T 0069/92 14-01-1993

I. The Appellant opposed European patent No. 0 144 158 and now contests the interlocutory decision of the Opposition Division that, account being taken of the amendments made during the opposition proceedings, the patent and the invention to which it relates meets the requirements of the EPC.

II. In the appeal proceedings, the Respondent made further amendments to the claims and description. There are now three independent claims, Claims 1, 21 and 23, worded as follows:

"1. An integrated circuit device comprising a timing apparatus (4) for a logic device (2) said timing apparatus having an output (5) connected to supply a high frequency output timing signal to said logic device, said timing apparatus (4) comprising a phase locked loop arranged to produce said output timing signal whose frequency is a multiple of the frequency of an input clock signal, wherein said phase locked loop comprises comparator means (7) having a first input to which said input clock signal is applied, a second input, and output means on which comparison signals are provided, a divider (8) having an input connected to receive said output timing signal and an output connected to said second input of the comparator means (7) said divider (8) being arranged to divide the frequency of said output timing signal by a predetermined integer, and a voltage controlled oscillator (12) arranged to be controlled in dependence upon said comparison signals to produce said output timing signal at its output, the output of said voltage controlled oscillator (12) being connected to the input of said divider (8) wherein said timing apparatus (4) has an input (6) connected to one input pin (3') for receiving said input clock signal, said comparator means (7) has two outputs (9,10) on which said comparison signals are provided, one to increase the frequency and the other to decrease the frequency of the voltage controlled oscillator, said phase locked loop includes converter and filter means (11) connected to receive the comparison signals (9,10) and arranged to generate a voltage signal (27) whose magnitude is determined by the comparison signals, said voltage controlled oscillator (12) being controlled by said voltage signal (27), said converter and filter means (11) includes a first current source circuit (18,19,20,21) connected to receive one comparison signal (9) of the comparator means (7) and including a first current source transistor (19) operable in response to said one comparison signal (9) to vary said voltage signal (27) to increase the frequency of the oscillator (12), a second current source circuit (23,24,25,26) connected to receive the other comparison signal (10) of the comparator means (7) and including a second current source transistor (24) operable in response to said other comparison signal to vary said voltage signal (27) to decrease the frequency of the oscillator (12) and a current reference circuit (13), characterised in that said integrated circuit device further comprises a logic device (2) to which a plurality of input and output pins (3) are connected, both the said logic device (2) and said timing apparatus (4) being completely formed on a common single chip (1), and in that the current reference (13) has first and second current mirror circuits (30,31) (28,29) connected respectively between a power supply and ground, a first current mirror transistor (31) in the first current mirror circuit being coupled to said first current source transistor (19) and controlling the current value in said first current source transistor (19), and a second current mirror transistor (28) in the second current mirror circuit coupled to said second current source transistor (24) and controlling the current value in said second current source transistor (24), and the output (5) of said voltage controlled oscillator (12) is directly connected to said logic device (2) to supply thereto high frequency output timing signals of at least 40MHz."

"21. A method of supplying timing signals to an integrated circuit logic device (2) comprising the steps of applying a low frequency clock signal to an input (6) of a timing apparatus, the timing apparatus being arranged to generate a high frequency timing signal at its output (5) having a frequency which is a multiple of that of said clock signal, dividing the frequency of said high frequency timing signal by a predetermined integer, comparing the divided frequency with the frequency of the clock signal, generating an increase or decrease comparison signal (9,10) where the clock signal frequency is respectively greater than or less than said divided frequency, using said increase and decrease comparison signals to switch respective current sources (19,24) and generate a D.C. voltage whose magnitude is determined by said increase and decrease comparison signals, and generating the high frequency timing signal at the output (5) of a voltage controlled oscillator (12) in dependence upon said comparison signals, characterised in that the timing apparatus employed is formed with the logic device (2) on a common single chip, and in that current flow through each of said current sources is controlled by a respective current mirror circuit (28,29,30,31) and in that the high frequency timing signal at the output of said voltage controlled oscillator is at least 40MHz and is connected directly to said logic device (2) to form the timing signal therefor."

"23. A method of supplying timing signals to an integrated circuit logic device (2) comprising the steps of applying a low frequency clock signal to an input (6) of a timing apparatus, the timing apparatus being arranged to generate a high frequency timing signal at its output (5) having a frequency which is a multiple of that of said clock signal, dividing the frequency of said high frequency timing signal by a predetermined integer, comparing the divided frequency with the frequency of the clock signal, generating an increase or decrease comparison signal (9,10) where the clock signal frequency is respectively greater than or less than said divided frequency, using said increase and decrease comparison signals to switch respective current sources (19,24) and generate a D.C. voltage whose magnitude is determined by said increase and decrease comparison signals, and generating the high frequency timing signal at the output (5) of a voltage controlled oscillator (12) in dependence upon said comparison signals, characterised by controlling the current flow in each current source (19,24) by use of a programmable current reference circuit (13) including a current mirror circuit (28,29,30,31) for each of said current sources, determining the operating speed of the logic device (2) and programming the current reference circuit (13) to provide a high frequency output signal of at least 40MHz which matches said operating speed and supplying said high frequency output signal to the logic device (2) which is formed with the timing apparatus on a common single chip."

