: fi = input frequency (MHz) fo = output frequency (MHz) CL = load capacitance (pF) VDD = supply voltage (V) Ct = timing capacitance (pF) fosc = oscillator frequency (MHz) RC oscillator Typical formula for oscillator frequency: 1 f osc = --------------------------------2,3 x R t x C t Fig.4 External component connection for RC oscillator. January 1995 5 + 690 VDD 6 900 VDD + 22 000 VDD Philips Semiconductors Product specification 14-stage ripple-carry binary counter/divider and oscillator HEF4060B MSI Timing component limitations The oscillator frequency is mainly determined by RtCt, provided Rt << R2 and R2C2 << RtCt. The function of R2 is to minimize the influence of the forward voltage across the input protection diodes on the frequency. The stray capacitance C2 should be kept as small as possible. In consideration of accuracy, Ct must be larger than the inherent stray capacitance. Rt must be larger than the LOCMOS `ON' resistance in series with it, which typically is 500 at VDD = 5 V, 300 at VDD = 10 V and 200 at VDD = 15 V. The recommended values for these components to maintain agreement with the typical oscillation formula are: Ct 100 pF, up to any practical value, 10 k Rt 1 M. Typical crystal oscillator circuit In Fig.5, R2 is the power limiting resistor. For starting and maintaining oscillation a minimum transconductance is necessary. Fig.5 Fig.6 External component connection for crystal oscillator. Test set-up for measuring forward transconductance gfs = dio/dvi at vo is constant (see also graph Fig.7); MR = LOW. January 1995 6 Philips Semiconductors Product specification 14-stage ripple-carry binary counter/divider and oscillator HEF4060B MSI A: average B: average + 2 s, C: average - 2 s, where `s' is the observed standard deviation. Ct curve at Rt = 100 k; R2 = 470 k. Rt curve at Ct = 1 nF; R2 = 5 Rt. Fig.7 Fig.8 Typical forward transconductance gfs as a function of the supply voltage at Tamb = 25 C. RC oscillator frequency as a function of Rt and Ct at VDD = 5 to 15 V; Tamb = 25 C. ___ Rt = 100 k; Ct = 1 nF; R2 = 0. - - - Rt = 100 k; Ct = 1 nF; R2 = 300 k. Fig.9 Oscillator frequency deviation (fosc) as a function of ambient temperature; referenced at: fosc at Tamb = 25 C and VDD = 10 V. January 1995 7