公开(公告)号：DE1254183B

公开(公告)日：1967-11-16

申请号：DEJ0021874

申请日：1962-06-01

Applicant: IBM

Inventor： FUNK HOWARD LEROY ,  HARRISON THOMAS JAMES ,  JURSIK JAMES

IPC: H03M1/00 ,  H03K13/06

公开(公告)号：DE1279369B

公开(公告)日：1968-10-03

申请号：DEJ0028808

申请日：1965-08-19

Applicant: IBM

Inventor： FUNK HOWARD LEROY

IPC: G01J1/24

公开(公告)号：DE1272360B

公开(公告)日：1968-07-11

申请号：DE1272360

申请日：1964-09-19

Applicant: IBM

Inventor： HOPNER EMIL ,  FUNK HOWARD LEROY ,  CRITSCHLOW DALE LEVERNE

IPC: H03K5/06

公开(公告)号：DE1034687B

公开(公告)日：1958-07-24

申请号：DEI0009381

申请日：1954-11-16

Applicant: IBM DEUTSCHLAND

Inventor： YOUNG DONALD REEDER ,  FUNK HOWARD LEROY

IPC: G11C11/22 ,  H01G7/02 ,  H01P7/06 ,  H03H7/30 ,  H03K3/45 ,  H03K3/64 ,  H03K23/76 ,  H03K25/00

Abstract: 756,908. Circuits employing multi-stable ferroelectric elements. INTERNATIONAL BUSINESS MACHINES CORPORATION. Nov. 12, 1954 [Nov. 17, 1953], No. 32809/54. Class 40 (4). [Also in Group XIX] A counter comprises a ferroelectric capacitor capable of assuming a multiplicity of stable states of polarization between two limits, means for polarizing the capacitor to one of the limiting states, means for applying information representing quantified pulses to the capacitor to cause it to exist at an intermediate state between the limits, and means for producing an indication of the information stored. Positive input pulses on a lead 14, Fig. 2, are standardized in amplitude and duration by a device 15 so that a pre-arranged number n-1 of such pulses are required to cause complete reversal of polarization of a ferroelectric storage element 10 from state b, Fig. 1, to state a. During the first n-1 pulses insufficient voltage is developed at the point 11 to affect a one-shot multivibrator 17, but the element 10 presents only a low capacitance to the nth pulse, and sufficient voltage is then developed to trigger the multivibrator 17 and produce a single output pulse on lead 18. This pulse is also applied to a cathode follower 19 which supplies a pulse to the opposite plate of the capacitor 10 sufficient to return the element to its initial state b of polarization. In an alternative arrangement, instead of returning the ferroelectric element 20, Fig. 3, to its initial state, the nth pulse reverses a bi-stable flip-flop 23 which, through lines 32, 33, reverses the bias on diodes 28, 30 to cause subsequent input pulses from a quantifying circuit 36 to be applied to the opposite side of the ferroelectric element 20 and, so step the polarization in the opposite direction. The 2nth pulse returns the input pulses to the initial channel, and so on. Subtraction and addition can be performed by selectively applying input pulses to the upper -and lower plates respectively of the ferroelectric element. Various methods of reading out the stored amount are described including " rolling out " by applying a series of n pulses, or applying a large pulse and observing the voltage developed across resistor 13, Fig. 2. Fig. 4 shows a pulse quantifying circuit. A bias 54 normally holds a ferroelectric capacitor 50 in a polarization state d, Fig. 1. A positive count pulse, applied to terminal 51, drives the capacitor 50 to state c. At this time, a predetermined quantified pulse is developed due to the flow of electrons from a condenser 55 towards the point 52. This positive pulse passes a diode 56 and is applied to a counter of the type described above. At the termination of the input pulse, current flows through a resistor 53 to recharge the capacitor 50 in its opposite limiting sense.