III. In the Statement of Grounds of Appeal, the Appellant argued essentially that the decision under appeal was based on an incorrect assessment of the closest prior art document EP-A-0 072 751 (D2). Contrary to paragraph 3(i) of the impugned decision, D2 disclosed the combination on a single chip of a codec and timing apparatus including a phase locked loop (see page 1, lines 24 and 25, page 1, line 34 to page 2, line 11, and "A single-chip codec with switched-capacitor filters" cited in the search report of D2). Moreover, contrary to paragraph 3(ii) of the impugned decision, D2 disclosed a comparator (1, Figure 1) with two outputs (c, d), one to increase the frequency (when c = 0) and the other to decrease the frequency (when d = 0) of the voltage controlled oscillator (3), see D2, page 4, lines 5 to 26. The choice of positive instead of negative logic was not inventive. Thus, the Appellant argued that the subject-matter of Claim 1 in the form maintained by the Opposition Division did not involve an inventive step.

The Appellant also argued that the Opposition Division had committed a substantial procedural violation in not considering whether the requirements of Article 123(3) EPC had been met. The newly introduced Claim 22 (now Claim 20) extended the protection to cover combinations with analogue MOS circuits.

IV. The Respondent pointed out that Claim 22 objected to by the Appellant could not extend the protection because it was dependent on Claim 1. It merely specified that the integrated circuit device, which according to Claim 1 comprised a logic device, comprised a MOS device.

The Respondent accepted that D2 disclosed more features of the present invention than had been acknowledged in the proceedings before the Opposition Division and amended the claims to take account of this. Regarding inventive step, the Respondent argued essentially that although D2 disclosed a phase locked loop formed as an integrated circuit and mentioned that it may be used for a codec, it did not disclose a codec, or any other logic circuit, on the same chip as the phase locked loop. D2 was concerned with reducing the size of the necessary capacitors so that they could be integrated on the same chip as the phase locked loop whose output frequency was 128 kHz. The present invention, subject-matter of the claims as amended during the appeal proceedings, used two reference current mirror circuits to solve the different problem of reducing phase jitter when timing signals of a frequency of at least 40 MHz were produced on chip. This was not disclosed in D2.

V. During oral proceedings held on 14 January 1993, the Appellant argued essentially that Claim 1 of the patent in suit had three characterising features:

(a) everything on one chip, (b) current mirror circuits, (c) frequency at least 40 MHz.

Regarding (a), it was already known from D2's search report to put a codec and its timing circuit on one chip. Regarding (b), D2 showed two current source transistors (Q10, Q11) in Figure 5A. Regarding (c), there was no disclosure in the application as originally filed that the frequency could be above 40 MHz with no upper limit, only the range 40 to 100 MHz was disclosed. A phase locked loop producing an output frequency of tens of MHz was known from DE-A-2 739 035 (D3), cited in the notice of opposition. To support the argument concerning feature (a) the Appellant sought to introduce into the appeal proceedings the paper "A single-chip codec with switched- capacitor filters" cited in the search report of D2 and four further references cited in that paper. The Board decided to disregard these new documents.

VI. The Respondent replied that integrated logic circuits produced noise on the substrate which affected the positions of the edges of clock signals when these were generated on chip. With a clock frequency of 128 kHz, as in D2, clock edge jitter of 50 ns could be tolerated. But with a frequency of 40 MHz, jitter 2 or 3 ns would cause clock ambiguity. The present invention reduced the jitter to an acceptable level by using current mirror circuits to control the current in the current sources. In D2, the current flow through transistors Q10 and Q11 was set by a potential divider (Q7, Q8, Q9, Figure 5A, or Q7, R10, Q9, Figure 6A) which could not compensate for noise on the substrate. The application as originally filed contained an example where the frequency was 40 to 100 MHz, but there was no suggestion that 100 MHz was a necessary upper limit.

VII. The Appellant requests that the interlocutory decision of the Opposition Division be set aside and that the patent in suit be revoked in its entirety.

VIII. The Respondent requests that the patent be maintained on the basis of the following documents:

- Claims 1, 21 and 23 as presented in the oral proceedings.

- Claims 2 to 20 and 22 as filed on 10 September 1992.

- Description as printed in the patent specification, with the text from column 1, line 48, to column 2, line 54, inclusive, being replaced by pages 2a, 2b and 2c as presented in the oral proceedings.

- Drawings as printed in the patent specification.